Progetti UE

Titolo progetto Responsabile del progetto Staff Altro Staff di Ateneo Staff di Dipartimento Descrizione Descrizione (field_descrizione:language) Descrizione: translated Programma Numero del progetto Link al progetto Data di inizio del progetto Allegati Pubblicazioni di riferimento Tema Partner Partner (field_collaborazioni_internazion:delta) Finanziamenti Premi
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 0
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 1
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 2
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 3
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 4
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 5
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 6
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 7
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 8
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 9
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 10
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 11
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 12
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

English

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 13
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 0
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 1
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 2
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 3
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 4
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 5
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 6
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 7
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 8
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 9
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 10
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 11
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 12
AGRILOOP - Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities Marianna Villano Lionel Nguemna Tayou, Marianna Villano, Andrea Martinelli, Cleofe Palocci, Chiara Cavaliere, Laura Chronopoulou, Maria Luisa Astolfi, Angela Marchetti, Sara Alfano

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

Italian

Pushing the frontier of circular agriculture by converting residues into novel economic, social and environmental opportunities

The main objective of the AgriLoop project is to extend the agricultural production value of two major players of the global bioeconomy: EU and China. This will be realized through the development of bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g.: tomato, soy, straw, potato, brewery, oil, winery, and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector.

In this context, the main activities of Sapienza will be focused on the production, extraction, and characterization of biopolymers (i.e., polyhydroxyalkanoates) with mixed microbial cultures as well as on the study of the fate of contaminants from the feedstock to the final products.

 

HORIZON-CL6-2022-CIRCBIO-01-05 - EU-China international cooperation on unlocking the potential of agricultural residues and wastes for circular and sustainable bio-based solutions 101081776 Thursday, 1 December, 2022 Sustainable chemistry Institut National de Recherche pour l'Agriculture, l'Alimentation et l'Environnement (INRAE), Stichting Wageningen Research (WR), Syddansk Universitet, Ecozept, Universidad de Santiago de Compostela, Federació de Cooperatives Agràries de Catalunya, Alma Mater Studiorum – Università di Bologna, Universidade Nova de Lisboa - TomaPaint S.r.l. - NOVA ID FCT - ENTOMOTECH S.L., Consejo Superior de Investigaciones Científicas, University of Gent, Università degli Studi di Verona, Bio-Mi - Universite de Montpellier, Avecom , INRAE Transfert 13
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

English

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 0
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

English

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 1
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

English

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 2
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

English

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 3
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

English

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 4
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

English

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 5
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

English

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 6
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

Italian

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 0
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

Italian

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 1
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

Italian

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 2
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

Italian

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 3
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

Italian

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 4
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

Italian

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 5
LIFE MUSCLES - MUssel Sustainable production (re)cyCLES Antonella Piozzi Iolanda Francolini

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

Italian

immagine sito Life Muscles

Within the Life MUSCLES project, coordinated by Legambiente and  to reduce the environmental impact of PP socks used for mussel farming by developing and promoting a more sustainable production value chain, the Department of Chemistry is engaged in the physical characterization of the materials constituting recycled PP and BP materials of nets (socks), before and after their recovery and recycling. In particular, Antonella Piozzi's research group will verify the possible reuse of the plastic material of the retinas with a view to a circular economy. Furthermore, since to improve the sustainability of mussel farming the plastic material constituting the nets will be replaced with biodegradable material, the same type of characterization will be carried out on the biopolymer nets for the purposes of their mechanical recycling.

The LIFE MUSCLES consortium  is between scientific partners, companies in the plastics and bioplastics sector and mussel farmers cooperatives.

Life MUSCLES is realized with the contribution of the European Commission to the LIFE program, projects on Environment and efficient use of resources (Total Eligible Budget: 3,074,246 €, EU Contribution: 1,690,835 €).

Life Muscles logo

LIFE Programme LIFE20 ENV/IT/000570 Friday, 1 October, 2021 Sustainable chemistry Legambiente, Dipartimento DIMEVET - ALMA MATER STUDIORUM, Dipartimento di Scienze Fisiche, della Terra e dell’Ambiente - Università di Siena, Associazione Mediterranea Acquacoltori (AMA), NOVAMONT, ROM PLASTICA, Soc. Agricola Ittica Del Giudice (Gargano) - Coop. Miticoltori Associati (La Spezia) 6
OpMetBat - Operando metrology for energy storage materials Sergio Brutti Agostini Marco (Dipartimento di Chimica e tecnologia del Farmaco) Maria Assunta Navarra, Paola D'Angelo

The OpMetBat project will build a metrological framework supporting traceable operando characterisation of state-of-the-art battery materials under dynamic charge / discharge conditions. This includes advancement and validation of ex situ methods, establishing new protocols, cells and a best practice guide for operando approaches and developing new instrumentation enabling hybrid, multiparameter measurement to inform new materials development. 

Italian

The OpMetBat project will build a metrological framework supporting traceable operando characterisation of state-of-the-art battery materials under dynamic charge / discharge conditions. This includes advancement and validation of ex situ methods, establishing new protocols, cells and a best practice guide for operando approaches and developing new instrumentation enabling hybrid, multiparameter measurement to inform new materials development. 

European Partmership on Metrology Participating States and from the European Union’s Horizon 2020 research and innovation programme 21GRD01 OpMetBat Thursday, 1 September, 2022 PDF icon image.pdf Renewable energy
REALSEI (opeRando chEmical spAce- and time-resoLved quantification of Solid Electrolyte Interphase in hard carbon anode for sustainable sodium-ion batteries) Giorgia Greco, Sergio Brutti

The scientific goal of the REALSEI research project is to apply and validate an experimental protocol to visualize the formation of the Solid Electrolyte Interphase (SEI) resolved in space and in real-time (operando) on the surface of Hard Carbon (HC) negative electrode in a Na+ ion battery (NIB), and correlate the bulk structure with the surface properties of the sample. To obtain this goal innovative space- and time-resolved operando experiments will be designed and implemented by exploiting X-ray advanced synchrotron techniques. 

Italian

The scientific goal of the REALSEI research project is to apply and validate an experimental protocol to visualize the formation of the Solid Electrolyte Interphase (SEI) resolved in space and in real-time (operando) on the surface of Hard Carbon (HC) negative electrode in a Na+ ion battery (NIB), and correlate the bulk structure with the surface properties of the sample. To obtain this goal innovative space- and time-resolved operando experiments will be designed and implemented by exploiting X-ray advanced synchrotron techniques. 

Marie-Skłodowska Curie 101029608 Saturday, 1 May, 2021 PDF icon image.pdf Renewable energy
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 0
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 1
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 2
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 3
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 4
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 5
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 6
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 7
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 8
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 9
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 10
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 11
RHINOCEROS Pietro Altimari, Pier Giorgio Schiavi ECO RECYCLING

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

Italian

Batteries reuse and direct production of high performances cathodic and anodic materials and other raw materials from batteries recycling using low cost and environmentally friendly technologies

Rhinoceros logo

Obiettivo del progetto Rhinoceros è lo sviluppo di tecnologie sostenibili per il riuso e il riciclo di batterie di veicoli elettrici e di sistemi stazionari. Il progetto prevederà la realizzazione di un sistema robotico intelligente per il sorting e il disassemblaggio delle batterie. Il sistema robotico sarà in grado di identificare e separare le batterie dismesse di veicoli elettrici che possono essere direttamente riutilizzate in applicazioni di “seconda vita”  in sistemi di accumulo stazionario. Per le batterie che non possano essere direttamente riutilizzate, saranno ottimizzati diversi processi di riciclo in grado di recuperare tutti i materiali presenti nelle batterie.

In tale ambito, Sapienza guiderà lo sviluppo di un processo di riciclo delle batterie litio-ione che prevede dapprima il recupero selettivo del litio e successivamente, a partire dalla polvere priva di litio, la sintesi di materiali elettrodici di nuova generazione: lithium-manganese rich e grafene. La metodologia di sintesi di questi materiali che verrà sviluppata permette di escludere la necessità di una completa separazione dei diversi elementi contenuti nella polvere elettrodica. Infatti, i processi di riciclo di batterie litio-ione prevedono attualmente una complessa e costosa separazione dei diversi metalli contenuti nella frazione catodica (Li, Co, Ni, Mn).

Escludendo tale separazione, la strategia proposta permetterà di ridurre i costi di produzione dei materiali catodici da batterie a fine vita e l’impatto ambientale dei processi di riciclo (e.g., riduzione quantità reagenti e consumi energetici necessari per separazione). Inoltre, la contestuale conversione della grafite della frazione anodica in grafene, un materiale ad elevato valore aggiunto impiegato in batterie di nuova generazione, contribuirà ad accrescere la competitività del processo proposto.

HORIZON-CL5-2021-D2-01-06: Sustainable, safe and efficient recycling processes (Batteries Partnership) 101069685 Thursday, 1 September, 2022 Renewable energy Tecnalia Research & Innovation (TEC) - coordinator, Accurec-Recycling (ACC), Jean Goldschmidt International – Hydrometal (JGI-HM), ARKEMA FRANCE SA (ARK) , TES RECUPYL SAS (TES), Leitat Technological Center – Managing Technologies, VLAAMSE INSTELLING VOOR TECHNOLOGISCH ONDERZOEK N.V. (VITO) , KARLSRUHE INSTITUTE OF TECHNOLOGY (KIT), INSTITUTE FOR APPLIED MATERIALS - ENERGY STORAGE SYSTEMS (IAM-ESS) , CHALMERS UNIVERSITY OF TECHNOLOGY/CHALMERS TEKNISKA HOGSKOLA AB (CHA) , UNIVERSITETET I AGDER (UiA) , PNO INNOVATION , FORD OTOMOTIV SANAYI ANONIM SIRKETI (FORD) , LEVERTONHELM LIMITED 12
SIGNE-Composite Silicon/Graphite Anodes with Ni-Rich Cathodes and Safe Ether based Electrolytes for High Capacity Li-ion Batteries Sergio Brutti Enrico Bodo, Maria Assunta Navarra

SiGNE will deliver an advanced lithium-ion battery (LIB) aimed at the High Capacity Approach. Specific objectives are to (1) Develop high energy density, safe and manufacturable Lithium ion battery (2) optimise the full-cell chemistry to achieve beyond state of art performance (3) Demonstrate full-cell fast charging capability (4) Show high full-cell cycling efficiency with >80% retentive capacity (5) Demonstrate high sustainability of this new battery technology and (6) Demonstrate high cost-competitiveness, large-scale manufacturability and EV uptake readiness.

Italian

SiGNE will deliver an advanced lithium-ion battery (LIB) aimed at the High Capacity Approach. Specific objectives are to (1) Develop high energy density, safe and manufacturable Lithium ion battery (2) optimise the full-cell chemistry to achieve beyond state of art performance (3) Demonstrate full-cell fast charging capability (4) Show high full-cell cycling efficiency with >80% retentive capacity (5) Demonstrate high sustainability of this new battery technology and (6) Demonstrate high cost-competitiveness, large-scale manufacturability and EV uptake readiness.

HORIZON RIA 101069738 Thursday, 1 September, 2022 PDF icon image.pdf Renewable energy

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