Biodegradable materials

These images show a fast-propagating clear-zone; each image is taken eight hours apart. Credit: Olsen Research Group Products made from polymers—ranging from plastic bags to clothing to cookware to electronics—provide many comforts and support today's standard of living, but since they do not decompose easily, they pose long-term environmental challenges. Developing polymers, a large class of materials, with a more sustainable life cycle is a critical step in making progress toward a green economy and addressing this piece of the global climate change crisis. The development of biodegradable polymers, however, remains limited by current biodegradation testing methods. To address this limitation, a team of MIT researchers led by Bradley D. Olsen, the Alexander and I. Michael Kasser (1960) Professor in the Department of Chemical Engineering, has developed an expansive biodegradation data set to help determine whether or not a polymer is biodegradable. Their findings were recently published in the Proceedings of the National Academy of Sciences (PNAS). The MIT team is led by Olsen and Ph.D. candidates Katharina A. Fransen and Sarah H. M. Av-Ron, and also includes postdoc Dylan J. Walsh and undergraduate students Tess R. Buchanan, Dechen T. Rota, and Lana Van Note. "Despite polymer waste being a known and significant contributor to the climate crisis, the study of polymer biodegradation has been limited to a small number of polymers because current biodegradation testing metho...

These images show a fast-propagating clear-zone; each image is taken eight hours apart. Credit: Olsen Research Group Products made from polymers—ranging from plastic bags to clothing to cookware to electronics—provide many comforts and support today's standard of living, but since they do not decompose easily, they pose long-term environmental challenges. Developing polymers, a large class of materials, with a more sustainable life cycle is a critical step in making progress toward a green economy and addressing this piece of the global climate change crisis. The development of biodegradable polymers, however, remains limited by current biodegradation testing methods. To address this limitation, a team of MIT researchers led by Bradley D. Olsen, the Alexander and I. Michael Kasser (1960) Professor in the Department of Chemical Engineering, has developed an expansive biodegradation data set to help determine whether or not a polymer is biodegradable. Their findings were recently published in the Proceedings of the National Academy of Sciences (PNAS). The MIT team is led by Olsen and Ph.D. candidates Katharina A. Fransen and Sarah H. M. Av-Ron, and also includes postdoc Dylan J. Walsh and undergraduate students Tess R. Buchanan, Dechen T. Rota, and Lana Van Note. "Despite polymer waste being a known and significant contributor to the climate crisis, the study of polymer biodegradation has been limited to a small number of polymers because current biodegradation testing metho...

These images show a fast-propagating clear-zone; each image is taken eight hours apart. Credit: Olsen Research Group Products made from polymers—ranging from plastic bags to clothing to cookware to electronics—provide many comforts and support today's standard of living, but since they do not decompose easily, they pose long-term environmental challenges. Developing polymers, a large class of materials, with a more sustainable life cycle is a critical step in making progress toward a green economy and addressing this piece of the global climate change crisis. The development of biodegradable polymers, however, remains limited by current biodegradation testing methods. To address this limitation, a team of MIT researchers led by Bradley D. Olsen, the Alexander and I. Michael Kasser (1960) Professor in the Department of Chemical Engineering, has developed an expansive biodegradation data set to help determine whether or not a polymer is biodegradable. Their findings were recently published in the Proceedings of the National Academy of Sciences (PNAS). The MIT team is led by Olsen and Ph.D. candidates Katharina A. Fransen and Sarah H. M. Av-Ron, and also includes postdoc Dylan J. Walsh and undergraduate students Tess R. Buchanan, Dechen T. Rota, and Lana Van Note. "Despite polymer waste being a known and significant contributor to the climate crisis, the study of polymer biodegradation has been limited to a small number of polymers because current biodegradation testing metho...

These images show a fast-propagating clear-zone; each image is taken eight hours apart. Credit: Olsen Research Group Products made from polymers—ranging from plastic bags to clothing to cookware to electronics—provide many comforts and support today's standard of living, but since they do not decompose easily, they pose long-term environmental challenges. Developing polymers, a large class of materials, with a more sustainable life cycle is a critical step in making progress toward a green economy and addressing this piece of the global climate change crisis. The development of biodegradable polymers, however, remains limited by current biodegradation testing methods. To address this limitation, a team of MIT researchers led by Bradley D. Olsen, the Alexander and I. Michael Kasser (1960) Professor in the Department of Chemical Engineering, has developed an expansive biodegradation data set to help determine whether or not a polymer is biodegradable. Their findings were recently published in the Proceedings of the National Academy of Sciences (PNAS). The MIT team is led by Olsen and Ph.D. candidates Katharina A. Fransen and Sarah H. M. Av-Ron, and also includes postdoc Dylan J. Walsh and undergraduate students Tess R. Buchanan, Dechen T. Rota, and Lana Van Note. "Despite polymer waste being a known and significant contributor to the climate crisis, the study of polymer biodegradation has been limited to a small number of polymers because current biodegradation testing metho...