The sustainable materials roadmap

Magda Titirici; Sterling G Baird; Taylor D Sparks; Shirley Min Yang; Agnieszka Brandt-Talbot; Omid Hosseinaei; David P Harper; Richard M Parker; Silvia Vignolini; Lars A Berglund; Yuanyuan Li; Huai-Ling Gao; Li-Bo Mao; Shu-Hong Yu; Noel Díez; Guillermo A Ferrero; Marta Sevilla; Petra Ágota Szilágyi; Connor J Stubbs; Joshua C Worch; Yunping Huang; Christine K Luscombe; Koon-Yang Lee; Hui Luo; M J Platts; Devendra Tiwari; Dmitry Kovalevskiy; David J. Fermin; Heather Au; Hande Alptekin; Maria Crespo-Ribadeneyra; Valeska P Ting; Tim-Patrick Fellinger; Jesús Barrio; Olivia Westhead; Claudie Roy; Ifan E L Stephens; Sabina Alexandra Nicolae; Saurav Ch Sarma; Rose P Oates; Chen-Gang Wang; Zibiao Li; Xian Jun Loh; Rupert J. Myers; Niko Heeren; Alice Grégoire; Clément Périssé; Xiaoying Zhao; Yael Vodovotz; Becky Earley; Göran Finnveden; Anna Björklund; Gavin D J Harper; Allan Walton; Paul A Anderson

doi:10.1088/2515-7639/ac4ee5

The sustainable materials roadmap

Magda Titirici, Sterling G Baird, Taylor D Sparks, Shirley Min Yang, Agnieszka Brandt-Talbot, Omid Hosseinaei, David P Harper, Richard M Parker, Silvia Vignolini, Lars A Berglund^*, Yuanyuan Li, Huai-Ling Gao, Li-Bo Mao, Shu-Hong Yu, Noel Díez, Guillermo A Ferrero, Marta Sevilla, Petra Ágota Szilágyi, Connor J Stubbs, Joshua C WorchYunping Huang, Christine K Luscombe, Koon-Yang Lee, Hui Luo, M J Platts, Devendra Tiwari, Dmitry Kovalevskiy, David J. Fermin, Heather Au, Hande Alptekin, Maria Crespo-Ribadeneyra, Valeska P Ting, Tim-Patrick Fellinger, Jesús Barrio, Olivia Westhead, Claudie Roy, Ifan E L Stephens, Sabina Alexandra Nicolae, Saurav Ch Sarma, Rose P Oates, Chen-Gang Wang, Zibiao Li, Xian Jun Loh, Rupert J. Myers, Niko Heeren, Alice Grégoire, Clément Périssé, Xiaoying Zhao, Yael Vodovotz, Becky Earley, Göran Finnveden, Anna Björklund, Gavin D J Harper, Allan Walton, Paul A Anderson

^*Corresponding author for this work

Mathematics, Physics and Electrical Engineering

Research output: Contribution to journal › Review article › peer-review

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Abstract

Over the past 150 years, our ability to produce and transform engineered materials has been responsible for our current high standards of living, especially in developed economies. However, we must carefully think of the effects our addiction to creating and using materials at this fast rate will have on the future generations. The way we currently make and use materials detrimentally affects the planet Earth, creating many severe environmental problems. It affects the next generations by putting in danger the future of the economy, energy, and climate. We are at the point where something must drastically change, and it must change now. We must create more sustainable materials alternatives using natural raw materials and inspiration from nature while making sure not to deplete important resources, i.e. in competition with the food chain supply. We must use less materials, eliminate the use of toxic materials and create a circular materials economy where reuse and recycle are priorities. We must develop sustainable methods for materials recycling and encourage design for disassembly. We must look across the whole materials life cycle from raw resources till end of life and apply thorough life cycle assessments (LCAs) based on reliable and relevant data to quantify sustainability. We need to seriously start thinking of where our future materials will come from and how could we track them, given that we are confronted with resource scarcity and geographical constrains. This is particularly important for the development of new and sustainable energy technologies, key to our transition to net zero. Currently ‘critical materials’ are central components of sustainable energy systems because they are the best performing. A few examples include the permanent magnets based on rare earth metals (Dy, Nd, Pr) used in wind turbines, Li and Co in Li-ion batteries, Pt and Ir in fuel cells and electrolysers, Si in solar cells just to mention a few. These materials are classified as ‘critical’ by the European Union and Department of Energy. Except in sustainable energy, materials are also key components in packaging, construction, and textile industry along with many other industrial sectors. This roadmap authored by prominent researchers working across disciplines in the very important field of sustainable materials is intended to highlight the outstanding issues that must be addressed and provide an insight into the pathways towards solving them adopted by the sustainable materials community. In compiling this roadmap, we hope to aid the development of the wider sustainable materials research community, providing a guide for academia, industry, government, and funding agencies in this critically important and rapidly developing research space which is key to future sustainability.

Original language	English
Article number	032001
Number of pages	98
Journal	JPhys Materials
Volume	5
Issue number	3
DOIs	https://doi.org/10.1088/2515-7639/ac4ee5
Publication status	Published - 1 Jul 2022

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Titirici, M., Baird, S. G., Sparks, T. D., Yang, S. M., Brandt-Talbot, A., Hosseinaei, O., Harper, D. P., Parker, R. M., Vignolini, S., Berglund, L. A., Li, Y., Gao, H-L., Mao, L-B., Yu, S-H., Díez, N., Ferrero, G. A., Sevilla, M., Szilágyi, P. Á., Stubbs, C. J., ... Anderson, P. A. (2022). The sustainable materials roadmap. JPhys Materials, 5(3), [032001]. https://doi.org/10.1088/2515-7639/ac4ee5

@article{dda5fed315d44320aba38af481869325,

title = "The sustainable materials roadmap",

abstract = "Over the past 150 years, our ability to produce and transform engineered materials has been responsible for our current high standards of living, especially in developed economies. However, we must carefully think of the effects our addiction to creating and using materials at this fast rate will have on the future generations. The way we currently make and use materials detrimentally affects the planet Earth, creating many severe environmental problems. It affects the next generations by putting in danger the future of the economy, energy, and climate. We are at the point where something must drastically change, and it must change now. We must create more sustainable materials alternatives using natural raw materials and inspiration from nature while making sure not to deplete important resources, i.e. in competition with the food chain supply. We must use less materials, eliminate the use of toxic materials and create a circular materials economy where reuse and recycle are priorities. We must develop sustainable methods for materials recycling and encourage design for disassembly. We must look across the whole materials life cycle from raw resources till end of life and apply thorough life cycle assessments (LCAs) based on reliable and relevant data to quantify sustainability. We need to seriously start thinking of where our future materials will come from and how could we track them, given that we are confronted with resource scarcity and geographical constrains. This is particularly important for the development of new and sustainable energy technologies, key to our transition to net zero. Currently {\textquoteleft}critical materials{\textquoteright} are central components of sustainable energy systems because they are the best performing. A few examples include the permanent magnets based on rare earth metals (Dy, Nd, Pr) used in wind turbines, Li and Co in Li-ion batteries, Pt and Ir in fuel cells and electrolysers, Si in solar cells just to mention a few. These materials are classified as {\textquoteleft}critical{\textquoteright} by the European Union and Department of Energy. Except in sustainable energy, materials are also key components in packaging, construction, and textile industry along with many other industrial sectors. This roadmap authored by prominent researchers working across disciplines in the very important field of sustainable materials is intended to highlight the outstanding issues that must be addressed and provide an insight into the pathways towards solving them adopted by the sustainable materials community. In compiling this roadmap, we hope to aid the development of the wider sustainable materials research community, providing a guide for academia, industry, government, and funding agencies in this critically important and rapidly developing research space which is key to future sustainability.",

keywords = "research, project, materials, sustainable, sustainable materials",

author = "Magda Titirici and Baird, {Sterling G} and Sparks, {Taylor D} and Yang, {Shirley Min} and Agnieszka Brandt-Talbot and Omid Hosseinaei and Harper, {David P} and Parker, {Richard M} and Silvia Vignolini and Berglund, {Lars A} and Yuanyuan Li and Huai-Ling Gao and Li-Bo Mao and Shu-Hong Yu and Noel D{\'i}ez and Ferrero, {Guillermo A} and Marta Sevilla and Szil{\'a}gyi, {Petra {\'A}gota} and Stubbs, {Connor J} and Worch, {Joshua C} and Yunping Huang and Luscombe, {Christine K} and Koon-Yang Lee and Hui Luo and Platts, {M J} and Devendra Tiwari and Dmitry Kovalevskiy and Fermin, {David J.} and Heather Au and Hande Alptekin and Maria Crespo-Ribadeneyra and Ting, {Valeska P} and Tim-Patrick Fellinger and Jes{\'u}s Barrio and Olivia Westhead and Claudie Roy and Stephens, {Ifan E L} and Nicolae, {Sabina Alexandra} and Sarma, {Saurav Ch} and Oates, {Rose P} and Chen-Gang Wang and Zibiao Li and Loh, {Xian Jun} and Myers, {Rupert J.} and Niko Heeren and Alice Gr{\'e}goire and Cl{\'e}ment P{\'e}riss{\'e} and Xiaoying Zhao and Yael Vodovotz and Becky Earley and G{\"o}ran Finnveden and Anna Bj{\"o}rklund and Harper, {Gavin D J} and Allan Walton and Anderson, {Paul A}",

note = "Funding information: The authors would like to thank The Faraday Institution ReLiB Project Grant Numbers FIRG005 and FIRG006, the UKRI Interdisciplinary Circular Economy Centre for Technology Metals (Met4Tech) Grant No. EP/V011855/1 and the EPSRC Critical Elements and Materials Network (CREAM) EP/R020140/1 for providing financial assistance for this research.",

year = "2022",

month = jul,

day = "1",

doi = "10.1088/2515-7639/ac4ee5",

language = "English",

volume = "5",

journal = "JPhys Materials",

issn = "2515-7639",

publisher = "IOP Publishing Ltd.",

number = "3",

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Titirici, M, Baird, SG, Sparks, TD, Yang, SM, Brandt-Talbot, A, Hosseinaei, O, Harper, DP, Parker, RM, Vignolini, S, Berglund, LA, Li, Y, Gao, H-L, Mao, L-B, Yu, S-H, Díez, N, Ferrero, GA, Sevilla, M, Szilágyi, PÁ, Stubbs, CJ, Worch, JC, Huang, Y, Luscombe, CK, Lee, K-Y, Luo, H, Platts, MJ, Tiwari, D, Kovalevskiy, D, Fermin, DJ, Au, H, Alptekin, H, Crespo-Ribadeneyra, M, Ting, VP, Fellinger, T-P, Barrio, J, Westhead, O, Roy, C, Stephens, IEL, Nicolae, SA, Sarma, SC, Oates, RP, Wang, C-G, Li, Z, Loh, XJ, Myers, RJ, Heeren, N, Grégoire, A, Périssé, C, Zhao, X, Vodovotz, Y, Earley, B, Finnveden, G, Björklund, A, Harper, GDJ, Walton, A & Anderson, PA 2022, 'The sustainable materials roadmap', JPhys Materials, vol. 5, no. 3, 032001. https://doi.org/10.1088/2515-7639/ac4ee5

TY - JOUR

T1 - The sustainable materials roadmap

AU - Titirici, Magda

AU - Baird, Sterling G

AU - Sparks, Taylor D

AU - Yang, Shirley Min

AU - Brandt-Talbot, Agnieszka

AU - Hosseinaei, Omid

AU - Harper, David P

AU - Parker, Richard M

AU - Vignolini, Silvia

AU - Berglund, Lars A

AU - Li, Yuanyuan

AU - Gao, Huai-Ling

AU - Mao, Li-Bo

AU - Yu, Shu-Hong

AU - Díez, Noel

AU - Ferrero, Guillermo A

AU - Sevilla, Marta

AU - Szilágyi, Petra Ágota

AU - Stubbs, Connor J

AU - Worch, Joshua C

AU - Huang, Yunping

AU - Luscombe, Christine K

AU - Lee, Koon-Yang

AU - Luo, Hui

AU - Platts, M J

AU - Tiwari, Devendra

AU - Kovalevskiy, Dmitry

AU - Fermin, David J.

AU - Au, Heather

AU - Alptekin, Hande

AU - Crespo-Ribadeneyra, Maria

AU - Ting, Valeska P

AU - Fellinger, Tim-Patrick

AU - Barrio, Jesús

AU - Westhead, Olivia

AU - Roy, Claudie

AU - Stephens, Ifan E L

AU - Nicolae, Sabina Alexandra

AU - Sarma, Saurav Ch

AU - Oates, Rose P

AU - Wang, Chen-Gang

AU - Li, Zibiao

AU - Loh, Xian Jun

AU - Myers, Rupert J.

AU - Heeren, Niko

AU - Grégoire, Alice

AU - Périssé, Clément

AU - Zhao, Xiaoying

AU - Vodovotz, Yael

AU - Earley, Becky

AU - Finnveden, Göran

AU - Björklund, Anna

AU - Harper, Gavin D J

AU - Walton, Allan

AU - Anderson, Paul A

N1 - Funding information: The authors would like to thank The Faraday Institution ReLiB Project Grant Numbers FIRG005 and FIRG006, the UKRI Interdisciplinary Circular Economy Centre for Technology Metals (Met4Tech) Grant No. EP/V011855/1 and the EPSRC Critical Elements and Materials Network (CREAM) EP/R020140/1 for providing financial assistance for this research.

PY - 2022/7/1

Y1 - 2022/7/1

N2 - Over the past 150 years, our ability to produce and transform engineered materials has been responsible for our current high standards of living, especially in developed economies. However, we must carefully think of the effects our addiction to creating and using materials at this fast rate will have on the future generations. The way we currently make and use materials detrimentally affects the planet Earth, creating many severe environmental problems. It affects the next generations by putting in danger the future of the economy, energy, and climate. We are at the point where something must drastically change, and it must change now. We must create more sustainable materials alternatives using natural raw materials and inspiration from nature while making sure not to deplete important resources, i.e. in competition with the food chain supply. We must use less materials, eliminate the use of toxic materials and create a circular materials economy where reuse and recycle are priorities. We must develop sustainable methods for materials recycling and encourage design for disassembly. We must look across the whole materials life cycle from raw resources till end of life and apply thorough life cycle assessments (LCAs) based on reliable and relevant data to quantify sustainability. We need to seriously start thinking of where our future materials will come from and how could we track them, given that we are confronted with resource scarcity and geographical constrains. This is particularly important for the development of new and sustainable energy technologies, key to our transition to net zero. Currently ‘critical materials’ are central components of sustainable energy systems because they are the best performing. A few examples include the permanent magnets based on rare earth metals (Dy, Nd, Pr) used in wind turbines, Li and Co in Li-ion batteries, Pt and Ir in fuel cells and electrolysers, Si in solar cells just to mention a few. These materials are classified as ‘critical’ by the European Union and Department of Energy. Except in sustainable energy, materials are also key components in packaging, construction, and textile industry along with many other industrial sectors. This roadmap authored by prominent researchers working across disciplines in the very important field of sustainable materials is intended to highlight the outstanding issues that must be addressed and provide an insight into the pathways towards solving them adopted by the sustainable materials community. In compiling this roadmap, we hope to aid the development of the wider sustainable materials research community, providing a guide for academia, industry, government, and funding agencies in this critically important and rapidly developing research space which is key to future sustainability.

AB - Over the past 150 years, our ability to produce and transform engineered materials has been responsible for our current high standards of living, especially in developed economies. However, we must carefully think of the effects our addiction to creating and using materials at this fast rate will have on the future generations. The way we currently make and use materials detrimentally affects the planet Earth, creating many severe environmental problems. It affects the next generations by putting in danger the future of the economy, energy, and climate. We are at the point where something must drastically change, and it must change now. We must create more sustainable materials alternatives using natural raw materials and inspiration from nature while making sure not to deplete important resources, i.e. in competition with the food chain supply. We must use less materials, eliminate the use of toxic materials and create a circular materials economy where reuse and recycle are priorities. We must develop sustainable methods for materials recycling and encourage design for disassembly. We must look across the whole materials life cycle from raw resources till end of life and apply thorough life cycle assessments (LCAs) based on reliable and relevant data to quantify sustainability. We need to seriously start thinking of where our future materials will come from and how could we track them, given that we are confronted with resource scarcity and geographical constrains. This is particularly important for the development of new and sustainable energy technologies, key to our transition to net zero. Currently ‘critical materials’ are central components of sustainable energy systems because they are the best performing. A few examples include the permanent magnets based on rare earth metals (Dy, Nd, Pr) used in wind turbines, Li and Co in Li-ion batteries, Pt and Ir in fuel cells and electrolysers, Si in solar cells just to mention a few. These materials are classified as ‘critical’ by the European Union and Department of Energy. Except in sustainable energy, materials are also key components in packaging, construction, and textile industry along with many other industrial sectors. This roadmap authored by prominent researchers working across disciplines in the very important field of sustainable materials is intended to highlight the outstanding issues that must be addressed and provide an insight into the pathways towards solving them adopted by the sustainable materials community. In compiling this roadmap, we hope to aid the development of the wider sustainable materials research community, providing a guide for academia, industry, government, and funding agencies in this critically important and rapidly developing research space which is key to future sustainability.

KW - research

KW - project

KW - materials

KW - sustainable

KW - sustainable materials

U2 - 10.1088/2515-7639/ac4ee5

DO - 10.1088/2515-7639/ac4ee5

M3 - Review article

VL - 5

JO - JPhys Materials

JF - JPhys Materials

SN - 2515-7639

IS - 3

M1 - 032001

ER -

The sustainable materials roadmap

Abstract

UN SDGs

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