Future material demand for automotive lithium-based batteries

The world is shifting to electric vehicles to mitigate climate change. Here, we quantify the future demand for key battery materials, considering potential electric vehicle fleet and battery chemistry developments as well as second-use and recycling of electric vehicle batteries. We find that in a lithium nickel cobalt manganese oxide dominated battery scenario, demand is estimated to increase by factors of 18–20 for lithium, 17–19 for cobalt, 28–31 for nickel, and 15–20 for most other materials from 2020 to 2050, requiring a drastic expansion of lithium, cobalt, and nickel supply chains and likely additional resource discovery. However, uncertainties are large. Key factors are the development of the electric vehicles fleet and battery capacity requirements per vehicle. If other battery chemistries were used at large scale, e.g. lithium iron phosphate or novel lithium-sulphur or lithium-air batteries, the demand for cobalt and nickel would be substantially smaller. Closed-loop recycling plays a minor, but increasingly important role for reducing primary material demand until 2050, however, advances in recycling are necessary to economically recover battery-grade materials from end-of-life batteries. Second-use of electric vehicles batteries further delays recycling potentials. Lithium-ion-based batteries are a key enabler for the global shift towards electric vehicles. Here, considering developments in battery chemistry and number of electric vehicles, analysis reveals the increasing amounts of lithium, cobalt and nickel that could be needed.

[1]  David F. Pyke,et al.  Electric vehicles: The role and importance of standards in an emerging market , 2010 .

[2]  Kevin G. Gallagher,et al.  Modeling the performance and cost of lithium-ion batteries for electric-drive vehicles. , 2011 .

[3]  Jun Bi,et al.  Predicting future quantities of obsolete household appliances in Nanjing by a stock-based model , 2011 .

[4]  Daniel B. Müller,et al.  Stock dynamics for forecasting material flows—Case study for housing in The Netherlands , 2006 .

[5]  Rolf Widmer,et al.  Sustainable governance of scarce metals: the case of lithium. , 2013, The Science of the total environment.

[6]  Qingbin Song,et al.  Material flow analysis on critical raw materials of lithium-ion batteries in China , 2019, Journal of Cleaner Production.

[7]  – Declaration of Intent " Become competitive in the global battery sector to drive e ‐ mobility forward " , 2016 .

[8]  Alexander M. Bradshaw,et al.  Supply risks associated with lithium-ion battery materials , 2018 .

[9]  E. Olivetti,et al.  Lithium-Ion Battery Supply Chain Considerations: Analysis of Potential Bottlenecks in Critical Metals , 2017 .

[10]  Rebecca E. Ciez,et al.  Examining different recycling processes for lithium-ion batteries , 2019, Nature Sustainability.

[11]  Fuquan Zhao,et al.  Impact of transport electrification on critical metal sustainability with a focus on the heavy-duty segment , 2019, Nature Communications.

[12]  L. Gaines Profitable Recycling of Low-Cobalt Lithium-Ion Batteries Will Depend on New Process Developments , 2019 .

[13]  Ulrich Eberle,et al.  Sustainable transportation based on electric vehicle concepts: a brief overview , 2010 .

[14]  Marco Pierini,et al.  Innovative composites and hybrid materials for electric vehicles lightweight design in a sustainability perspective , 2017 .

[15]  Jie Deng,et al.  Electric Vehicles Batteries: Requirements and Challenges , 2020 .

[16]  Alves Dias Patricia,et al.  Cobalt: demand-supply balances in the transition to electric mobility , 2018 .

[17]  Roger Pye Focus on Europe , 1979 .

[18]  A. Ghahreman,et al.  Review of Lithium Production and Recovery from Minerals, Brines, and Lithium-Ion Batteries , 2019, Mineral Processing and Extractive Metallurgy Review.

[19]  Fuquan Zhao,et al.  Selection of Lithium-ion Battery Technologies for Electric Vehicles under China’s New Energy Vehicle Credit Regulation , 2019, Energy Procedia.

[20]  Nenad G. Nenadic,et al.  Environmental trade-offs across cascading lithium-ion battery life cycles , 2015, The International Journal of Life Cycle Assessment.

[21]  Callie W. Babbitt,et al.  A future perspective on lithium-ion battery waste flows from electric vehicles , 2014 .

[22]  G. Benveniste,et al.  Comparison of the state of Lithium-Sulphur and lithium-ion batteries applied to electromobility. , 2018, Journal of environmental management.

[23]  Benoit Nemery,et al.  Sustainability of artisanal mining of cobalt in DR Congo , 2018, Nature Sustainability.

[24]  Samveg Saxena,et al.  Quantifying EV battery end-of-life through analysis of travel needs with vehicle powertrain models , 2015 .

[25]  R. Stolkin,et al.  Recycling lithium-ion batteries from electric vehicles , 2019, Nature.

[26]  Feixiang Wu,et al.  Li-ion battery materials: present and future , 2015 .

[27]  Hyung Chul Kim,et al.  Economic and Environmental Feasibility of Second-Life Lithium-ion Batteries as Fast Charging Energy Storage. , 2020, Environmental science & technology.

[28]  Peggy Zwolinski,et al.  An agile model for the eco-design of electric vehicle Li-ion batteries , 2019, CIRP Annals.

[29]  Eric Wood,et al.  Comparison of Plug-In Hybrid Electric Vehicle Battery Life Across Geographies and Drive Cycles , 2012 .

[30]  Jeremy Neubauer,et al.  Identifying and Overcoming Critical Barriers to Widespread Second Use of PEV Batteries , 2015 .

[31]  Lluc Canals Casals,et al.  Second life batteries lifespan: Rest of useful life and environmental analysis. , 2019, Journal of environmental management.

[32]  Ahmad T. Mayyas,et al.  The case for recycling: Overview and challenges in the material supply chain for automotive li-ion batteries , 2019, Sustainable Materials and Technologies.

[33]  Daniel B. Müller,et al.  Modeling the potential impact of lithium recycling from EV batteries on lithium demand: A dynamic MFA approach , 2018, Resources, Conservation and Recycling.

[34]  René Kleijn,et al.  Identifying supply risks by mapping the cobalt supply chain , 2020, Resources, Conservation and Recycling.

[35]  Nakia L. Simon,et al.  Recycling End-of-Life Electric Vehicle Lithium-Ion Batteries , 2019, Joule.

[36]  Stanislav I. Stoliarov,et al.  Experimental investigation of cascading failure in 18650 lithium ion cell arrays: Impact of cathode chemistry , 2020 .

[37]  Emmanuel C. Alozie,et al.  Promises and Challenges , 2015 .

[38]  Jens F. Peters,et al.  The Issue of Metal Resources in Li-Ion Batteries for Electric Vehicles , 2018 .

[39]  M. Huijbregts,et al.  Net emission reductions from electric cars and heat pumps in 59 world regions over time , 2020, Nature Sustainability.

[40]  C. Buisman,et al.  Challenges in Metal Recycling , 2012 .

[41]  Marcel Weil,et al.  Potential metal requirement of active materials in lithium-ion battery cells of electric vehicles and its impact on reserves: Focus on Europe , 2015 .

[42]  T. Prior,et al.  Resource depletion, peak minerals and the implications for sustainable resource management , 2012 .

[43]  Steven B. Young,et al.  A cascaded life cycle: reuse of electric vehicle lithium-ion battery packs in energy storage systems , 2015, The International Journal of Life Cycle Assessment.

[44]  Thomas H. Bradley,et al.  Review of hybrid, plug-in hybrid, and electric vehicle market modeling Studies , 2013 .

[45]  R. Cabeza,et al.  Present and Future , 2008 .

[46]  Linda Gaines,et al.  Lithium-ion battery recycling processes: Research towards a sustainable course , 2018, Sustainable Materials and Technologies.

[47]  Jun Lu,et al.  Batteries and fuel cells for emerging electric vehicle markets , 2018 .

[48]  寛 大岩 早期関節リウマチ:brief overview , 2018 .

[49]  Jeremy Neubauer,et al.  The impact of range anxiety and home, workplace, and public charging infrastructure on simulated battery electric vehicle lifetime utility , 2014 .

[50]  Alexandre Ponrouch,et al.  Post-Li batteries: promises and challenges , 2019, Philosophical Transactions of the Royal Society A.

[51]  Manbir S. Sodhi,et al.  Assessment of social sustainability hotspots in the supply chain of lithium-ion batteries , 2019, Procedia CIRP.

[52]  S. Pauliuk,et al.  Scenarios for Demand Growth of Metals in Electricity Generation Technologies, Cars, and Electronic Appliances , 2018, Environmental science & technology.

[53]  Masahiro Oguchi,et al.  Regional and longitudinal estimation of product lifespan distribution: a case study for automobiles and a simplified estimation method. , 2015, Environmental science & technology.

[54]  Yang Jin,et al.  High-purity electrolytic lithium obtained from low-purity sources using solid electrolyte , 2020, Nature Sustainability.