Roadmap on Li-ion battery manufacturing research
Journal article
Grant, P.S., Greenwood, D., Pardikar, K., Smith, R., Entwistle, T., Middlemiss, L.A., Murray, G., Cussen, S.A., Lain, M.J., Capener, M.J., Copley, M., Reynold, C.D., Hare, S.D., Simmons, M.J.H., Kendrick, E., Zankowski, S.P., Wheeler, S., Pengcheng, Z., Slater, P.R., Zhang, Y.S., Morrison, A.R.T., Dawson, W., Li, J., Shearling, P., Brett, D.J.L., Matthews, G., Ge, R., Drummond, R., Tredenick, E., Cheng, C., Duncan, S.R., Boyce, A.M., Faraji-Niri, M., Marco, J., Roman Ramirez, L., Harper, C., Blackmore, P., Shelley, T., Mohsseni, A. and Cumming, D.J. (2022). Roadmap on Li-ion battery manufacturing research. Journal of Physics: Energy. 4 (4). https://doi.org/10.1088/2515-7655/ac8e30
Authors | Grant, P.S., Greenwood, D., Pardikar, K., Smith, R., Entwistle, T., Middlemiss, L.A., Murray, G., Cussen, S.A., Lain, M.J., Capener, M.J., Copley, M., Reynold, C.D., Hare, S.D., Simmons, M.J.H., Kendrick, E., Zankowski, S.P., Wheeler, S., Pengcheng, Z., Slater, P.R., Zhang, Y.S., Morrison, A.R.T., Dawson, W., Li, J., Shearling, P., Brett, D.J.L., Matthews, G., Ge, R., Drummond, R., Tredenick, E., Cheng, C., Duncan, S.R., Boyce, A.M., Faraji-Niri, M., Marco, J., Roman Ramirez, L., Harper, C., Blackmore, P., Shelley, T., Mohsseni, A. and Cumming, D.J. |
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Abstract | Growth in the Li-ion battery market continues to accelerate, driven primarily by the increasing need for economic energy storage for electric vehicles. Electrode manufacture by slurry casting is the first main step in cell production but much of the manufacturing optimisation is based on trial and error, know-how and individual expertise. Advancing manufacturing science that underpins Li-ion battery electrode production is critical to adding to the electrode manufacturing value chain. Overcoming the current barriers in electrode manufacturing requires advances in materials, manufacturing technology, in-line process metrology and data analytics, and can enable improvements in cell performance, quality, safety and process sustainability. In this roadmap we explore the research opportunities to improve each stage of the electrode manufacturing process, from materials synthesis through to electrode calendering. We highlight the role of new process technology, such as dry processing, and advanced electrode design supported through electrode level, physics-based modelling. Progress in data driven models of electrode manufacturing processes is also considered. We conclude there is a growing need for innovations in process metrology to aid fundamental understanding and to enable feedback control, an opportunity for electrode design to reduce trial and error, and an urgent imperative to improve the sustainability of manufacture. |
Year | 2022 |
Journal | Journal of Physics: Energy |
Journal citation | 4 (4) |
Publisher | Institute of Physics |
Digital Object Identifier (DOI) | https://doi.org/10.1088/2515-7655/ac8e30 |
Publication dates | |
07 Nov 2022 | |
Publication process dates | |
Accepted | 31 Aug 2022 |
Deposited | 21 Nov 2022 |
Publisher's version | License File Access Level Open |
https://openresearch.lsbu.ac.uk/item/929w4
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