Roadmap on Li-ion battery manufacturing research

Patrick S Grant; David Greenwood; Kunal Pardikar; Rachel Smith; Thomas Entwistle; Laurence A Middlemiss; Glen Murray; Serena A Cussen; Michael J. Lain; M J Capener; Mark Copley; Carl D Reynolds; Sam D Hare; Mark J H Simmons; Emma Kendrick; Stanislaw P Zankowski; Samuel Wheeler; Pengcheng Zhu; Peter R Slater; Ye Shui Zhang; Andrew R T Morrison; Will Dawson; Juntao Li; Paul R Shearing; Dan J L Brett; Guillaume Matthews; Ruihuan Ge; Ross Drummond; Eloise C Tredenick; Chuan Cheng; Stephen R Duncan; Adam M Boyce; Mona Faraji-Niri; James Marco; Luis A Roman-Ramirez; Charlotte Harper; Paul Blackmore; Tim Shelley; Ahmad Mohsseni; Denis J Cumming

doi:10.1088/2515-7655/ac8e30

Roadmap on Li-ion battery manufacturing research

Patrick S Grant, David Greenwood, Kunal Pardikar, Rachel Smith, Thomas Entwistle, Laurence A Middlemiss, Glen Murray, Serena A Cussen, Michael J. Lain, M J Capener, Mark Copley, Carl D Reynolds, Sam D Hare, Mark J H Simmons, Emma Kendrick, Stanislaw P Zankowski, Samuel Wheeler, Pengcheng Zhu, Peter R Slater, Ye Shui ZhangAndrew R T Morrison, Will Dawson, Juntao Li, Paul R Shearing, Dan J L Brett, Guillaume Matthews, Ruihuan Ge, Ross Drummond, Eloise C Tredenick, Chuan Cheng, Stephen R Duncan, Adam M Boyce, Mona Faraji-Niri, James Marco, Luis A Roman-Ramirez, Charlotte Harper, Paul Blackmore, Tim Shelley, Ahmad Mohsseni, Denis J Cumming

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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.

Original language	English
Article number	042006
Number of pages	58
Journal	JPhys Energy
Volume	4
Issue number	4
DOIs	https://doi.org/10.1088/2515-7655/ac8e30
Publication status	Published - 7 Nov 2022

Keywords

Li-ion
Roadmap
battery
coating
electrode
machine learning
manufacturing
metrology

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10.1088/2515-7655/ac8e30Licence: Creative Commons: Attribution (CC BY)

GrantP2022RoadmapFinal published version, 9.17 MBLicence: Creative Commons: Attribution (CC BY)

Cite this

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., Reynolds, C. D., Hare, S. D., Simmons, M. J. H., Kendrick, E., Zankowski, S. P., Wheeler, S., Zhu, P., Slater, P. R., ... Cumming, D. J. (2022). Roadmap on Li-ion battery manufacturing research. JPhys Energy, 4(4), Article 042006. https://doi.org/10.1088/2515-7655/ac8e30

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title = "Roadmap on Li-ion battery manufacturing research",

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.",

keywords = "Li-ion, Roadmap, battery, coating, electrode, machine learning, manufacturing, metrology",

author = "Grant, {Patrick S} and David Greenwood and Kunal Pardikar and Rachel Smith and Thomas Entwistle and Middlemiss, {Laurence A} and Glen Murray and Cussen, {Serena A} and Lain, {Michael J.} and Capener, {M J} and Mark Copley and Reynolds, {Carl D} and Hare, {Sam D} and Simmons, {Mark J H} and Emma Kendrick and Zankowski, {Stanislaw P} and Samuel Wheeler and Pengcheng Zhu and Slater, {Peter R} and Zhang, {Ye Shui} and Morrison, {Andrew R T} and Will Dawson and Juntao Li and Shearing, {Paul R} and Brett, {Dan J L} and Guillaume Matthews and Ruihuan Ge and Ross Drummond and Tredenick, {Eloise C} and Chuan Cheng and Duncan, {Stephen R} and Boyce, {Adam M} and Mona Faraji-Niri and James Marco and Roman-Ramirez, {Luis A} and Charlotte Harper and Paul Blackmore and Tim Shelley and Ahmad Mohsseni and Cumming, {Denis J}",

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month = nov,

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doi = "10.1088/2515-7655/ac8e30",

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Grant, PS, Greenwood, D, Pardikar, K, Smith, R, Entwistle, T, Middlemiss, LA, Murray, G, Cussen, SA, Lain, MJ, Capener, MJ, Copley, M, Reynolds, CD , Hare, SD , Simmons, MJH , Kendrick, E, Zankowski, SP, Wheeler, S, Zhu, P , Slater, PR, Zhang, YS, Morrison, ART, Dawson, W, Li, J, Shearing, PR, Brett, DJL, Matthews, G, Ge, R, Drummond, R, Tredenick, EC, Cheng, C, Duncan, SR, Boyce, AM, Faraji-Niri, M, Marco, J, Roman-Ramirez, LA, Harper, C, Blackmore, P, Shelley, T, Mohsseni, A & Cumming, DJ 2022, 'Roadmap on Li-ion battery manufacturing research', JPhys Energy, vol. 4, no. 4, 042006. https://doi.org/10.1088/2515-7655/ac8e30

TY - JOUR

T1 - Roadmap on Li-ion battery manufacturing research

AU - Grant, Patrick S

AU - Greenwood, David

AU - Pardikar, Kunal

AU - Smith, Rachel

AU - Entwistle, Thomas

AU - Middlemiss, Laurence A

AU - Murray, Glen

AU - Cussen, Serena A

AU - Lain, Michael J.

AU - Capener, M J

AU - Copley, Mark

AU - Reynolds, Carl D

AU - Hare, Sam D

AU - Simmons, Mark J H

AU - Kendrick, Emma

AU - Zankowski, Stanislaw P

AU - Wheeler, Samuel

AU - Zhu, Pengcheng

AU - Slater, Peter R

AU - Zhang, Ye Shui

AU - Morrison, Andrew R T

AU - Dawson, Will

AU - Li, Juntao

AU - Shearing, Paul R

AU - Brett, Dan J L

AU - Matthews, Guillaume

AU - Ge, Ruihuan

AU - Drummond, Ross

AU - Tredenick, Eloise C

AU - Cheng, Chuan

AU - Duncan, Stephen R

AU - Boyce, Adam M

AU - Faraji-Niri, Mona

AU - Marco, James

AU - Roman-Ramirez, Luis A

AU - Harper, Charlotte

AU - Blackmore, Paul

AU - Shelley, Tim

AU - Mohsseni, Ahmad

AU - Cumming, Denis J

PY - 2022/11/7

Y1 - 2022/11/7

N2 - 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.

AB - 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.

KW - Li-ion

KW - Roadmap

KW - battery

KW - coating

KW - electrode

KW - machine learning

KW - manufacturing

KW - metrology

U2 - 10.1088/2515-7655/ac8e30

DO - 10.1088/2515-7655/ac8e30

M3 - Review article

SN - 2515-7655

VL - 4

JO - JPhys Energy

JF - JPhys Energy

IS - 4

M1 - 042006

ER -

Roadmap on Li-ion battery manufacturing research

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Keywords

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