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

Publication dates
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.
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
Print	07 Nov 2022
Publication process dates
Accepted	31 Aug 2022
Deposited	21 Nov 2022
Publisher's version	Grant_2022_J._Phys._Energy_4_042006.pdf License CC BY 4.0 File Access Level Open

Permalink -

https://openresearch.lsbu.ac.uk/item/929w4

Download files

Publisher's version

	Grant_2022_J._Phys._Energy_4_042006.pdf
License: CC BY 4.0
File access level: Open

61
total views
36
total downloads
2
views this month
2
downloads this month

Export as

Related outputs

Maximizing Polypropylene Recovery from Waste Carpet Feedstock: A Solvent-Driven Pathway Towards Circular Economy

Salazar Salazar, H., Baragau, I., Lu, Z., Roman Ramirez, L. and Kellici, S. (2024). Maximizing Polypropylene Recovery from Waste Carpet Feedstock: A Solvent-Driven Pathway Towards Circular Economy. RSC Sustainability . https://doi.org/10.1039/D3SU00270E

Impact of Formulation and Slurry Properties on Lithium-ion Electrode Manufacturing

Reynolds, C., Niri, M.F., Hidalgo, M.F., Heymer, R., Roman, Luis, Alsofi, G., Khanom, H., Pye, B., Marco, J. and Kendrick, E. (2023). Impact of Formulation and Slurry Properties on Lithium-ion Electrode Manufacturing. Batteries & Supercaps. p. e202300396. https://doi.org/10.1002/batt.202300396

Vapor Equilibrium Data for the Binary Mixtures of Dimethyl Carbonate and Ethyl Methyl Carbonate in Compressed Carbon Dioxide

Jethwa, S.J., Roman Ramirez, L., Anderson, P.A. and Leeke, G.A. (2023). Vapor Equilibrium Data for the Binary Mixtures of Dimethyl Carbonate and Ethyl Methyl Carbonate in Compressed Carbon Dioxide. International Journal of Thermophysics. 44 (86). https://doi.org/10.1007/s10765-023-03186-2

Quantifying key factors for optimised manufacturing of Li-ion battery anode and cathode via artificial intelligence

Niri, M.F., Liu, K., Apachitei, G., Roman Ramirez, L., Lain, M., Widanage, D. and Marco, J. (2022). Quantifying key factors for optimised manufacturing of Li-ion battery anode and cathode via artificial intelligence. Energy and AI. 7, p. 100129. https://doi.org/10.1016/j.egyai.2021.100129

Cross-sectional analysis of lithium ion electrodes using spatial autocorrelation techniques.

Lain, M., Apachitei, G., Roman Ramirez, L., Copley, M. and Marco, James (2022). Cross-sectional analysis of lithium ion electrodes using spatial autocorrelation techniques. Physical chemistry chemical physics : PCCP. 24 (48), pp. 29999-30009. https://doi.org/10.1039/d2cp03094b

Systematic analysis of the impact of slurry coating on manufacture of Li-ion battery electrodes via explainable machine learning

Faraji Niri, M., Reynolds, C., Kendrick, E., Marco, J. and Roman Ramirez, L. (2022). Systematic analysis of the impact of slurry coating on manufacture of Li-ion battery electrodes via explainable machine learning. Energy Storage Materials. 51, pp. 223-238. https://doi.org/10.1016/j.ensm.2022.06.036

Design of experiments applied to lithium-ion batteries: A literature review

Roman-Ramirez, L.A. and Marco, J. (2022). Design of experiments applied to lithium-ion batteries: A literature review. Applied Energy. 320, p. 119305. https://doi.org/10.1016/j.apenergy.2022.119305

Methanolysis of Poly(lactic Acid) Using Catalyst Mixtures and the Kinetics of Methyl Lactate Production

Lamberti, Fabio M., Roman-Ramirez, L., Dove, A. and Wood, J. (2022). Methanolysis of Poly(lactic Acid) Using Catalyst Mixtures and the Kinetics of Methyl Lactate Production. Polymers. 14 (9), p. e1763. https://doi.org/10.3390/polym14091763

Effect of coating operating parameters on electrode physical characteristics and final electrochemical performance of lithium-ion batteries

Roman Ramirez, L., Apachitei G., Faraji-Niri M., Lain M., Widanage D. and Marco J. (2022). Effect of coating operating parameters on electrode physical characteristics and final electrochemical performance of lithium-ion batteries. International Journal of Energy and Environmental Engineering. https://doi.org/10.1007/s40095-022-00481-w

Comparative study on the hydrogenation of naphthalene over both Al2O3‑supported Pd and NiMo catalysts against a novel LDH-derived Ni-MMO-supported Mo catalyst

Claydon, R.M., Roman Ramirez, L. and Wood, J. (2021). Comparative study on the hydrogenation of naphthalene over both Al2O3‑supported Pd and NiMo catalysts against a novel LDH-derived Ni-MMO-supported Mo catalyst. ACS Omega. 6 (30), pp. 20053-20067. https://doi.org/10.1021/acsomega.1c03083

Machine learning for optimised and clean Li-ion battery manufacturing: Revealing the dependency between electrode and cell characteristics

Niri, M.F., Liu, K., Apachitei, G., Roman Ramirez, L., Lain, M., Widanage, D. and Marco, J. (2021). Machine learning for optimised and clean Li-ion battery manufacturing: Revealing the dependency between electrode and cell characteristics. Journal of Cleaner Production. 324, p. 129272. https://doi.org/10.1016/j.jclepro.2021.129272

Understanding the effect of coating-drying operating variables on electrode physical and electrochemical properties of lithium-ion batteries

Roman Ramirez, L., Apachitei, G., Faraji-Niri, M., Lain, M., Widanage, W.D. and Marco, J. (2021). Understanding the effect of coating-drying operating variables on electrode physical and electrochemical properties of lithium-ion batteries. Journal of Power Sources. 516, p. 230689. https://doi.org/10.1016/j.jpowsour.2021.230689

Experimental data of cathodes manufactured in a convective dryer at the pilot-plant scale, and charge and discharge capacities of half-coin lithium-ion cells.

Román-Ramírez, L.A., Apachitei, G., Faraji-Niri, M., Lain, M., Widanage, D. and Marco, J. (2021). Experimental data of cathodes manufactured in a convective dryer at the pilot-plant scale, and charge and discharge capacities of half-coin lithium-ion cells. Data in Brief. 40, p. 107720. https://doi.org/10.1016/j.dib.2021.107720

Kinetics of methyl lactate formation from the transesterification of polylactic acid catalyzed by Zn(II) complexes

Roman Ramirez, L., McKeown, P., Jones, M.D. and Wood, J. (2020). Kinetics of methyl lactate formation from the transesterification of polylactic acid catalyzed by Zn(II) complexes . ACS Omega. 5 (10), pp. 5556-5564. https://doi.org/10.1021/acsomega.0c00291

Evaluation of the Peng–Robinson and the Cubic-Plus-Association equations of state in modeling VLE of carboxylic acids with water

Roman Ramirez, L. and Leeke, G.A. (2020). Evaluation of the Peng–Robinson and the Cubic-Plus-Association equations of state in modeling VLE of carboxylic acids with water . International Journal of Thermophysics. 41 (51). https://doi.org/10.1007/s10765-020-02643-6

Chemical degradation of end-of-life poly(lactic acid) into methyl lactate by a Zn(II) complex

Roman Ramirez, L., McKeown, P., Shah, C., Abraham, J., Jones, M.D. and Wood, J. (2020). Chemical degradation of end-of-life poly(lactic acid) into methyl lactate by a Zn(II) complex. Industrial and Engineering Chemistry Research. 59 (54), pp. 11149-11156. https://doi.org/10.1021/acs.iecr.0c01122

Organocatalysis for versatile polymer degradation

Kamran, M., Davidson, M.G., Jones, M.D., Roman Ramirez, L. and Wood, J. (2020). Organocatalysis for versatile polymer degradation. Green Chemistry. 12. https://doi.org/10.1039/D0GC01252A

Kinetics of Alkyl Lactate Formation from the Alcoholysis of Poly(Lactic Acid)

Lamberti, F.M., Roman Ramirez, L., McKeown, P., Jones, M.D. and Wood, J. (2020). Kinetics of Alkyl Lactate Formation from the Alcoholysis of Poly(Lactic Acid) . Processes. 8 (2), p. 738. https://doi.org/10.3390/pr8060738

Ethyl Lactate Production from the Catalytic Depolymerisation of Post‑consumer Poly(lactic acid)

Roman Ramirez, L., Powders, M., McKeown, P., Jones, M.D. and Wood, J. (2020). Ethyl Lactate Production from the Catalytic Depolymerisation of Post‑consumer Poly(lactic acid). Journal of Polymers and the Environment. 28, pp. 2956-2964. https://doi.org/10.1007/s10924-020-01824-6

Evaluation of association schemes in the CPA and PC-SAFT equations of state in modeling VLE of organic acids + water systems

Roman Ramirez, L., Garcia-Sanchez, F. and Leeke, G.A. (2020). Evaluation of association schemes in the CPA and PC-SAFT equations of state in modeling VLE of organic acids + water systems. Chemical Engineering Communications. 208 (9), pp. 1313-1325. https://doi.org/10.1080/00986445.2020.1771323

Recycling of Bioplastics: Routes and Benefits

Lamberi, F.M., Roman Ramirez, L. and Wood, J. (2020). Recycling of Bioplastics: Routes and Benefits. Journal of Polymers and the Environment. 28, pp. 2551-2571. https://doi.org/10.1007/s10924-020-01795-8

Zinc complexes for PLA formation and chemical recycling

McKeown, P., Roman Ramirez, L., Bates, S., Wood, J. and Jones, M. (2019). Zinc complexes for PLA formation and chemical recycling . ChemSusChem. 12 (24), pp. 5233-5238. https://doi.org/10.1002/cssc.201902755

Poly(lactic acid) Degradation into Methyl Lactate Catalyzed by a Well-Defined Zn(II) Complex

Roman Ramirez, L., Mckeown, P., Jones, M.D. and Wood, J. (2019). Poly(lactic acid) Degradation into Methyl Lactate Catalyzed by a Well-Defined Zn(II) Complex. ACS Catalysis. 9 (1), pp. 409-416. https://doi.org/10.1021/acscatal.8b04863

P-x data of (acetic acid + water) at T = (412.6, 443.2, 483.2) K

Roman Ramirez, L. and Leeke, G.A. (2016). P-x data of (acetic acid + water) at T = (412.6, 443.2, 483.2) K . Journal of Chemical and Engineering Data. 61 (6), pp. 2078-2082. https://doi.org/10.1021/acs.jced.5b01104

Vapour-liquid equilibrium of propanoic acid+water at 423.2, 453.2 and 483.2K from 1.87 to 19.38bar. Experimental and modelling with PR, CPA, PC-SAFT and PCP-SAFT

Roman Ramirez, L., Garcia-Sanchez, F., Santos, R.C.D. and Leeke, G.A. (2015). Vapour-liquid equilibrium of propanoic acid+water at 423.2, 453.2 and 483.2K from 1.87 to 19.38bar. Experimental and modelling with PR, CPA, PC-SAFT and PCP-SAFT . Fluid Phase Equilibria. 388, pp. 151-159. https://doi.org/10.1016/j.fluid.2015.01.004

Modeling of asphaltene precipitation from n-alkane diluted heavy oils and bitumens using the PC-SAFT equation of state

Zúñiga-Hinojosa, M.A., Justo-Garcia, D.N., Aquino-Olivos, M.A., Roman Ramirez, L. and Garcia-Sanchez, F. (2014). Modeling of asphaltene precipitation from n-alkane diluted heavy oils and bitumens using the PC-SAFT equation of state. Fluid Phase Equilibria. 376, pp. 210-224. https://doi.org/10.1016/j.fluid.2014.06.004