Perspectives for next generation lithium-ion battery cathode materials

Associated organisational unit

MSF PhDs Cohort 2 (2019/20)

Electronic data

FutureCat Roadmap
Accepted author manuscript, 1.7 MB, PDF document
Available under license: CC BY: Creative Commons Attribution 4.0 International License

Text available via DOI:

https://doi.org/10.1063/5.0051092
Final published version
Available under license: CC BY: Creative Commons Attribution 4.0 International License

View graph of relations

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Published

Standard

Perspectives for next generation lithium-ion battery cathode materials. / Booth, S.G.; Nedoma, A.J.; Anthonisamy, N.N. et al.
In: APL Materials, Vol. 9, No. 10, 109201, 31.10.2021.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Booth, SG, Nedoma, AJ, Anthonisamy, NN, Baker, PJ, Boston, R, Bronstein, H, Clarke, SJ, Cussen, EJ, Daramalla, V, De Volder, M, Dutton, SE, Falkowski, V, Fleck, NA, Geddes, HS, Gollapally, N, Goodwin, AL, Griffin, JM , Haworth, AR, Hayward, MA, Hull, S, Inkson, BJ, Johnston, BJ, Lu, Z, MacManus-Driscoll, JL, Martínez De Irujo Labalde, X, McClelland, I, McCombie, K, Murdock, B, Nayak, D, Park, S, Pérez, GE, Pickard, CJ, Piper, LFJ, Playford, HY, Price, S, Scanlon, DO, Stallard, JC, Tapia-Ruiz, N, West, AR, Wheatcroft, L, Wilson, M, Zhang, L, Zhi, X, Zhu, B & Cussen, SA 2021, 'Perspectives for next generation lithium-ion battery cathode materials', APL Materials, vol. 9, no. 10, 109201. https://doi.org/10.1063/5.0051092

APA

Booth, S. G., Nedoma, A. J., Anthonisamy, N. N., Baker, P. J., Boston, R., Bronstein, H., Clarke, S. J., Cussen, E. J., Daramalla, V., De Volder, M., Dutton, S. E., Falkowski, V., Fleck, N. A., Geddes, H. S., Gollapally, N., Goodwin, A. L., Griffin, J. M., Haworth, A. R., Hayward, M. A., ... Cussen, S. A. (2021). Perspectives for next generation lithium-ion battery cathode materials. APL Materials, 9(10), Article 109201. https://doi.org/10.1063/5.0051092

Vancouver

Booth SG, Nedoma AJ, Anthonisamy NN, Baker PJ, Boston R, Bronstein H et al. Perspectives for next generation lithium-ion battery cathode materials. APL Materials. 2021 Oct 31;9(10):109201. Epub 2021 Oct 5. doi: 10.1063/5.0051092

Author

Booth, S.G. ; Nedoma, A.J. ; Anthonisamy, N.N. et al. / Perspectives for next generation lithium-ion battery cathode materials. In: APL Materials. 2021 ; Vol. 9, No. 10.

Bibtex

@article{05b9059967b04181aa9579b9f1ea231d,

title = "Perspectives for next generation lithium-ion battery cathode materials",

abstract = "Transitioning to electrified transport requires improvements in sustainability, energy density, power density, lifetime, and approved the cost of lithium-ion batteries, with significant opportunities remaining in the development of next-generation cathodes. This presents a highly complex, multiparameter optimization challenge, where developments in cathode chemical design and discovery, theoretical and experimental understanding, structural and morphological control, synthetic approaches, and cost reduction strategies can deliver performance enhancements required in the near- and longer-term. This multifaceted challenge requires an interdisciplinary approach to solve, which has seen the establishment of numerous academic and industrial consortia around the world to focus on cathode development. One such example is the Next Generation Lithium-ion Cathode Materials project, FutureCat, established by the UK{\textquoteright}s Faraday Institution for electrochemical energy storage research in 2019, aimed at developing our understanding of existing and newly discovered cathode chemistries. Here, we present our perspective on persistent fundamental challenges, including protective coatings and additives to extend lifetime and improve interfacial ion transport, the design of existing and the discovery of new cathode materials where cation and cation-plus-anion redox-activity can be exploited to increase energy density, the application of earth-abundant elements that could ultimately reduce costs, and the delivery of new electrode topologies resistant to fracture which can extend battery lifetime",

author = "S.G. Booth and A.J. Nedoma and N.N. Anthonisamy and P.J. Baker and R. Boston and H. Bronstein and S.J. Clarke and E.J. Cussen and V. Daramalla and {De Volder}, M. and S.E. Dutton and V. Falkowski and N.A. Fleck and H.S. Geddes and N. Gollapally and A.L. Goodwin and J.M. Griffin and A.R. Haworth and M.A. Hayward and S. Hull and B.J. Inkson and B.J. Johnston and Z. Lu and J.L. MacManus-Driscoll and {Mart{\'i}nez De Irujo Labalde}, X. and I. McClelland and K. McCombie and B. Murdock and D. Nayak and S. Park and G.E. P{\'e}rez and C.J. Pickard and L.F.J. Piper and H.Y. Playford and S. Price and D.O. Scanlon and J.C. Stallard and N. Tapia-Ruiz and A.R. West and L. Wheatcroft and M. Wilson and L. Zhang and X. Zhi and B. Zhu and S.A. Cussen",

year = "2021",

month = oct,

day = "31",

doi = "10.1063/5.0051092",

language = "English",

volume = "9",

journal = "APL Materials",

issn = "2166-532X",

publisher = "American Institute of Physics",

number = "10",

}

RIS

TY - JOUR

T1 - Perspectives for next generation lithium-ion battery cathode materials

AU - Booth, S.G.

AU - Nedoma, A.J.

AU - Anthonisamy, N.N.

AU - Baker, P.J.

AU - Boston, R.

AU - Bronstein, H.

AU - Clarke, S.J.

AU - Cussen, E.J.

AU - Daramalla, V.

AU - De Volder, M.

AU - Dutton, S.E.

AU - Falkowski, V.

AU - Fleck, N.A.

AU - Geddes, H.S.

AU - Gollapally, N.

AU - Goodwin, A.L.

AU - Griffin, J.M.

AU - Haworth, A.R.

AU - Hayward, M.A.

AU - Hull, S.

AU - Inkson, B.J.

AU - Johnston, B.J.

AU - Lu, Z.

AU - MacManus-Driscoll, J.L.

AU - Martínez De Irujo Labalde, X.

AU - McClelland, I.

AU - McCombie, K.

AU - Murdock, B.

AU - Nayak, D.

AU - Park, S.

AU - Pérez, G.E.

AU - Pickard, C.J.

AU - Piper, L.F.J.

AU - Playford, H.Y.

AU - Price, S.

AU - Scanlon, D.O.

AU - Stallard, J.C.

AU - Tapia-Ruiz, N.

AU - West, A.R.

AU - Wheatcroft, L.

AU - Wilson, M.

AU - Zhang, L.

AU - Zhi, X.

AU - Zhu, B.

AU - Cussen, S.A.

PY - 2021/10/31

Y1 - 2021/10/31

N2 - Transitioning to electrified transport requires improvements in sustainability, energy density, power density, lifetime, and approved the cost of lithium-ion batteries, with significant opportunities remaining in the development of next-generation cathodes. This presents a highly complex, multiparameter optimization challenge, where developments in cathode chemical design and discovery, theoretical and experimental understanding, structural and morphological control, synthetic approaches, and cost reduction strategies can deliver performance enhancements required in the near- and longer-term. This multifaceted challenge requires an interdisciplinary approach to solve, which has seen the establishment of numerous academic and industrial consortia around the world to focus on cathode development. One such example is the Next Generation Lithium-ion Cathode Materials project, FutureCat, established by the UK’s Faraday Institution for electrochemical energy storage research in 2019, aimed at developing our understanding of existing and newly discovered cathode chemistries. Here, we present our perspective on persistent fundamental challenges, including protective coatings and additives to extend lifetime and improve interfacial ion transport, the design of existing and the discovery of new cathode materials where cation and cation-plus-anion redox-activity can be exploited to increase energy density, the application of earth-abundant elements that could ultimately reduce costs, and the delivery of new electrode topologies resistant to fracture which can extend battery lifetime

AB - Transitioning to electrified transport requires improvements in sustainability, energy density, power density, lifetime, and approved the cost of lithium-ion batteries, with significant opportunities remaining in the development of next-generation cathodes. This presents a highly complex, multiparameter optimization challenge, where developments in cathode chemical design and discovery, theoretical and experimental understanding, structural and morphological control, synthetic approaches, and cost reduction strategies can deliver performance enhancements required in the near- and longer-term. This multifaceted challenge requires an interdisciplinary approach to solve, which has seen the establishment of numerous academic and industrial consortia around the world to focus on cathode development. One such example is the Next Generation Lithium-ion Cathode Materials project, FutureCat, established by the UK’s Faraday Institution for electrochemical energy storage research in 2019, aimed at developing our understanding of existing and newly discovered cathode chemistries. Here, we present our perspective on persistent fundamental challenges, including protective coatings and additives to extend lifetime and improve interfacial ion transport, the design of existing and the discovery of new cathode materials where cation and cation-plus-anion redox-activity can be exploited to increase energy density, the application of earth-abundant elements that could ultimately reduce costs, and the delivery of new electrode topologies resistant to fracture which can extend battery lifetime

U2 - 10.1063/5.0051092

DO - 10.1063/5.0051092

M3 - Journal article

VL - 9

JO - APL Materials

JF - APL Materials

SN - 2166-532X

IS - 10

M1 - 109201

ER -

Research

Associated organisational unit

Electronic data

Links

Text available via DOI: