Evolving better solvate electrolytes for lithium secondary batteries

Frederik Philippi; Maleen Middendorf; Keisuke Shigenobu; Yuna Matsuyama; Oriele Palumbo; David Pugh; Taku Sudoh; Kaoru Dokko; Masayoshi Watanabe; Monika Schönhoff; Wataru Shinoda; Kazuhide Ueno

doi:10.1039/d4sc01492h

Evolving better solvate electrolytes for lithium secondary batteries

Frederik Philippi^*, Maleen Middendorf, Keisuke Shigenobu, Yuna Matsuyama, Oriele Palumbo, David Pugh, Taku Sudoh, Kaoru Dokko, Masayoshi Watanabe, Monika Schönhoff, Wataru Shinoda, Kazuhide Ueno

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

The overall performance of lithium batteries remains unmatched to this date. Decades of optimisation have resulted in long-lasting batteries with high energy density suitable for mobile applications. However, the electrolytes used at present suffer from low lithium transference numbers, which induces concentration polarisation and reduces efficiency of charging and discharging. Here we show how targeted modifications can be used to systematically evolve anion structural motifs which can yield electrolytes with high transference numbers. Using a multidisciplinary combination of theoretical and experimental approaches, we screened a large number of anions. Thus, we identified anions which reach lithium transference numbers around 0.9, surpassing conventional electrolytes. Specifically, we find that nitrile groups have a coordination tendency similar to SO₂ and are capable of inducing the formation of Li⁺ rich clusters. In the bigger picture, we identified a balanced anion/solvent coordination tendency as one of the key design parameters.

Original language	English
Pages (from-to)	7342-7358
Number of pages	17
Journal	Chemical Science
Volume	15
Issue number	19
DOIs	https://doi.org/10.1039/d4sc01492h
Publication status	Published - 11 Apr 2024

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title = "Evolving better solvate electrolytes for lithium secondary batteries",

abstract = "The overall performance of lithium batteries remains unmatched to this date. Decades of optimisation have resulted in long-lasting batteries with high energy density suitable for mobile applications. However, the electrolytes used at present suffer from low lithium transference numbers, which induces concentration polarisation and reduces efficiency of charging and discharging. Here we show how targeted modifications can be used to systematically evolve anion structural motifs which can yield electrolytes with high transference numbers. Using a multidisciplinary combination of theoretical and experimental approaches, we screened a large number of anions. Thus, we identified anions which reach lithium transference numbers around 0.9, surpassing conventional electrolytes. Specifically, we find that nitrile groups have a coordination tendency similar to SO2 and are capable of inducing the formation of Li+ rich clusters. In the bigger picture, we identified a balanced anion/solvent coordination tendency as one of the key design parameters.",

author = "Frederik Philippi and Maleen Middendorf and Keisuke Shigenobu and Yuna Matsuyama and Oriele Palumbo and David Pugh and Taku Sudoh and Kaoru Dokko and Masayoshi Watanabe and Monika Sch{\"o}nhoff and Wataru Shinoda and Kazuhide Ueno",

note = "Funding Information: We would like to acknowledge funding by the Japan Society for the Promotion of Science (JSPS) in form of a JSPS International Research Fellowship and JSPS KAKENHI grants (Grant No. 22K19082, 22KJ1402 for K. S., 23KK0102, and 22F22775). The computation in this work was performed using the facilities of Research Centre for Computational Science, Okazaki, Japan (Project: 23-IMS-C095) and Supercomputer Centre, the Institute for Solid State Physics, the University of Tokyo. Maleen Middendorf is supported by the International Graduate School for Battery Chemistry, Characterization, Analysis, Recycling and Application (BACCARA), which is funded by the Ministry for Culture and Science of North Rhine Westphalia, Germany. We are grateful to Spyridon Koutsoukos for CHNS measurements, and Toru Ishikawa for many helpful demonstrations. Publisher Copyright: {\textcopyright} 2024 The Royal Society of Chemistry.",

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AU - Philippi, Frederik

AU - Middendorf, Maleen

AU - Shigenobu, Keisuke

AU - Matsuyama, Yuna

AU - Palumbo, Oriele

AU - Pugh, David

AU - Sudoh, Taku

AU - Dokko, Kaoru

AU - Watanabe, Masayoshi

AU - Schönhoff, Monika

AU - Shinoda, Wataru

AU - Ueno, Kazuhide

N1 - Funding Information: We would like to acknowledge funding by the Japan Society for the Promotion of Science (JSPS) in form of a JSPS International Research Fellowship and JSPS KAKENHI grants (Grant No. 22K19082, 22KJ1402 for K. S., 23KK0102, and 22F22775). The computation in this work was performed using the facilities of Research Centre for Computational Science, Okazaki, Japan (Project: 23-IMS-C095) and Supercomputer Centre, the Institute for Solid State Physics, the University of Tokyo. Maleen Middendorf is supported by the International Graduate School for Battery Chemistry, Characterization, Analysis, Recycling and Application (BACCARA), which is funded by the Ministry for Culture and Science of North Rhine Westphalia, Germany. We are grateful to Spyridon Koutsoukos for CHNS measurements, and Toru Ishikawa for many helpful demonstrations. Publisher Copyright: © 2024 The Royal Society of Chemistry.

PY - 2024/4/11

Y1 - 2024/4/11

N2 - The overall performance of lithium batteries remains unmatched to this date. Decades of optimisation have resulted in long-lasting batteries with high energy density suitable for mobile applications. However, the electrolytes used at present suffer from low lithium transference numbers, which induces concentration polarisation and reduces efficiency of charging and discharging. Here we show how targeted modifications can be used to systematically evolve anion structural motifs which can yield electrolytes with high transference numbers. Using a multidisciplinary combination of theoretical and experimental approaches, we screened a large number of anions. Thus, we identified anions which reach lithium transference numbers around 0.9, surpassing conventional electrolytes. Specifically, we find that nitrile groups have a coordination tendency similar to SO2 and are capable of inducing the formation of Li+ rich clusters. In the bigger picture, we identified a balanced anion/solvent coordination tendency as one of the key design parameters.

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Evolving better solvate electrolytes for lithium secondary batteries

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