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26.01.2024 13:09

How Silicon Can Improve the Performance of Solid-State Batteries

Caroline Link Presse, Kommunikation und Marketing
Justus-Liebig-Universität Gießen

    Researchers from Germany and Canada analyze the potential of silicon as an alternative electrode material - publication in "Nature Materials"

    High-performance batteries are required for a wide range of applications and demand is growing rapidly. This is why the research and development of electrochemical energy storage systems, including for electromobility, is one of the most important areas of work in materials science worldwide. The focus is not only on the charging capacities and charging speeds of the batteries, but also on the life span, safety, availability of raw materials and the CO2 balance. Against this background, the chemists Dr. Hanyu Huo and Prof. Dr. Jürgen Janek (both Justus Liebig University Giessen), the physicist Prof. Dr. Kerstin Volz (University of Marburg), the materials scientist Dierk Raabe (Max Planck Institute for Iron Research, Düsseldorf) and the theoretical material scientist Prof. Dr. Chandra Veer Singh (University of Toronto, Canada) and their teams have investigated the properties of silicon anodes in solid-state batteries. They have come to the conclusion that these anodes have great potential to improve the performance of these batteries. Their findings on the stability, chemomechanics and ageing behavior of silicon electrodes have now been published in the journal "Nature Materials".
    For the investigations, the research team combined various experimental and theoretical methods to quantitatively evaluate the transport of lithium in the electrode, the strong mechanical volume change of silicon during the charging and discharging processes and the reaction with the solid electrolyte. "This comprehensive and fundamental analysis is an important step towards the possible use of silicon as an electrode material in solid-state batteries, which is currently the focus of intensive international research," says Prof. Janek, one of the authors of the study.
    The solid-state battery is an advanced concept of the lithium-ion battery, which currently functions with a liquid, organic electrolyte. The ultimate target is to use a solid electrolyte, which promises even better storage properties, longer service life and increased safety. The development of solid-state batteries has been the subject of intensive research worldwide for around ten years, and the Giessen team led by Prof. Jürgen Janek is one of the leading academic groups in this field.
    During the charging process of a battery, lithium is absorbed in the negative electrode, the anode. "This causes the silicon at the anode of the battery to expand by several hundred percent, which leads to considerable mechanical problems in a solid-state battery," explains Prof. Janek. "In addition, the favored solid electrolytes react with the stored lithium, which also leads to capacity losses. Our recently published work evaluates these aspects quantitatively in detail for the first time."
    In the development of more powerful solid-state batteries that can compete with conventional lithium-ion batteries, the anode should be formed by a material with a particularly high storage capacity - ideally a lithium metal. However, this carries the risk of internal short circuits under operating conditions, so silicon is being investigated as an alternative with a similarly high storage capacity. "Our results show that the silicon anode has considerable potential for use in solid-state batteries, which could be exploited by cleverly adapting the interfaces in the battery," says Prof. Janek. Additional material concepts are required to overcome the chemical and chemomechanical ageing of silicon anodes. One part of this solution could be a polymer interlayer, as the research team from Germany and Canada has already been able to demonstrate.
    Prof. Janek and Prof. Volz have been working closely together for several years on research into new battery materials. The work that has now been published required the use of additional theoretical methods available at the MPI for Metals Research in Prof. Raabe's department (chemomechanical phase field simulations) and Prof. Singh's working group at the University of Toronto (DFT calculations).

    About the Authors
    The authors of the study are among the leading international scientists in physical and inorganic chemical materials research. Prof. Dr. Jürgen Janek has a chair for Physical Chemistry at Justus Liebig University Giessen (JLU) since 1999. He is the director of the Center for Materials Research at JLU and is one of the two scientific directors of the BELLA laboratory at the Karlsruhe Institute of Technology. Prof. Janek is a member of the German National Academy of Sciences Leopoldina and was recently awarded an honorary doctorate from Delft University of Technology for his work and, together with Prof. Kerstin Volz, was awarded the first Leopoldina Greve Prize for fundamental scientific work on materials for high-performance batteries.
    Prof. Dr. Kerstin Volz has been Professor of Physics at the University of Marburg since 2009 and heads the Scientific Center for Materials Science (WZMW) there. She is also the spokesperson for the Collaborative Research Center 1083 "Structure and Dynamics of Inner Interfaces". Together with her working group, she researches the manufacture and structure of novel functional materials.
    Prof. Dr. Dierk Raabe has been Director at the Max Planck Institute for Iron Research since 1999, where he conducts research into computational materials science, sustainable metallurgy, phase transformations and hydrogen. He has received the Gottfried Wilhelm Leibniz Prize, two ERC Advanced Grants and the Acta Materialia Gold Medal Award. He is a professor at RWTH Aachen University, honorary professor at KU Leuven in Belgium, honorary doctor of the Norwegian University of Science and Technology and member of the National Academy Leopoldina.
    Prof. Chandra Veer Singh is professor of Materials Science and Engineering at University of Toronto. He is the director of the Computational Materials Engineering lab, which is focused on the utilization of atomistic simulations and machine learning for the design and development of new materials for sustainable energy and lightweight transportation applications.

    Campus Research Focus “Material, Molecule and Energy”
    The development of future-oriented technologies and materials is the central goal of the joint research activities of the researchers in the campus research focus "Materials, Molecule and Energy"


    Wissenschaftliche Ansprechpartner:

    Prof. Dr. Dr. h.c. Jürgen Janek
    Institute of Physical Chemistry
    Justus Liebig University Giessen
    Phone: 0049 641 99-34500
    E-Mail: juergen.janek@phys.chemie.uni-giessen.de

    Prof. Dr. Kerstin Volz
    Scientific Center for Materials Science
    University of Marburg
    Phone: 0049 6421 28-22297
    E-Mail: volz@staff.uni-marburg.de


    Originalpublikation:

    Chemo-Mechanical Failure Mechanisms of the Silicon Anode in Solid-State Batteries: H. Huo, M. Jiang, Y. Bai, S. Ahmed, K. Volz, H. Hartmann, A. Henss, C. Veer Sing, D. Raabe, J. Janek. Nature Materials (2024)
    https://www.nature.com/articles/s41563-023-01792-x


    Weitere Informationen:

    http://www.fcmh.de/mat


    Bilder

    Battery research at JLU: Preparing to analyse the material structure of a battery during operation using X-ray diffraction.
    Battery research at JLU: Preparing to analyse the material structure of a battery during operation u ...
    JLU / Rolf K. Wegst


    Merkmale dieser Pressemitteilung:
    Journalisten, Wissenschaftler
    Chemie, Elektrotechnik, Physik / Astronomie, Werkstoffwissenschaften
    überregional
    Forschungsergebnisse, Kooperationen
    Englisch


     

    Battery research at JLU: Preparing to analyse the material structure of a battery during operation using X-ray diffraction.


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