Structural response of silicon-containing graphite anodes on lithium intercalation

T. Hölderle; D. Petz; V. Kochetov; V. Baran; A. Kriele; Z. Hegedüs; U. Lienert; M. Avdeev; P. Müller-Buschbaum; A. Senyshyn

doi:10.1016/j.ensm.2025.104042

Structural response of silicon-containing graphite anodes on lithium intercalation

T. Hölderle, D. Petz, V. Kochetov, V. Baran, A. Kriele, Z. Hegedüs, U. Lienert, M. Avdeev, P. Müller-Buschbaum, A. Senyshyn

Chair of Functional Materials

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

Abstract

This study investigates the impact of silicon content in the graphite anode of cylinder-type Li-ion batteries using operando neutron powder diffraction techniques. A batch of four different Li-ion cells is analyzed, with a focus on the structural response of active cell components during electrochemical cycling. The results indicate that high silicon content in the graphite anode causes a delay in the initial lithiation of graphite, shifting it towards higher voltages independent of the cell's internal resistance. Differential voltage, incremental capacity analyses and quantitative energy-dispersive X-ray spectroscopy, corroborate these structural changes. Additionally, X-ray diffraction computed tomography using a µm-sized synchrotron beam revealed local structural degradation and lithiation inhomogeneity in the high silicon content cells during cycling.

Original language	English
Article number	104042
Journal	Energy Storage Materials
Volume	75
DOIs	https://doi.org/10.1016/j.ensm.2025.104042
State	Published - Feb 2025

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title = "Structural response of silicon-containing graphite anodes on lithium intercalation",

abstract = "This study investigates the impact of silicon content in the graphite anode of cylinder-type Li-ion batteries using operando neutron powder diffraction techniques. A batch of four different Li-ion cells is analyzed, with a focus on the structural response of active cell components during electrochemical cycling. The results indicate that high silicon content in the graphite anode causes a delay in the initial lithiation of graphite, shifting it towards higher voltages independent of the cell's internal resistance. Differential voltage, incremental capacity analyses and quantitative energy-dispersive X-ray spectroscopy, corroborate these structural changes. Additionally, X-ray diffraction computed tomography using a µm-sized synchrotron beam revealed local structural degradation and lithiation inhomogeneity in the high silicon content cells during cycling.",

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T1 - Structural response of silicon-containing graphite anodes on lithium intercalation

AU - Hölderle, T.

AU - Petz, D.

AU - Kochetov, V.

AU - Baran, V.

AU - Kriele, A.

AU - Hegedüs, Z.

AU - Lienert, U.

AU - Avdeev, M.

AU - Müller-Buschbaum, P.

AU - Senyshyn, A.

PY - 2025/2

Y1 - 2025/2

N2 - This study investigates the impact of silicon content in the graphite anode of cylinder-type Li-ion batteries using operando neutron powder diffraction techniques. A batch of four different Li-ion cells is analyzed, with a focus on the structural response of active cell components during electrochemical cycling. The results indicate that high silicon content in the graphite anode causes a delay in the initial lithiation of graphite, shifting it towards higher voltages independent of the cell's internal resistance. Differential voltage, incremental capacity analyses and quantitative energy-dispersive X-ray spectroscopy, corroborate these structural changes. Additionally, X-ray diffraction computed tomography using a µm-sized synchrotron beam revealed local structural degradation and lithiation inhomogeneity in the high silicon content cells during cycling.

AB - This study investigates the impact of silicon content in the graphite anode of cylinder-type Li-ion batteries using operando neutron powder diffraction techniques. A batch of four different Li-ion cells is analyzed, with a focus on the structural response of active cell components during electrochemical cycling. The results indicate that high silicon content in the graphite anode causes a delay in the initial lithiation of graphite, shifting it towards higher voltages independent of the cell's internal resistance. Differential voltage, incremental capacity analyses and quantitative energy-dispersive X-ray spectroscopy, corroborate these structural changes. Additionally, X-ray diffraction computed tomography using a µm-sized synchrotron beam revealed local structural degradation and lithiation inhomogeneity in the high silicon content cells during cycling.

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DO - 10.1016/j.ensm.2025.104042

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VL - 75

JO - Energy Storage Materials

JF - Energy Storage Materials

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Structural response of silicon-containing graphite anodes on lithium intercalation

Abstract

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