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

Michael J. Lain; Geanina Apachitei; Luis Román-Ramírez; Mark Copley; James Marco

doi:10.1039/d2cp03094b

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

Michael J. Lain, Geanina Apachitei, Luis Román-Ramírez, Mark Copley, James Marco

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

3 Citations (Scopus)

Abstract

Join counting, a standard technique in spatial autocorrelation analysis, has been used to quantify the clustering of carbon, fluorine and sodium in cross-sectioned anode and cathode samples. The sample preparation and EDS mapping steps are sufficiently fast for every coating from two Design of Experiment (DoE) test matrices to be characterised. The results show two types of heterogeneity in material distribution; gradients across the coating from the current collector to the surface, and clustering. In the cathode samples, the carbon is more clustered than the fluorine, implying that the conductive carbon component is less well distributed than the binder. The results are correlated with input parameters systematically varied in the DoE coating blade gap, coating speed, and other output parameters coat weight, and electrochemical resistance.

Original language	English
Pages (from-to)	29999-30009
Number of pages	11
Journal	Physical Chemistry Chemical Physics
Volume	24
Issue number	48
DOIs	https://doi.org/10.1039/d2cp03094b https://doi.org/10.1039/d2cp03094b
Publication status	Published - 6 Dec 2022

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© 2022 The Royal Society of Chemistry.

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title = "Cross-sectional analysis of lithium ion electrodes using spatial autocorrelation techniques.",

abstract = "Join counting, a standard technique in spatial autocorrelation analysis, has been used to quantify the clustering of carbon, fluorine and sodium in cross-sectioned anode and cathode samples. The sample preparation and EDS mapping steps are sufficiently fast for every coating from two Design of Experiment (DoE) test matrices to be characterised. The results show two types of heterogeneity in material distribution; gradients across the coating from the current collector to the surface, and clustering. In the cathode samples, the carbon is more clustered than the fluorine, implying that the conductive carbon component is less well distributed than the binder. The results are correlated with input parameters systematically varied in the DoE coating blade gap, coating speed, and other output parameters coat weight, and electrochemical resistance.",

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AU - Lain, Michael J.

AU - Apachitei, Geanina

AU - Román-Ramírez, Luis

AU - Copley, Mark

AU - Marco, James

PY - 2022/12/6

Y1 - 2022/12/6

N2 - Join counting, a standard technique in spatial autocorrelation analysis, has been used to quantify the clustering of carbon, fluorine and sodium in cross-sectioned anode and cathode samples. The sample preparation and EDS mapping steps are sufficiently fast for every coating from two Design of Experiment (DoE) test matrices to be characterised. The results show two types of heterogeneity in material distribution; gradients across the coating from the current collector to the surface, and clustering. In the cathode samples, the carbon is more clustered than the fluorine, implying that the conductive carbon component is less well distributed than the binder. The results are correlated with input parameters systematically varied in the DoE coating blade gap, coating speed, and other output parameters coat weight, and electrochemical resistance.

AB - Join counting, a standard technique in spatial autocorrelation analysis, has been used to quantify the clustering of carbon, fluorine and sodium in cross-sectioned anode and cathode samples. The sample preparation and EDS mapping steps are sufficiently fast for every coating from two Design of Experiment (DoE) test matrices to be characterised. The results show two types of heterogeneity in material distribution; gradients across the coating from the current collector to the surface, and clustering. In the cathode samples, the carbon is more clustered than the fluorine, implying that the conductive carbon component is less well distributed than the binder. The results are correlated with input parameters systematically varied in the DoE coating blade gap, coating speed, and other output parameters coat weight, and electrochemical resistance.

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DO - 10.1039/d2cp03094b

M3 - Article

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VL - 24

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EP - 30009

JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

IS - 48

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

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