_version_ 1866917283689922560
author Rahe, Christiane
Ditler, Heinrich
Tegetmeyer-Kleine, Thorsten
Flügel, Marius
Waldmann, Thomas
Mehrens, Margret Wohlfahrt
Schleker, Philipp
Jakes, Peter
Wolff, Beatrice
Granwehr, Josef
Eichel, Rüdiger-A.
Vacík, Jiří
Ceccio, Giovanni
Cannavo, Antonino
Pivarníková, Ivana
Gilles, Ralph
Müller-Buschbaum, Peter
Mikitisin, Adrian
Mayer, Joachim
Noyong, Michael
Simon, Ulrich
Bolsinger, Marius
Knoblauch, Volker
Sauer, Dirk Uwe
author_facet Rahe, Christiane
Ditler, Heinrich
Tegetmeyer-Kleine, Thorsten
Flügel, Marius
Waldmann, Thomas
Mehrens, Margret Wohlfahrt
Schleker, Philipp
Jakes, Peter
Wolff, Beatrice
Granwehr, Josef
Eichel, Rüdiger-A.
Vacík, Jiří
Ceccio, Giovanni
Cannavo, Antonino
Pivarníková, Ivana
Gilles, Ralph
Müller-Buschbaum, Peter
Mikitisin, Adrian
Mayer, Joachim
Noyong, Michael
Simon, Ulrich
Bolsinger, Marius
Knoblauch, Volker
Sauer, Dirk Uwe
contents Lithium (Li) plating on graphite is a significant degradation mechanism in Li-ion batteries. While numerous experimental techniques have been used to study Li plating in laboratory cells, investigations of commercial high-energy cells often rely on electrochemical methods. Here we present and classify various methods for detecting Li plating on a commercial A123 pouch cell. In a round robin study across multiple battery research laboratories, Li-plated graphitic electrode material was analyzed using electrochemical, microscopic, and spectroscopic methods capable of detecting metallic Li deposits. After cell opening, their overall distribution on the anode surface was examined using a flatbed scanner to ensure comparability of the samples. Optical and electron microscopy provided detailed surface and, in combination with a focused ion beam, subsurface structure and morphology. Spectroscopic methods confirmed the presence and onset of plated Li with varying sensitivity. Moreover, spectroscopic and imaging techniques were combined correlatively where possible. Availability and measurement duration of each technique was compared. Optical methods are fast and easy to use; thus, they are recommended for most samples, with spectroscopic confirmation reserved for reference samples. This multimodal study demonstrates a range of methods that can be used alone or in combination to qualitatively or quantitatively detect Li-plating.
format Preprint
id arxiv_https___arxiv_org_abs_2602_17455
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Multi-Method Li Plating Characterization of a Commercial 26 Ah Li-Ion Pouch-Cell
Rahe, Christiane
Ditler, Heinrich
Tegetmeyer-Kleine, Thorsten
Flügel, Marius
Waldmann, Thomas
Mehrens, Margret Wohlfahrt
Schleker, Philipp
Jakes, Peter
Wolff, Beatrice
Granwehr, Josef
Eichel, Rüdiger-A.
Vacík, Jiří
Ceccio, Giovanni
Cannavo, Antonino
Pivarníková, Ivana
Gilles, Ralph
Müller-Buschbaum, Peter
Mikitisin, Adrian
Mayer, Joachim
Noyong, Michael
Simon, Ulrich
Bolsinger, Marius
Knoblauch, Volker
Sauer, Dirk Uwe
Materials Science
Lithium (Li) plating on graphite is a significant degradation mechanism in Li-ion batteries. While numerous experimental techniques have been used to study Li plating in laboratory cells, investigations of commercial high-energy cells often rely on electrochemical methods. Here we present and classify various methods for detecting Li plating on a commercial A123 pouch cell. In a round robin study across multiple battery research laboratories, Li-plated graphitic electrode material was analyzed using electrochemical, microscopic, and spectroscopic methods capable of detecting metallic Li deposits. After cell opening, their overall distribution on the anode surface was examined using a flatbed scanner to ensure comparability of the samples. Optical and electron microscopy provided detailed surface and, in combination with a focused ion beam, subsurface structure and morphology. Spectroscopic methods confirmed the presence and onset of plated Li with varying sensitivity. Moreover, spectroscopic and imaging techniques were combined correlatively where possible. Availability and measurement duration of each technique was compared. Optical methods are fast and easy to use; thus, they are recommended for most samples, with spectroscopic confirmation reserved for reference samples. This multimodal study demonstrates a range of methods that can be used alone or in combination to qualitatively or quantitatively detect Li-plating.
title Multi-Method Li Plating Characterization of a Commercial 26 Ah Li-Ion Pouch-Cell
topic Materials Science
url https://arxiv.org/abs/2602.17455