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| Main Authors: | , , , , , , , , |
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| Format: | Preprint |
| Published: |
2026
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2605.26727 |
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| _version_ | 1866914602943512576 |
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| author | Catalina, Sofia K. Frohna, Kyle Thompson, Willow Harmon, Katherine J. Yoon, Dasol Wang, Jianbo Ophus, Colin Congreve, Daniel N. Chueh, William C. |
| author_facet | Catalina, Sofia K. Frohna, Kyle Thompson, Willow Harmon, Katherine J. Yoon, Dasol Wang, Jianbo Ophus, Colin Congreve, Daniel N. Chueh, William C. |
| contents | Operando microscopy has unveiled key mechanistic insights in battery materials during early cycling, but long-term characterization to unveil material evolution, degradation, and failure remain limited. To address this gap, we develop a custom operando optical microscope that captures images across hundreds of cycles and hours using optically accessible, anode-free pouch cells. We image through-plane, bulk-representative electrodeposition behavior of aqueous tin metal anodes, which are promising due to their high energy density but whose reactivity limits practical cycle life. We show that substrate governs the morphology and stability of plated tin, particularly at high plated capacities. Specifically, copper substrates exhibit a multi-stage tin growth mode, which results in high overpotentials and irreversible active material loss at high plated capacities. In contrast, graphite substrates display a single-stage growth mode with slower kinetics. Using this insight, we balance performance and stability to demonstrate a high-utilization (70%, 630 mAh g$^{-1}_{Sn}$) porous graphite substrate Sn anode with high efficiency and long lifetime. Our results underscore the importance of material and device optimization guided by operando characterization across device lifetime with broad applicability to electrochemical systems. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2605_26727 |
| institution | arXiv |
| publishDate | 2026 |
| record_format | arxiv |
| spellingShingle | Visualizing Degradation in Anode-Free High-Utilization Aqueous Batteries Across Cell Lifetime Catalina, Sofia K. Frohna, Kyle Thompson, Willow Harmon, Katherine J. Yoon, Dasol Wang, Jianbo Ophus, Colin Congreve, Daniel N. Chueh, William C. Materials Science Chemical Physics Optics Operando microscopy has unveiled key mechanistic insights in battery materials during early cycling, but long-term characterization to unveil material evolution, degradation, and failure remain limited. To address this gap, we develop a custom operando optical microscope that captures images across hundreds of cycles and hours using optically accessible, anode-free pouch cells. We image through-plane, bulk-representative electrodeposition behavior of aqueous tin metal anodes, which are promising due to their high energy density but whose reactivity limits practical cycle life. We show that substrate governs the morphology and stability of plated tin, particularly at high plated capacities. Specifically, copper substrates exhibit a multi-stage tin growth mode, which results in high overpotentials and irreversible active material loss at high plated capacities. In contrast, graphite substrates display a single-stage growth mode with slower kinetics. Using this insight, we balance performance and stability to demonstrate a high-utilization (70%, 630 mAh g$^{-1}_{Sn}$) porous graphite substrate Sn anode with high efficiency and long lifetime. Our results underscore the importance of material and device optimization guided by operando characterization across device lifetime with broad applicability to electrochemical systems. |
| title | Visualizing Degradation in Anode-Free High-Utilization Aqueous Batteries Across Cell Lifetime |
| topic | Materials Science Chemical Physics Optics |
| url | https://arxiv.org/abs/2605.26727 |