Sustainable release of LiNO3 in carbonate electrolytes for stable lithium metal anodes

Siyu Li; Yuhang Liu; Ke Wang; Xiaoqi Hu; Wanqing Guan; Zhuzhu Du; Hongfang Du; Wei Ai

doi:10.1039/d3cc05859j

Sustainable release of LiNO₃ in carbonate electrolytes for stable lithium metal anodes

Siyu Li, Yuhang Liu, Ke Wang, Xiaoqi Hu, Wanqing Guan, Zhuzhu Du, Hongfang Du, Wei Ai

Institute of Flexible Electronics

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

4 Scopus citations

Abstract

LiNO₃ is recognized as an effective additive, forming a dense, nitrogen-rich solid electrolyte interphase (SEI) on lithium's surface, which safeguards it from parasitic reactions. However, its use is limited due to the poor solubility in carbonate electrolytes. Herein, we introduce a bilayer separator designed to release LiNO₃ sustainably. This continual release not only alters the chemistry of the SEI but also replenishes the additives that are depleted during battery cycling, thereby enhancing the durability of the modified interphase. This strategy effectively curtails Li dendrite formation, significantly enhancing the longevity of Li|LiFePO₄ batteries, evidenced by an impressive 85% capacity retention after 800 cycles. This research offers a compelling remedy to the longstanding challenge of incorporating LiNO₃ in carbonate electrolytes.

Original language	English
Pages (from-to)	2649-2652
Number of pages	4
Journal	Chemical Communications
Volume	60
Issue number	19
DOIs	https://doi.org/10.1039/d3cc05859j
State	Published - 7 Feb 2024

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abstract = "LiNO3 is recognized as an effective additive, forming a dense, nitrogen-rich solid electrolyte interphase (SEI) on lithium's surface, which safeguards it from parasitic reactions. However, its use is limited due to the poor solubility in carbonate electrolytes. Herein, we introduce a bilayer separator designed to release LiNO3 sustainably. This continual release not only alters the chemistry of the SEI but also replenishes the additives that are depleted during battery cycling, thereby enhancing the durability of the modified interphase. This strategy effectively curtails Li dendrite formation, significantly enhancing the longevity of Li|LiFePO4 batteries, evidenced by an impressive 85% capacity retention after 800 cycles. This research offers a compelling remedy to the longstanding challenge of incorporating LiNO3 in carbonate electrolytes.",

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AU - Li, Siyu

AU - Liu, Yuhang

AU - Wang, Ke

AU - Hu, Xiaoqi

AU - Guan, Wanqing

AU - Du, Zhuzhu

AU - Du, Hongfang

AU - Ai, Wei

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N2 - LiNO3 is recognized as an effective additive, forming a dense, nitrogen-rich solid electrolyte interphase (SEI) on lithium's surface, which safeguards it from parasitic reactions. However, its use is limited due to the poor solubility in carbonate electrolytes. Herein, we introduce a bilayer separator designed to release LiNO3 sustainably. This continual release not only alters the chemistry of the SEI but also replenishes the additives that are depleted during battery cycling, thereby enhancing the durability of the modified interphase. This strategy effectively curtails Li dendrite formation, significantly enhancing the longevity of Li|LiFePO4 batteries, evidenced by an impressive 85% capacity retention after 800 cycles. This research offers a compelling remedy to the longstanding challenge of incorporating LiNO3 in carbonate electrolytes.

AB - LiNO3 is recognized as an effective additive, forming a dense, nitrogen-rich solid electrolyte interphase (SEI) on lithium's surface, which safeguards it from parasitic reactions. However, its use is limited due to the poor solubility in carbonate electrolytes. Herein, we introduce a bilayer separator designed to release LiNO3 sustainably. This continual release not only alters the chemistry of the SEI but also replenishes the additives that are depleted during battery cycling, thereby enhancing the durability of the modified interphase. This strategy effectively curtails Li dendrite formation, significantly enhancing the longevity of Li|LiFePO4 batteries, evidenced by an impressive 85% capacity retention after 800 cycles. This research offers a compelling remedy to the longstanding challenge of incorporating LiNO3 in carbonate electrolytes.

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Sustainable release of LiNO₃ in carbonate electrolytes for stable lithium metal anodes

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