Journal
ADVANCED MATERIALS
Volume 33, Issue 38, Pages -Publisher
WILEY-V C H VERLAG GMBH
DOI: 10.1002/adma.202102034
Keywords
bifunctional solvents; lithium-sulfur batteries; long-term cycling; low-density electrolytes; ultrathin lithium
Categories
Funding
- Center for Clean Energy
- China Postdoctoral Science Foundation [2019M660846]
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The research introduces a bifunctional fluorinated silane-based electrolyte with a density of 1.0 g mL(-1), which reduces lithium metal loss rate and extends the cycle life of lithium-sulfur batteries. Compared with conventional electrolytes, this electrolyte not only lowers the electrolyte/cell capacity ratio, but also enhances stability under limited lithium amounts.
The lithium metal anode (LMA) instability at deep cycle with high utilization is a crucial barrier for developing lithium (Li) metal batteries, resulting in excessive Li inventory and electrolyte demand. This issue becomes more severe in capacity-type lithium-sulfur (Li-S) batteries. High-concentration or localized high-concentration electrolytes are noted as effective strategies to stabilize Li metal but usually lead to a high electrolyte density (>1.4 g mL(-1)). Here we propose a bifunctional fluorinated silane-based electrolyte with a low density of 1.0 g mL(-1) that not only is much lighter than conventional electrolytes (approximate to 1.2 g mL(-1)) but also form a robust solid electrolyte interface to minimize Li depletion. Therefore, the Li loss rate is reduced over 4.5-fold with the proposed electrolyte relative to its conventional counterpart. When paired with onefold excess LMA at the electrolyte weight/cell capacity (E/C) ratio of 4.5 g Ah(-1), the Li-S pouch cell using our electrolyte can survive for 103 cycles, much longer than with the conventional electrolyte (38 cycles). This demonstrates that our electrolyte not only reduces the E/C ratio but also enhances the cyclic stability of Li-S batteries under limited Li amounts.
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