Journal Article10.1002/anie.202307728
Boosting the "Solid-Liquid-Solid" Conversion Reaction via Bifunctional Carbonate-Based Electrolyte for Ultra-long-life Potassium-Sulfur Batteries.
Shufen Ye,Nana Yao,Xiang Chen,Mingze Ma,Lifeng Wang,Zhihao Chen,Yuxiu Yao,Qiang Zhang,Yan Yu +8 more
- 14 Sep 2023
pp e202307728-e202307728
10
TL;DR: Boosting the "Solid-Liquid-Solid" Conversion Reaction in K-S batteries by regulating polysulfide dissolution and inhibiting dendrite growth through a bifunctional carbonate-based electrolyte.
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Abstract: Potassium-sulfur (K-S) batteries have attracted wide attention owing to their high theoretical energy density and low cost. However, the intractable shuttle effect of K polysulfides results in poor cyclability of K-S batteries, which severely limits their practical application. Herein, a bifunctional concentrated electrolyte (3 mol L-1 potassium bis(trifluoromethanesulfonyl)imide in ethylene carbonate (EC)) with high ionic conductivity and low viscosity is developed to regulate the dissolution behavior of polysulfides and induce uniform K deposition. The organic groups in the cathode electrolyte interphase layer derived from EC can effectively block the polysulfide shuttle and realize a "solid-liquid-solid" reaction mechanism. The KF-riched solid-electrolyte interphase inhibits K dendrite growth during cycling. As a result, the achieved K-S batteries display a high reversible capacity of 654 mAh g-1 at 0.5 A g-1 after 800 cycles and a long lifespan over 2000 cycles at 1 A g-1.
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Citations
A P2/P3 Biphasic Layered Oxide Composite as a High-Energy and Long-Cycle-Life Cathode for Potassium-Ion Batteries.
Liping Duan,Caoyang Shao,Jiaying Liao,Lili Song,Yingna Zhang,Renke Li,Shaohua Guo,Xiaosi Zhou,Haoshen Zhou +8 more
- 05 Mar 2024
TL;DR: A P2/P3 biphasic layered oxide composite is designed and synthesized as a high-energy and long-cycle-life cathode for potassium-ion batteries, exhibiting a large discharge capacity and remarkable energy density of 321 Wh kg -1.
28
Tunable Interfacial Electric Field-Mediated Cobalt-Doped FeSe/Fe3Se4 Heterostructure for High-Efficiency Potassium Storage.
Lili Song,Shilin Zhang,Liping Duan,Renke Li,Yifan Xu,Jiaying Liao,Liang Sun,Xiaosi Zhou,Zaiping Guo +8 more
- 25 Apr 2024
TL;DR: High-efficiency potassium storage is achieved by quantifying and tuning the interfacial electric field (IEF) in a cobalt-doped FeSe/Fe3Se4 heterostructure. The IEF is increased via Co doping, improving electron transport and potassium adsorption capacity. The optimized anode exhibits superior rate capability and long cycle lifespan.
21
Electrolyte Intermolecular Interaction Mediated Nonflammable Potassium-Ion Sulfur Batteries
Honghong Liang,Pushpendra Kumar,Zenghong Ma,Fei Zhao,Huhu Cheng,Hongliang Xie,Z. Cao,Luigi Cavallo,Qian Li,Jun Ming +9 more
11
The role of electrocatalytic materials for developing post-lithium metal||sulfur batteries
Chao Ye,Huan Li,Yujie Chen,Junnan Hao,Jiahao Liu,Jieqiong Shan,Shi Zhang Qiao +6 more
TL;DR: Post-Li metal||S batteries have high theoretical specific energy, but their practical implementation is hindered by insufficient understanding of cell parameters and sulfur electrocatalytic conversion mechanisms.
Tunable Interfacial Electric Field‐Mediated Cobalt‐Doped FeSe/Fe3Se4 Heterostructure for High‐Efficiency Potassium Storage
Lili Song,Shilin Zhang,Liping Duan,Ren‐Ke Li,Yifan Xu,Jiaying Liao,Liang Sun,Xiaosi Zhou,Zaiping Guo +8 more
TL;DR: High-efficiency potassium storage achieved through tunable interfacial electric field in undifferentiated cobalt-doped FeSe/Fe3Se4 heterostructure.
5
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