Engineering Peculiar Cathode Electrolyte Interphase toward Sustainable and High‐Rate Li–S Batteries

The lithium–sulfur battery is considered to be one of the most promising rechargeable energy storage systems because of its high theoretical energy density. Unfortunately, the shuttle effect during cycling causes serious loss of sulfur species and corrosion of the lithium metal anode, resulting in severe capacity decay. This work proposes to completely suppress the shuttle effect of lithium polysulfides (LiPSs) without sacrificing the interfacial Li+ transport, through in situ construction of a compact cathode electrolyte interphase (CEI), which is formed of the reaction between vinylene carbonate (VC), bis(trifluoromethane)sulfonimide ions and LiPSs in a self‐limiting manner during the initial discharge process. Hence, the CEI‐confined sulfur cathode in the VC‐based electrolyte with a solid phase conversion mechanism delivers a long‐term cycling stability and high‐rate performance, as well as excellent performance under an extreme climate in a subzero temperature of −20 °C, limited lithium source with a low N/P ratio of 1.1, and even at mechanical mutilation. The present study reveals an appealing approach to tailor the composition and interfacial structure of sulfur cathodes by in situ construction of a robust, self‐healing, and high Li+ conductive CEI from the aspect of electrolyte, and thus completely solve the issue of the shuttle effect.

[1]  Changhong Wang,et al.  Cathode materials for single-phase solid-solid conversion Li-S batteries , 2022, Matter.

[2]  Chao Lai,et al.  Regulating liquid and solid-state electrolytes for solid-phase conversion in Li–S batteries , 2022, Chem.

[3]  Q. Zhang,et al.  A Solid-Phase Conversion Sulfur Cathode with Full Capacity Utilization and Superior Cycle Stability for Lithium-Sulfur Batteries. , 2022, Small.

[4]  Kyu-Nam Jung,et al.  Elastomeric electrolytes for high-energy solid-state lithium batteries , 2022, Nature.

[5]  Lixia Yuan,et al.  Insight into the Fading Mechanism of the Solid‐Conversion Sulfur Cathodes and Designing Long Cycle Lithium–Sulfur Batteries , 2021, Advanced Energy Materials.

[6]  Z. Bao,et al.  Steric Effect Tuned Ion Solvation Enabling Stable Cycling of High-Voltage Lithium Metal Battery. , 2021, Journal of the American Chemical Society.

[7]  Jiujun Zhang,et al.  Wide Working Temperature Range Rechargeable Lithium–Sulfur Batteries: A Critical Review , 2021, Advanced Functional Materials.

[8]  W. Goddard,et al.  Effects of High and Low Salt Concentrations in Electrolytes at Lithium-Metal Anode Surfaces Using DFT-ReaxFF Hybrid Molecular Dynamics Method. , 2021, The journal of physical chemistry letters.

[9]  W. Goddard,et al.  The DFT-ReaxFF Hybrid Reactive Dynamics Method with Application to the Reductive Decomposition Reaction of the TFSI and DOL Electrolyte at a Lithium-Metal Anode Surface. , 2021, The journal of physical chemistry letters.

[10]  Xiulin Fan,et al.  Electrolyte design for LiF-rich solid–electrolyte interfaces to enable high-performance microsized alloy anodes for batteries , 2020, Nature Energy.

[11]  Chibueze V. Amanchukwu,et al.  A new class of ionically conducting fluorinated ether electrolytes with high electrochemical stability. , 2020, Journal of the American Chemical Society.

[12]  Lixia Yuan,et al.  Realizing an Applicable "Solid→Solid" Cathode Process via a Transplantable Solid Electrolyte Interface for Lithium-Sulfur Batteries. , 2019, ACS applied materials & interfaces.

[13]  Sehee Lee,et al.  Crystalline Lithium Imidazolate Covalent Organic Frameworks with High Li-Ion Conductivity. , 2019, Journal of the American Chemical Society.

[14]  Z. Wen,et al.  Recent Progress in Liquid Electrolyte-Based Li–S Batteries: Shuttle Problem and Solutions , 2018, Electrochemical Energy Reviews.

[15]  Yi Cui,et al.  Correlating Structure and Function of Battery Interphases at Atomic Resolution Using Cryoelectron Microscopy , 2018, Joule.

[16]  Shizhao Xiong,et al.  Toward Better Lithium–Sulfur Batteries: Functional Non-aqueous Liquid Electrolytes , 2018, Electrochemical Energy Reviews.

[17]  Xueliang Sun,et al.  Structural Design of Lithium–Sulfur Batteries: From Fundamental Research to Practical Application , 2018, Electrochemical Energy Reviews.

[18]  Zhongtao Li,et al.  Combination of Nitrogen-Doped Graphene with MoS2 Nanoclusters for Improved Li-S Battery Cathode: Synthetic Effect between 2D Components , 2017 .

[19]  Guangmin Zhou,et al.  Catalytic Effects in Lithium–Sulfur Batteries: Promoted Sulfur Transformation and Reduced Shuttle Effect , 2017, Advanced science.

[20]  Song Wenlong,et al.  Polyaniline-wrapping hollow sulfur with MCM-41 template and improved capacity and cycling performance of lithium sulfur batteries , 2016 .

[21]  Jiaqiang Xu,et al.  Facile large-scale synthesis of core–shell structured sulfur@polypyrrole composite and its application in lithium–sulfur batteries with high energy density , 2016 .

[22]  Feixiang Wu,et al.  Enhancing the Stability of Sulfur Cathodes in Li–S Cells via in Situ Formation of a Solid Electrolyte Layer , 2016 .

[23]  Qian Sun,et al.  Safe and Durable High-Temperature Lithium-Sulfur Batteries via Molecular Layer Deposited Coating. , 2016, Nano letters.

[24]  Zhe Yuan,et al.  Powering Lithium-Sulfur Battery Performance by Propelling Polysulfide Redox at Sulfiphilic Hosts. , 2016, Nano letters.

[25]  Shiguo Zhang,et al.  Recent Advances in Electrolytes for Lithium–Sulfur Batteries , 2015 .

[26]  Shaoming Huang,et al.  A Lightweight TiO2/Graphene Interlayer, Applied as a Highly Effective Polysulfide Absorbent for Fast, Long‐Life Lithium–Sulfur Batteries , 2015, Advanced materials.

[27]  Kishan Dholakia,et al.  The role of LiO2 solubility in O2 reduction in aprotic solvents and its consequences for Li-O2 batteries. , 2014, Nature chemistry.

[28]  Guoqiang Ma,et al.  Mesoporous carbon/sulfur composite with polyaniline coating for lithium sulfur batteries , 2014 .

[29]  Jun Liu,et al.  V2O5 Polysulfide Anion Barrier for Long-Lived Li–S Batteries , 2014 .

[30]  Yuki Yamada,et al.  Unusual stability of acetonitrile-based superconcentrated electrolytes for fast-charging lithium-ion batteries. , 2014, Journal of the American Chemical Society.

[31]  Guangyuan Zheng,et al.  Understanding the role of different conductive polymers in improving the nanostructured sulfur cathode performance. , 2013, Nano letters.

[32]  Yingchao Yu,et al.  Yolk-shell structure of polyaniline-coated sulfur for lithium-sulfur batteries. , 2013, Journal of the American Chemical Society.

[33]  Taeeun Yim,et al.  Effect of chemical reactivity of polysulfide toward carbonate-based electrolyte on the electrochemical performance of Li–S batteries , 2013 .

[34]  Guangyuan Zheng,et al.  High-performance hollow sulfur nanostructured battery cathode through a scalable, room temperature, one-step, bottom-up approach , 2013, Proceedings of the National Academy of Sciences.

[35]  Guangyuan Zheng,et al.  Nanostructured sulfur cathodes. , 2013, Chemical Society reviews.

[36]  F. Alloin,et al.  Electrochemical properties of ether-based electrolytes for lithium/sulfur rechargeable batteries , 2013 .

[37]  John B Goodenough,et al.  The Li-ion rechargeable battery: a perspective. , 2013, Journal of the American Chemical Society.

[38]  Jean-Marie Tarascon,et al.  Li-O2 and Li-S batteries with high energy storage. , 2011, Nature materials.

[39]  Jie Gao,et al.  Effects of Liquid Electrolytes on the Charge–Discharge Performance of Rechargeable Lithium/Sulfur Batteries: Electrochemical and in-Situ X-ray Absorption Spectroscopic Studies , 2011 .

[40]  H. Dai,et al.  Graphene-wrapped sulfur particles as a rechargeable lithium-sulfur battery cathode material with high capacity and cycling stability. , 2011, Nano letters.

[41]  Xiulei Ji,et al.  Stabilizing lithium-sulphur cathodes using polysulphide reservoirs. , 2011, Nature Communications.

[42]  L. Nazar,et al.  A highly ordered nanostructured carbon-sulphur cathode for lithium-sulphur batteries. , 2009, Nature materials.

[43]  A. V. Duin,et al.  ReaxFF: A Reactive Force Field for Hydrocarbons , 2001 .

[44]  G. Stucky,et al.  Microemulsion Templating of Siliceous Mesostructured Cellular Foams with Well-Defined Ultralarge Mesopores , 2000 .

[45]  G. Kresse,et al.  Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set , 1996 .

[46]  Steve Plimpton,et al.  Fast parallel algorithms for short-range molecular dynamics , 1993 .

[47]  Viktor Gutmann,et al.  The Donor-Acceptor Approach to Molecular Interactions , 1978 .

[48]  A. I. Popov,et al.  Spectroscopic studies of ionic solvation. X. Study of the solvation of sodium ions in nonaqueous solvents by sodium-23 nuclear magnetic resonance , 1971 .

[49]  Yi Cui,et al.  The path towards sustainable energy. , 2016, Nature materials.