Lithium Difluorophosphate‐Based Dual‐Salt Low Concentration Electrolytes for Lithium Metal Batteries

The safety hazards and low Coulombic efficiency originating from the growth of lithium dendrites and decomposition of the electrolyte restrict the practical application of Li metal batteries (LMBs). Inspired by the low cost of low concentration electrolytes (LCEs) in industrial applications, dual‐salt LCEs employing 0.1 m Li difluorophosphate (LiDFP) and 0.4 m LiBOB/LiFSI/LiTFSI are proposed to construct a robust and conductive interphase on a Li metal anode. Compared with the conventional electrolyte using 1 m LiPF6, the ionic conductivity of LCEs is reduced but the conductivity decrement of the separator immersed in LCEs is moderate, especially for the LiDFP–LiFSI and LiDFP–LiTFSI electrolytes. The accurate Coulombic efficiency (CE) of the Li||Cu cells increases from 83.3% (electrolyte using 1 m LiPF6) to 97.6%, 94.5%, and 93.6% for LiDFP–LiBOB, LiDFP–LiFSI, and LiDFP–LiTFSI electrolytes, respectively. The capacity retention of Li||LiFePO4 cells using the LiDFP–LiBOB electrolyte reaches 95.4% along with a CE over 99.8% after 300 cycles at a current density of 2.0 mA cm−2 and the capacity reaches 103.7 mAh g−1 at a current density of up to 16.0 mA cm−2. This work provides a dual‐salt LCE for practical LMBs and presents a new perspective for the design of electrolytes for LMBs.

[1]  G. G. Eshetu,et al.  Electrolytes and Interphases in Sodium‐Based Rechargeable Batteries: Recent Advances and Perspectives , 2020, Advanced Energy Materials.

[2]  Eric J. Dufek,et al.  Electrode scale and electrolyte transport effects on extreme fast charging of lithium-ion cells , 2020 .

[3]  Xingguo Qi,et al.  Ultralow-Concentration Electrolyte for Na-Ion Batteries , 2020 .

[4]  Lixin Qiao,et al.  A supramolecular interaction strategy enabling high-performance all solid state electrolyte of lithium metal batteries , 2020 .

[5]  Rui Zhang,et al.  The Failure of Solid Electrolyte Interphase on Li Metal Anode: Structural Uniformity or Mechanical Strength? , 2020, Advanced Energy Materials.

[6]  Xiulin Fan,et al.  Countersolvent Electrolytes for Lithium‐Metal Batteries , 2020, Advanced Energy Materials.

[7]  Jiaqi Huang,et al.  A compact inorganic layer for robust anode protection in lithium‐sulfur batteries , 2020 .

[8]  G. Cui,et al.  Nonflammable Nitrile Deep Eutectic Electrolyte Enables High-Voltage Lithium Metal Batteries , 2020 .

[9]  M. L. Focarete,et al.  Functional separators for the batteries of the future , 2020 .

[10]  Yunhua Xu,et al.  Poorly Soluble 2,6-Dimethoxy-9,10-Anthraquinone Cathode for Lithium-Ion Batteries: the Role of Electrolyte Concentration. , 2020, ACS applied materials & interfaces.

[11]  G. Cui,et al.  A Temperature‐Responsive Electrolyte Endowing Superior Safety Characteristic of Lithium Metal Batteries , 2019, Advanced Energy Materials.

[12]  Chao Lai,et al.  Grain refining mechanisms: Initial levelling stage during nucleation for high-stability lithium anodes , 2019 .

[13]  Rui Zhang,et al.  Sustainable solid electrolyte interphase enables high-energy-density lithium metal batteries under practical conditions. , 2019, Angewandte Chemie.

[14]  Qiang Zhang,et al.  Fluorinated Solid-Electrolyte Interphase in High-Voltage Lithium Metal Batteries , 2019, Joule.

[15]  Hong‐Jie Peng,et al.  Expediting redox kinetics of sulfur species by atomic‐scale electrocatalysts in lithium–sulfur batteries , 2019, InfoMat.

[16]  Yan Yu,et al.  A Novel Protective Strategy on High‐Voltage LiCoO 2 Cathode for Fast Charging Applications: Li 1.6 Mg 1.6 Sn 2.8 O 8 Double Layer Structure via SnO 2 Surface Modification , 2019, Small Methods.

[17]  Yiying Wu,et al.  Localized High‐Concentration Electrolytes Boost Potassium Storage in High‐Loading Graphite , 2019, Advanced Energy Materials.

[18]  B. Liu,et al.  Enhanced Stability of Li Metal Anodes by Synergetic Control of Nucleation and the Solid Electrolyte Interphase , 2019, Advanced Energy Materials.

[19]  Hongkyung Lee,et al.  Monolithic solid–electrolyte interphases formed in fluorinated orthoformate-based electrolytes minimize Li depletion and pulverization , 2019, Nature Energy.

[20]  Weishan Li,et al.  Recent research progresses in ether‐ and ester‐based electrolytes for sodium‐ion batteries , 2019, InfoMat.

[21]  Ji‐Guang Zhang,et al.  High‐Performance Silicon Anodes Enabled By Nonflammable Localized High‐Concentration Electrolytes , 2019, Advanced Energy Materials.

[22]  Hongkyung Lee,et al.  Enabling High-Voltage Lithium-Metal Batteries under Practical Conditions , 2019, Joule.

[23]  Jang‐Yeon Hwang,et al.  Trimethylsilyl azide (C3H9N3Si): a highly efficient additive for tailoring fluoroethylene carbonate (FEC) based electrolytes for Li-metal batteries , 2019, Journal of Materials Chemistry A.

[24]  Ji‐Guang Zhang,et al.  Constructing Robust Electrode/Electrolyte Interphases to Enable Wide Temperature Applications of Lithium-Ion Batteries. , 2019, ACS applied materials & interfaces.

[25]  Weishan Li,et al.  Lithium Bis(oxalate)borate Reinforces the Interphase on Li-Metal Anodes. , 2019, ACS applied materials & interfaces.

[26]  Shaopeng Li,et al.  RbF as a Dendrite-Inhibiting Additive in Lithium Metal Batteries. , 2019, ACS applied materials & interfaces.

[27]  Hao Zheng,et al.  High-Voltage LiNi0.5Mn1.5O4 Cathode Stability of Fluorinated Ether Based on Enhanced Separator Wettability , 2019, Journal of The Electrochemical Society.

[28]  G. Cui,et al.  Lithium–Metal Batteries: Additive‐Assisted Novel Dual‐Salt Electrolyte Addresses Wide Temperature Operation of Lithium–Metal Batteries (Small 16/2019) , 2019, Small.

[29]  Hongkyung Lee,et al.  High-Concentration Ether Electrolytes for Stable High-Voltage Lithium Metal Batteries , 2019, ACS Energy Letters.

[30]  Yuyan Shao,et al.  Stable Li Metal Anode with “Ion–Solvent-Coordinated” Nonflammable Electrolyte for Safe Li Metal Batteries , 2019, ACS Energy Letters.

[31]  Xiulin Fan,et al.  High electronic conductivity as the origin of lithium dendrite formation within solid electrolytes , 2019, Nature Energy.

[32]  L. Nyholm,et al.  Dendrite-free lithium electrode cycling via controlled nucleation in low LiPF6 concentration electrolytes , 2018, Materials Today.

[33]  Kang Xu,et al.  Localized High-Concentration Sulfone Electrolytes for High-Efficiency Lithium-Metal Batteries , 2018, Chem.

[34]  Hongkyung Lee,et al.  A Localized High-Concentration Electrolyte with Optimized Solvents and Lithium Difluoro(oxalate)borate Additive for Stable Lithium Metal Batteries , 2018, ACS Energy Letters.

[35]  Ji‐Guang Zhang,et al.  Stable cycling of high-voltage lithium metal batteries in ether electrolytes , 2018, Nature Energy.

[36]  Wu Xu,et al.  Lithium Difluorophosphate as a Dendrite-Suppressing Additive for Lithium Metal Batteries. , 2018, ACS applied materials & interfaces.

[37]  Min Zhu,et al.  Lithium Difluorophosphate As a Promising Electrolyte Lithium Additive for High-Voltage Lithium-Ion Batteries , 2018, ACS Applied Energy Materials.

[38]  G. Cui,et al.  Self-Stabilized Solid Electrolyte Interface on a Host-Free Li-Metal Anode toward High Areal Capacity and Rate Utilization , 2018 .

[39]  O. Borodin,et al.  A carbonate-free, sulfone-based electrolyte for high-voltage Li-ion batteries , 2018 .

[40]  Ji‐Guang Zhang,et al.  High‐Voltage Lithium‐Metal Batteries Enabled by Localized High‐Concentration Electrolytes , 2018, Advanced materials.

[41]  Sheng Cheng,et al.  A highly concentrated phosphate-based electrolyte for high-safety rechargeable lithium batteries. , 2018, Chemical communications.

[42]  Mahesh Mynam,et al.  Effect of Salt Concentration on Properties of Lithium Ion Battery Electrolytes: A Molecular Dynamics Study , 2018 .

[43]  Hui Xu,et al.  Developing High‐Performance Lithium Metal Anode in Liquid Electrolytes: Challenges and Progress , 2018, Advanced materials.

[44]  Jianming Zheng,et al.  Accurate Determination of Coulombic Efficiency for Lithium Metal Anodes and Lithium Metal Batteries , 2018 .

[45]  Ji‐Guang Zhang,et al.  Guided Lithium Metal Deposition and Improved Lithium Coulombic Efficiency through Synergistic Effects of LiAsF6 and Cyclic Carbonate Additives , 2018 .

[46]  Yangxing Li,et al.  Suppression of Dendritic Lithium Growth by in Situ Formation of a Chemically Stable and Mechanically Strong Solid Electrolyte Interphase. , 2018, ACS applied materials & interfaces.

[47]  Qiang Zhang,et al.  Prestoring Lithium into Stable 3D Nickel Foam Host as Dendrite‐Free Lithium Metal Anode , 2017 .

[48]  Yayuan Liu,et al.  Nanoscale perspective: Materials designs and understandings in lithium metal anodes , 2017, Nano Research.

[49]  Chong Yan,et al.  Fluoroethylene Carbonate Additives to Render Uniform Li Deposits in Lithium Metal Batteries , 2017 .

[50]  Yi Cui,et al.  Reviving the lithium metal anode for high-energy batteries. , 2017, Nature nanotechnology.

[51]  Jianming Zheng,et al.  Electrolyte additive enabled fast charging and stable cycling lithium metal batteries , 2017, Nature Energy.

[52]  Haihui Wang,et al.  Enhanced separator wettability by LiTFSI and its application for lithium metal batteries , 2017 .

[53]  Ji‐Guang Zhang,et al.  Enhanced charging capability of lithium metal batteries based on lithium bis(trifluoromethanesulfonyl)imide-lithium bis(oxalato)borate dual-salt electrolytes , 2016 .

[54]  Yuki Yamada,et al.  Superconcentrated electrolytes for a high-voltage lithium-ion battery , 2016, Nature Communications.

[55]  C. Hsieh,et al.  Immobilization of Anions on Polymer Matrices for Gel Electrolytes with High Conductivity and Stability in Lithium Ion Batteries. , 2016, ACS applied materials & interfaces.

[56]  Haihui Wang,et al.  Enhancement on the wettability of lithium battery separator toward nonaqueous electrolytes , 2016 .

[57]  Samuel S. Cartmell,et al.  Highly Stable Operation of Lithium Metal Batteries Enabled by the Formation of a Transient High‐Concentration Electrolyte Layer , 2016 .

[58]  M. Ue,et al.  A combination of lithium difluorophosphate and vinylene carbonate as reducible additives to improve cycling performance of graphite electrodes at high rates , 2015 .

[59]  Jun Liu,et al.  Dendrite-free lithium deposition via self-healing electrostatic shield mechanism. , 2013, Journal of the American Chemical Society.

[60]  Mathew D. Halls,et al.  High-throughput quantum chemistry and virtual screening for lithium ion battery electrolyte additives , 2010 .

[61]  J. Yamaki,et al.  Structural and Functional Analysis of Surface Film on Li Anode in Vinylene Carbonate-Containing Electrolyte , 2004 .

[62]  Kang Xu,et al.  Nonaqueous liquid electrolytes for lithium-based rechargeable batteries. , 2004, Chemical reviews.

[63]  Jeffrey A. Nichols,et al.  Ionization Potential, Electron Affinity, Electronegativity, Hardness, and Electron Excitation Energy: Molecular Properties from Density Functional Theory Orbital Energies , 2003 .

[64]  Doron Aurbach,et al.  Recent studies of the lithium-liquid electrolyte interface Electrochemical, morphological and spectral studies of a few important systems , 1995 .

[65]  S. Satoh,et al.  Orbital interactions and chemical hardness , 1994 .

[66]  Martin Winter,et al.  Inorganic film-forming electrolyte additives improving the cycling behaviour of metallic lithium electrodes and the self-discharge of carbon—lithium electrodes , 1993 .

[67]  John H. Bedenbaugh,et al.  Lithium-Methylamine Reduction. I. Reduction of Furan, 2-Methylfuran, and Furfuryl Alcohol , 1970 .

[68]  Yuki Yamada,et al.  Fire-extinguishing organic electrolytes for safe batteries , 2018 .

[69]  J. Eckert,et al.  Role of 1,3-Dioxolane and LiNO3 Addition on the Long Term Stability of Nanostructured Silicon/Carbon Anodes for Rechargeable Lithium Batteries , 2016 .

[70]  Pankaj Arora,et al.  Battery separators. , 2004, Chemical reviews.