Noninvasive In Situ NMR Study of “Dead Lithium” Formation and Lithium Corrosion in Full-Cell Lithium Metal Batteries

Capacity retention in lithium metal batteries needs to be improved if they are to be commercially viable, the low cycling stability and Li corrosion during storage of lithium metal batteries being even more problematic when there is no excess lithium in the cell. Herein, we develop in situ NMR metrology to study “anode-free” lithium metal batteries where lithium is plated directly onto a bare copper current collector from a LiFePO4 cathode. The methodology allows inactive or “dead lithium” formation during plating and stripping of lithium in a full-cell lithium metal battery to be tracked: dead lithium and SEI formation can be quantified by NMR and their relative rates of formation are here compared in carbonate and ether-electrolytes. Little-to-no dead Li was observed when FEC is used as an additive. The bulk magnetic susceptibility effects arising from the paramagnetic lithium metal were used to distinguish between different surface coverages of lithium deposits. The amount of lithium metal was monitored during rest periods, and lithium metal dissolution (corrosion) was observed in all electrolytes, even during the periods when the battery is not in use, i.e., when no current is flowing, demonstrating that dissolution of lithium remains a critical issue for lithium metal batteries. The high rate of corrosion is attributed to SEI formation on both lithium metal and copper (and Cu+, Cu2+ reduction). Strategies to mitigate the corrosion are explored, the work demonstrating that both polymer coatings and the modification of the copper surface chemistry help to stabilize the lithium metal surface.

[1]  M. Winter,et al.  Quantification of Dead Lithium via In Situ Nuclear Magnetic Resonance Spectroscopy , 2020 .

[2]  C. Grey,et al.  Towards an Understanding of the SEI Formation and Lithium Preferential Plating on Copper , 2020, ECS Meeting Abstracts.

[3]  Lauren E. Marbella,et al.  Investigating the effect of a fluoroethylene carbonate additive on lithium deposition and the solid electrolyte interphase in lithium metal batteries using in situ NMR spectroscopy , 2020, Journal of Materials Chemistry A.

[4]  Yi Cui,et al.  Design Principles of Artificial Solid Electrolyte Interphases for Lithium-Metal Anodes , 2020 .

[5]  B. Dunn,et al.  Understanding and applying coulombic efficiency in lithium metal batteries , 2020 .

[6]  S. Choudhury,et al.  Regulating electrodeposition morphology of lithium: towards commercially relevant secondary Li metal batteries. , 2020, Chemical Society reviews.

[7]  M. Winter,et al.  Galvanic Corrosion of Lithium‐Powder‐Based Electrodes , 2020, Advanced Energy Materials.

[8]  N. Dasgupta,et al.  Plan-View Operando Video Microscopy of Li Metal Anodes: Identifying the Coupled Relationships among Nucleation, Morphology, and Reversibility , 2020 .

[9]  O. Borodin,et al.  Nonflammable Lithium Metal Full Cells with Ultra-high Energy Density Based on Coordinated Carbonate Electrolytes , 2020, iScience.

[10]  Gustavo M. Hobold,et al.  The intrinsic behavior of lithium fluoride in solid electrolyte interphases on lithium , 2019, Proceedings of the National Academy of Sciences.

[11]  K. Edström,et al.  Highly Concentrated LiTFSI–EC Electrolytes for Lithium Metal Batteries , 2019, ACS Applied Energy Materials.

[12]  A. Jerschow,et al.  In situ and operando magnetic resonance imaging of electrochemical cells: A perspective. , 2019, Journal of magnetic resonance.

[13]  Chibueze V. Amanchukwu,et al.  Nonpolar Alkanes Modify Lithium‐Ion Solvation for Improved Lithium Deposition and Stripping , 2019, Advanced Energy Materials.

[14]  J. Dahn,et al.  Long cycle life and dendrite-free lithium morphology in anode-free lithium pouch cells enabled by a dual-salt liquid electrolyte , 2019, Nature Energy.

[15]  M. Gaultois,et al.  When do Anisotropic Magnetic Susceptibilities Lead to Large NMR Shifts? Exploring Particle Shape Effects in the Battery Electrode Material LiFePO4. , 2019, Journal of the American Chemical Society.

[16]  Y. Meng,et al.  Key Issues Hindering a Practical Lithium-Metal Anode , 2019, Trends in Chemistry.

[17]  Venkat R. Subramanian,et al.  Pathways for practical high-energy long-cycling lithium metal batteries , 2019, Nature Energy.

[18]  Yayuan Liu,et al.  Fast galvanic lithium corrosion involving a Kirkendall-type mechanism , 2019, Nature Chemistry.

[19]  Allen Pei,et al.  Nanostructural and Electrochemical Evolution of the Solid-Electrolyte Interphase on CuO Nanowires Revealed by Cryogenic-Electron Microscopy and Impedance Spectroscopy. , 2018, ACS nano.

[20]  Y. Meng,et al.  Quantifying inactive lithium in lithium metal batteries , 2018, Nature.

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

[22]  B. Lucht,et al.  Effect of electrolyte on the nanostructure of the solid electrolyte interphase (SEI) and performance of lithium metal anodes , 2018 .

[23]  Allen Pei,et al.  Effects of Polymer Coatings on Electrodeposited Lithium Metal. , 2018, Journal of the American Chemical Society.

[24]  Cao Cuong Nguyen,et al.  Effect of Fluoroethylene Carbonate Electrolytes on the Nanostructure of the Solid Electrolyte Interphase and Performance of Lithium Metal Anodes , 2018, ACS Applied Energy Materials.

[25]  B. Hwang,et al.  Polyethylene oxide film coating enhances lithium cycling efficiency of an anode-free lithium-metal battery. , 2018, Nanoscale.

[26]  S. Choudhury,et al.  Fast ion transport at solid–solid interfaces in hybrid battery anodes , 2018 .

[27]  Linda F. Nazar,et al.  An In Vivo Formed Solid Electrolyte Surface Layer Enables Stable Plating of Li Metal , 2017 .

[28]  Ji‐Guang Zhang,et al.  New Insights on the Structure of Electrochemically Deposited Lithium Metal and Its Solid Electrolyte Interphases via Cryogenic TEM. , 2017, Nano letters.

[29]  Yi Cui,et al.  Strong texturing of lithium metal in batteries , 2017, Proceedings of the National Academy of Sciences.

[30]  Ravishankar Sundararaman,et al.  Electroless Formation of Hybrid Lithium Anodes for Fast Interfacial Ion Transport. , 2017, Angewandte Chemie.

[31]  L. Nazar,et al.  A facile surface chemistry route to a stabilized lithium metal anode , 2017, Nature Energy.

[32]  Kevin N. Wood,et al.  Dead lithium: Mass transport effects on voltage, capacity, and failure of lithium metal anodes , 2017 .

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

[34]  M. Bazant,et al.  Liquid cell transmission electron microscopy observation of lithium metal growth and dissolution: Root growth, dead lithium and lithium flotsams , 2017 .

[35]  Guangyuan Zheng,et al.  Nanoscale Nucleation and Growth of Electrodeposited Lithium Metal. , 2017, Nano letters.

[36]  Javier Carretero-González,et al.  Materials’ Methods: NMR in Battery Research , 2017 .

[37]  Kevin N. Wood,et al.  Dendrites and Pits: Untangling the Complex Behavior of Lithium Metal Anodes through Operando Video Microscopy , 2016, ACS central science.

[38]  Jianming Zheng,et al.  Anode‐Free Rechargeable Lithium Metal Batteries , 2016 .

[39]  Yayuan Liu,et al.  Layered reduced graphene oxide with nanoscale interlayer gaps as a stable host for lithium metal anodes. , 2016, Nature nanotechnology.

[40]  L. Archer,et al.  Stable Artificial Solid Electrolyte Interphases for Lithium Batteries , 2016, 1604.04200.

[41]  C. Grey,et al.  Automatic Tuning Matching Cycler (ATMC) in situ NMR spectroscopy as a novel approach for real-time investigations of Li- and Na-ion batteries. , 2016, Journal of magnetic resonance.

[42]  J. Janek,et al.  Reaction Mechanism and Surface Film Formation of Conversion Materials for Lithium- and Sodium-Ion Batteries: An XPS Case Study on Sputtered Copper Oxide (CuO) Thin Film Model Electrodes , 2016 .

[43]  Jens Tübke,et al.  Lithium–Sulfur Cells: The Gap between the State‐of‐the‐Art and the Requirements for High Energy Battery Cells , 2015 .

[44]  M. Eikerling,et al.  Magnetic susceptibility as a direct measure of oxidation state in LiFePO4 batteries and cyclic water gas shift reactors. , 2015, Physical chemistry chemical physics : PCCP.

[45]  C. Grey,et al.  Investigating Li Microstructure Formation on Li Anodes for Lithium Batteries by in Situ 6Li/7Li NMR and SEM , 2015 .

[46]  Xiaogang Han,et al.  Next-Generation Lithium Metal Anode Engineering via Atomic Layer Deposition. , 2015, ACS nano.

[47]  O. Borodin,et al.  High rate and stable cycling of lithium metal anode , 2015, Nature Communications.

[48]  Terence J. Lozano,et al.  Failure Mechanism for Fast‐Charged Lithium Metal Batteries with Liquid Electrolytes , 2015 .

[49]  V. Chevrier,et al.  Alloy negative electrodes for Li-ion batteries. , 2014, Chemical reviews.

[50]  Reiner Mönig,et al.  Microscopic observations of the formation, growth and shrinkage of lithium moss during electrodeposition and dissolution , 2014 .

[51]  L. Greengard,et al.  Visualizing skin effects in conductors with MRI: (7)Li MRI experiments and calculations. , 2014, Journal of magnetic resonance.

[52]  R. Bongiovanni,et al.  NMR study of photo‐crosslinked solid polymer electrolytes: The influence of monofunctional oligoethers , 2013 .

[53]  C. Grey,et al.  Paramagnetic electrodes and bulk magnetic susceptibility effects in the in situ NMR studies of batteries: application to Li1.08Mn1.92O4 spinels. , 2013, Journal of magnetic resonance.

[54]  Alexej Jerschow,et al.  7Li MRI of Li batteries reveals location of microstructural lithium. , 2012, Nature materials.

[55]  C. Grey,et al.  In situ NMR of lithium ion batteries: bulk susceptibility effects and practical considerations. , 2012, Solid state nuclear magnetic resonance.

[56]  M. Shui,et al.  Comparative study on surface behaviors of copper current collector in electrolyte for lithium-ion batteries , 2011 .

[57]  E. Gileadi Physical Electrochemistry: Fundamentals, Techniques and Applications , 2011 .

[58]  Hailong Chen,et al.  In situ NMR observation of the formation of metallic lithium microstructures in lithium batteries. , 2010, Nature materials.

[59]  D. Hess,et al.  A Novel Method of Etching Copper Oxide Using Acetic Acid , 2001 .

[60]  John B. Goodenough,et al.  Effect of Structure on the Fe3 + / Fe2 + Redox Couple in Iron Phosphates , 1997 .

[61]  B. Scrosati,et al.  Kinetics and stability of the lithium electrode in poly(methylmethacrylate)-based gel electrolytes , 1995 .

[62]  O. Bohnké,et al.  Gel Electrolyte for Solid‐State Electrochromic Cell , 1992 .

[63]  J. Yamaki,et al.  Lithium Electrode Morphology during Cycling in Lithium Cells , 1988 .

[64]  D. Fauteux Electrochemical stability and ionic conductivity of some polymer-lix based electrolytes , 1988 .

[65]  J. Besenhard,et al.  Corrosion protection of secondary lithium electrodes in organic electrolytes , 1987 .

[66]  P. Novák CuO cathode in lithium cells—II. Reduction mechanism of CuO☆ , 1985 .

[67]  H. S. Gutowsky,et al.  Nuclear Magnetic Resonance in Metals. I. Broadening of Absorption Lines by Spin‐Lattice Interactions , 1952 .

[68]  A. Stephan,et al.  Review on gel polymer electrolytes for lithium batteries , 2006 .

[69]  T. J. Rowland Nuclear magnetic resonance in metals , 1961 .