Cryo-STEM mapping of solid–liquid interfaces and dendrites in lithium-metal batteries

Solid–liquid interfaces are important in a range of chemical, physical and biological processes1–4, but are often not fully understood owing to the lack of high-resolution characterization methods that are compatible with both solid and liquid components5. For example, the related processes of dendritic deposition of lithium metal and the formation of solid–electrolyte interphase layers6,7 are known to be key determinants of battery safety and performance in high-energy-density lithium-metal batteries. But exactly what is involved in these two processes, which occur at a solid–liquid interface, has long been debated8–11 because of the challenges of observing such interfaces directly. Here we adapt a technique that has enabled cryo-transmission electron microscopy (cryo-TEM) of hydrated specimens in biology—immobilization of liquids by rapid freezing, that is, vitrification12. By vitrifying the liquid electrolyte we preserve it and the structures at solid–liquid interfaces in lithium-metal batteries in their native state, and thus enable structural and chemical mapping of these interfaces by cryo-scanning transmission electron microscopy (cryo-STEM). We identify two dendrite types coexisting on the lithium anode, each with distinct structure and composition. One family of dendrites has an extended solid–electrolyte interphase layer, whereas the other unexpectedly consists of lithium hydride instead of lithium metal and may contribute disproportionately to loss of battery capacity. The insights into the formation of lithium dendrites that our work provides demonstrate the potential of cryogenic electron microscopy for probing nanoscale processes at intact solid–liquid interfaces in functional devices such as rechargeable batteries.Direct observation of the anode–electrolyte interface in a lithium-metal battery, without removing the liquid electrolyte, reveals two types of dendrites, one of which may contribute disproportionately to capacity fade.

[1]  J. Bouhattate,et al.  The diffusion and trapping of hydrogen along the grain boundaries in polycrystalline nickel , 2012 .

[2]  H. Aourag,et al.  Structural and mechanical properties of alkali hydrides investigated by the first-principles calculations and principal component analysis , 2016 .

[3]  M. Malac,et al.  Radiation damage in the TEM and SEM. , 2004, Micron.

[4]  Isaac M. Markus,et al.  Chemical and Structural Stability of Lithium-Ion Battery Electrode Materials under Electron Beam , 2014, Scientific Reports.

[5]  Zhengyuan Tu,et al.  Stable lithium electrodeposition in salt-reinforced electrolytes , 2015 .

[6]  C. Wan,et al.  Composition analysis of the passive film on the carbon electrode of a lithium-ion battery with an EC-based electrolyte , 1998 .

[7]  S. Choudhury,et al.  Building Organic/Inorganic Hybrid Interphases for Fast Interfacial Transport in Rechargeable Metal Batteries. , 2018, Angewandte Chemie.

[8]  D. Aurbach,et al.  On the possibility of LiH formation on Li surfaces in wet electrolyte solutions , 1999 .

[9]  Liumin Suo,et al.  Fluorine-donating electrolytes enable highly reversible 5-V-class Li metal batteries , 2018, Proceedings of the National Academy of Sciences.

[10]  Dangrong R. Liu Electron energy loss spectroscopy of LiH with a scanning transmission electron microscope , 1987 .

[11]  Martin Z. Bazant,et al.  Transition of lithium growth mechanisms in liquid electrolytes , 2016 .

[12]  T. Tyliszczak,et al.  Quantitative organic and light‐element analysis of comet 81P/Wild 2 particles using C‐, N‐, and O‐μ‐XANES , 2008 .

[13]  Qing Zhao,et al.  Building Organic/Inorganic Hybrid Interphases for Fast Interfacial Transport in Rechargeable Metal Batteries , 2018 .

[14]  S. Choudhury,et al.  Lithium Fluoride Additives for Stable Cycling of Lithium Batteries at High Current Densities , 2016 .

[15]  Lynden A. Archer,et al.  Design principles for electrolytes and interfaces for stable lithium-metal batteries , 2016, Nature Energy.

[16]  T. Jow,et al.  Lithium ethylene dicarbonate identified as the primary product of chemical and electrochemical reduction of EC in 1.2 M LiPF6/EC:EMC electrolyte. , 2005, The journal of physical chemistry. B.

[17]  H. Ratajczak,et al.  Ab initio calculations on the lithium fluoride–ethylene complex , 1977 .

[18]  J. Yamaki,et al.  A consideration of the morphology of electrochemically deposited lithium in an organic electrolyte , 1997 .

[19]  D. Aurbach Review of selected electrode–solution interactions which determine the performance of Li and Li ion batteries , 2000 .

[20]  Francisco Zaera,et al.  Probing liquid/solid interfaces at the molecular level. , 2012, Chemical reviews.

[21]  T. Lodge,et al.  Cryogenic transmission electron microscopy imaging of vesicles formed by a polystyrene-polyisoprene diblock copolymer , 2005 .

[22]  M. Armand,et al.  Issues and challenges facing rechargeable lithium batteries , 2001, Nature.

[23]  Paul Cueva,et al.  Data Processing for Atomic Resolution Electron Energy Loss Spectroscopy , 2012, Microscopy and Microanalysis.

[24]  Dusan Strmcnik,et al.  Energy and fuels from electrochemical interfaces. , 2016, Nature materials.

[25]  David B. Williams,et al.  The electron-energy-loss spectrum of lithium metal , 1986 .

[26]  J. Dubochet,et al.  Cryo-electron microscopy of vitrified specimens , 1988, Quarterly Reviews of Biophysics.

[27]  M. Zachman,et al.  Site-Specific Preparation of Intact Solid–Liquid Interfaces by Label-Free In Situ Localization and Cryo-Focused Ion Beam Lift-Out , 2016, Microscopy and Microanalysis.

[28]  S. Weiner,et al.  Crystallization Pathways in Biomineralization , 2011 .

[29]  A. Islam Lighter Alkali Hydride and Deruteride. Electronic Properties of Pure Solids , 1993 .

[30]  Rui Zhang,et al.  A Review of Solid Electrolyte Interphases on Lithium Metal Anode , 2015, Advanced science.

[31]  Xiao Hua,et al.  Origin of additional capacities in metal oxide lithium-ion battery electrodes. , 2013, Nature materials.

[32]  S. Subramaniam,et al.  Site-specific 3D imaging of cells and tissues with a dual beam microscope. , 2006, Journal of structural biology.

[33]  Daniel C. Ralph,et al.  High Dynamic Range Pixel Array Detector for Scanning Transmission Electron Microscopy , 2016, Microscopy and Microanalysis.

[34]  Y. Kondo,et al.  Reflectance spectrum of lithium hydride at the Li K-absorption edge , 1981 .

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

[36]  Peidong Yang,et al.  Direct Observation of Vapor-Liquid-Solid Nanowire Growth , 2001 .

[37]  Hubert A. Gasteiger,et al.  Origin of H2 Evolution in LIBs: H2O Reduction vs. Electrolyte Oxidation , 2016 .

[38]  Shinichi Kinoshita,et al.  Identification of the Source of Evolved Gas in Li-Ion Batteries Using #2#1 -labeled Solvents , 2008 .

[39]  Lynden A Archer,et al.  Stable lithium electrodeposition in liquid and nanoporous solid electrolytes. , 2014, Nature materials.