Correlating Microstructural Lithium Metal Growth with Electrolyte Salt Depletion in Lithium Batteries Using ⁷Li MRI.

Lithium dendrite growth in lithium ion and lithium rechargeable batteries is associated with severe safety concerns. To overcome these problems, a fundamental understanding of the growth mechanism of dendrites under working conditions is needed. In this work, in situ (7)Li magnetic resonance (MRI) is performed on both the electrolyte and lithium metal electrodes in symmetric lithium cells, allowing the behavior of the electrolyte concentration gradient to be studied and correlated with the type and rate of microstructure growth on the Li metal electrode. For this purpose, chemical shift (CS) imaging of the metal electrodes is a particularly sensitive diagnostic method, enabling a clear distinction to be made between different types of microstructural growth occurring at the electrode surface and the eventual dendrite growth between the electrodes. The CS imaging shows that mossy types of microstructure grow close to the surface of the anode from the beginning of charge in every cell studied, while dendritic growth is triggered much later. Simple metrics have been developed to interpret the MRI data sets and to compare results from a series of cells charged at different current densities. The results show that at high charge rates, there is a strong correlation between the onset time of dendrite growth and the local depletion of the electrolyte at the surface of the electrode observed both experimentally and predicted theoretical (via the Sand's time model). A separate mechanism of dendrite growth is observed at low currents, which is not governed by salt depletion in the bulk liquid electrolyte. The MRI approach presented here allows the rate and nature of a process that occurs in the solid electrode to be correlated with the concentrations of components in the electrolyte.

[1]  M. Britton Magnetic resonance imaging of electrochemical cells containing bulk metal. , 2014, Chemphyschem : a European journal of chemical physics and physical chemistry.

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

[3]  Jean-Marie Tarascon,et al.  Dendrite short-circuit and fuse effect on Li/polymer/Li cells , 2006 .

[4]  Doron Aurbach,et al.  Factors Which Limit the Cycle Life of Rechargeable Lithium (Metal) Batteries , 2000 .

[5]  Rahul V. Magan,et al.  Influence of surface reaction rate on the size dispersion of interfacial nanostructures , 2003 .

[6]  J. O'm. Bockris,et al.  The Mechanism of the Dendritic Electrocrystallization of Zinc , 1969 .

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

[8]  R. Voss,et al.  Computer Simulation of Dendritic Electrodeposition , 1985 .

[9]  Christoph Rau,et al.  Three-dimensional characterization of electrodeposited lithium microstructures using synchrotron X-ray phase contrast imaging. , 2015, Chemical communications.

[10]  R. Bowtell,et al.  Application of a Fourier‐based method for rapid calculation of field inhomogeneity due to spatial variation of magnetic susceptibility , 2005 .

[11]  Fredrik Hallberg,et al.  Quantifying mass transport during polarization in a Li ion battery electrolyte by in situ 7Li NMR imaging. , 2012, Journal of the American Chemical Society.

[12]  M. Forsyth,et al.  In Situ, Real-Time Visualization of Electrochemistry Using Magnetic Resonance Imaging , 2013, The journal of physical chemistry letters.

[13]  Emanuel Peled,et al.  The Electrochemical Behavior of Alkali and Alkaline Earth Metals in Nonaqueous Battery Systems—The Solid Electrolyte Interphase Model , 1979 .

[14]  Thomas Hanemann,et al.  Suppressed lithium dendrite growth in lithium batteries using ionic liquid electrolytes: Investigation by electrochemical impedance spectroscopy, scanning electron microscopy, and in situ 7Li nuclear magnetic resonance spectroscopy , 2013 .

[15]  Minoru Inaba,et al.  Effects of Some Organic Additives on Lithium Deposition in Propylene Carbonate , 2002 .

[16]  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.

[17]  J.-N. Chazalviel,et al.  In Situ Concentration Cartography in the Neighborhood of Dendrites Growing in Lithium/Polymer‐Electrolyte/Lithium Cells , 1999 .

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

[19]  J. L. Barton,et al.  The electrolytic growth of dendrites from ionic solutions , 1962, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

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

[21]  J. Tarascon,et al.  Lithium metal stripping/plating mechanisms studies: A metallurgical approach , 2006 .

[22]  Doron Aurbach,et al.  Micromorphological Studies of Lithium Electrodes in Alkyl Carbonate Solutions Using in Situ Atomic Force Microscopy , 2000 .

[23]  M. Rosso,et al.  Concentration measurements in lithium/polymer–electrolyte/lithium cells during cycling , 2001 .

[24]  Kubo,et al.  The effect of bulk magnetic susceptibility on solid state NMR spectra of paramagnetic compounds , 1998, Journal of magnetic resonance.

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

[26]  J. Chazalviel,et al.  Electrochemical aspects of the generation of ramified metallic electrodeposits. , 1990, Physical review. A, Atomic, molecular, and optical physics.

[27]  Martensitic transformation of lithium: Magnetic susceptibility measurements , 1997 .

[28]  Saad A. Khan,et al.  Inhibition of Lithium Dendrites by Fumed Silica-Based Composite Electrolytes , 2004 .

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

[30]  L. Sander,et al.  Diffusion-limited aggregation, a kinetic critical phenomenon , 1981 .

[31]  W. Yoon,et al.  The effect of internal resistance on dendritic growth on lithium metal electrodes in the lithium secondary batteries , 2008 .

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

[33]  M. Behm,et al.  Electrochemical characterisation and modelling of the mass transport phenomena in LiPF6–EC–EMC electrolyte , 2008 .

[34]  Doron Aurbach,et al.  A short review of failure mechanisms of lithium metal and lithiated graphite anodes in liquid electrolyte solutions , 2002 .

[35]  B. Liaw,et al.  A review of lithium deposition in lithium-ion and lithium metal secondary batteries , 2014 .

[36]  K. Kanamura,et al.  Electrochemical Deposition of Very Smooth Lithium Using Nonaqueous Electrolytes Containing HF , 1996 .

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

[38]  Hiroshi Senoh,et al.  Effect of Current Density on Morphology of Lithium Electrodeposited in Ionic Liquid-Based Electrolytes , 2014 .

[39]  M. Winter,et al.  (7)Li in situ 1D NMR imaging of a lithium ion battery. , 2015, Physical chemistry chemical physics : PCCP.

[40]  P. Meakin Formation of fractal clusters and networks by irreversible diffusion-limited aggregation , 1983 .

[41]  Thomas F. Miller,et al.  Suppression of Dendrite Formation via Pulse Charging in Rechargeable Lithium Metal Batteries , 2012 .