Ab Initio Modeling of Electrolyte Molecule Ethylene Carbonate Decomposition Reaction on Li(Ni,Mn,Co)O2 Cathode Surface.

Electrolyte decomposition reactions on Li-ion battery electrodes contribute to the formation of solid electrolyte interphase (SEI) layers. These SEI layers are one of the known causes for the loss in battery voltage and capacity over repeated charge/discharge cycles. In this work, density functional theory (DFT)-based ab initio calculations are applied to study the initial steps of the decomposition of the organic electrolyte component ethylene carbonate (EC) on the (101̅4) surface of a layered Li(Nix,Mny,Co1-x-y)O2 (NMC) cathode crystal, which is commonly used in commercial Li-ion batteries. The effects on the EC reaction pathway due to dissolved Li+ ions in the electrolyte solution and different NMC cathode surface terminations containing adsorbed hydroxyl -OH or fluorine -F species are explicitly considered. We predict a very fast chemical reaction consisting of an EC ring-opening process on the bare cathode surface, the rate of which is independent of the battery operation voltage. This EC ring-opening reaction is unavoidable once the cathode material contacts with the electrolyte because this process is purely chemical rather than electrochemical in nature. The -OH and -F adsorbed species display a passivation effect on the surface against the reaction with EC, but the extent is limited except for the case of -OH bonded to a surface transition metal atom. Our work implies that the possible rate-limiting steps of the electrolyte molecule decomposition are the reactions on the decomposed organic products on the cathode surface rather than on the bare cathode surface.

[1]  David H. K. Jackson,et al.  Atomic Layer Deposited MgO: A Lower Overpotential Coating for Li[Ni0.5Mn0.3Co0.2]O2 Cathode. , 2017, ACS applied materials & interfaces.

[2]  D. Morgan,et al.  Nanoscale Voltage Enhancement at Cathode Interfaces in Li-Ion Batteries , 2017, 1704.00872.

[3]  Muratahan Aykol,et al.  High-throughput computational design of cathode coatings for Li-ion batteries , 2016, Nature Communications.

[4]  C. Musgrave,et al.  Degradation of Ethylene Carbonate Electrolytes of Lithium Ion Batteries via Ring Opening Activated by LiCoO2 Cathode Surfaces and Electrolyte Species. , 2016, ACS applied materials & interfaces.

[5]  Debasish Mohanty,et al.  Effect of electrode manufacturing defects on electrochemical performance of lithium-ion batteries: Cognizance of the battery failure sources , 2016 .

[6]  David H. K. Jackson,et al.  Atomic Layer Deposition of Al2O3-Ga2O3 Alloy Coatings for Li[Ni0.5Mn0.3Co0.2]O2 Cathode to Improve Rate Performance in Li-Ion Battery. , 2016, ACS applied materials & interfaces.

[7]  David H. K. Jackson,et al.  Optimizing AlF3 atomic layer deposition using trimethylaluminum and TaF5: Application to high voltage Li-ion battery cathodes , 2016 .

[8]  Pengjian Zuo,et al.  Role of fluorine surface modification in improving electrochemical cyclability of concentration gradient Li[Ni0.73Co0.12Mn0.15]O2 cathode material for Li-ion batteries , 2016 .

[9]  Jaroslaw Knap,et al.  Towards high throughput screening of electrochemical stability of battery electrolytes , 2015, Nanotechnology.

[10]  D. Morgan,et al.  Lithium transport through lithium-ion battery cathode coatings , 2015, 1607.02125.

[11]  Xiqian Yu,et al.  Structural changes and thermal stability of charged LiNixMnyCozO₂ cathode materials studied by combined in situ time-resolved XRD and mass spectroscopy. , 2014, ACS applied materials & interfaces.

[12]  Muratahan Aykol,et al.  Thermodynamic Aspects of Cathode Coatings for Lithium‐Ion Batteries , 2014 .

[13]  Donald J. Siegel,et al.  Crystal Surface and State of Charge Dependencies of Electrolyte Decomposition on LiMn2O4 Cathode , 2014 .

[14]  Ahmad Pesaran,et al.  Electric Vehicle Battery Thermal Issues and Thermal Management Techniques , 2013 .

[15]  S. Greenbaum,et al.  Understanding Li(+)-Solvent Interaction in Nonaqueous Carbonate Electrolytes with (17)O NMR. , 2013, The journal of physical chemistry letters.

[16]  Huajun Guo,et al.  Washing effects on electrochemical performance and storage characteristics of LiNi0.8Co0.1Mn0.1O2 as cathode material for lithium-ion batteries , 2013 .

[17]  K. Leung First Principles Modeling of the Initial Stages of Organic Solvent Decomposition on Li(x)Mn(2)O(4) (100) Surfaces , 2012, 1209.3428.

[18]  Honghong Cheng,et al.  Enhanced Cycleabity in Lithium Ion Batteries: Resulting from Atomic Layer Depostion of Al2O3 or TiO2 on LiCoO2 Electrodes , 2012 .

[19]  Robert Kostecki,et al.  The mechanism of HF formation in LiPF6-based organic carbonate electrolytes , 2012 .

[20]  Sehee Lee,et al.  Using atomic layer deposition to hinder solvent decomposition in lithium ion batteries: first-principles modeling and experimental studies. , 2011, Journal of the American Chemical Society.

[21]  B. Lucht,et al.  Electrolyte Reactions with the Surface of High Voltage LiNi0.5Mn1.5O4 Cathodes for Lithium-Ion Batteries , 2010 .

[22]  Kevin Leung,et al.  Ab initio molecular dynamics simulations of the initial stages of solid-electrolyte interphase formation on lithium ion battery graphitic anodes. , 2010, Physical chemistry chemical physics : PCCP.

[23]  G. Ceder,et al.  Tailoring the Morphology of LiCoO2: A First Principles Study , 2009 .

[24]  G. Henkelman,et al.  A grid-based Bader analysis algorithm without lattice bias , 2009, Journal of physics. Condensed matter : an Institute of Physics journal.

[25]  M. Langell,et al.  Surface properties of LiCoO2, LiNiO2 and LiNi1−xCoxO2 , 2007 .

[26]  R. Holze,et al.  Cathode materials modified by surface coating for lithium ion batteries , 2006 .

[27]  Kristina Edström,et al.  The cathode-electrolyte interface in the Li-ion battery , 2004 .

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

[29]  G. Ceder,et al.  Towards more accurate First Principles prediction of redox potentials in transition-metal compounds with LDA+U , 2004, cond-mat/0406382.

[30]  P. Balbuena,et al.  Lithium-ion batteries : solid-electrolyte interphase , 2004 .

[31]  K. Tasaki Computational Study of Salt Association in Li-Ion Battery Electrolyte , 2002 .

[32]  Andrea G. Bishop,et al.  Surface analysis of LiMn2O4 electrodes in carbonate based electrolytes , 2002 .

[33]  P. Balbuena,et al.  Theoretical studies to understand surface chemistry on carbon anodes for lithium-ion batteries: reduction mechanisms of ethylene carbonate. , 2001, Journal of the American Chemical Society.

[34]  D. Aurbach,et al.  The study of the anodic stability of alkyl carbonate solutions by in situ FTIR spectroscopy, EQCM, NMR and MS , 2001 .

[35]  S. Matsuta,et al.  Electron-spin-resonance study of the reaction of electrolytic solutions on the positive electrode for lithium-ion secondary batteries , 2001 .

[36]  G. Henkelman,et al.  A climbing image nudged elastic band method for finding saddle points and minimum energy paths , 2000 .

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

[38]  P. Novák,et al.  SNIFTIRS investigation of the oxidative decomposition of organic-carbonate-based electrolytes for lithium-ion cells , 2000 .

[39]  Doron Aurbach,et al.  The Study of Surface Phenomena Related to Electrochemical Lithium Intercalation into Li x MO y Host Materials (M = Ni, Mn) , 2000 .

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

[41]  Blöchl,et al.  Projector augmented-wave method. , 1994, Physical review. B, Condensed matter.

[42]  Wang,et al.  Accurate and simple analytic representation of the electron-gas correlation energy. , 1992, Physical review. B, Condensed matter.

[43]  V. Anisimov,et al.  Band theory and Mott insulators: Hubbard U instead of Stoner I. , 1991, Physical review. B, Condensed matter.