论文信息 - Lithium-ion battery fast charging: A review - 字舞流文

Lithium-ion battery fast charging: A review

Abstract In the recent years, lithium-ion batteries have become the battery technology of choice for portable devices, electric vehicles and grid storage. While increasing numbers of car manufacturers are introducing electrified models into their offering, range anxiety and the length of time required to recharge the batteries are still a common concern. The high currents needed to accelerate the charging process have been known to reduce energy efficiency and cause accelerated capacity and power fade. Fast charging is a multiscale problem, therefore insights from atomic to system level are required to understand and improve fast charging performance. The present paper reviews the literature on the physical phenomena that limit battery charging speeds, the degradation mechanisms that commonly result from charging at high currents, and the approaches that have been proposed to address these issues. Special attention is paid to low temperature charging. Alternative fast charging protocols are presented and critically assessed. Safety implications are explored, including the potential influence of fast charging on thermal runaway characteristics. Finally, knowledge gaps are identified and recommendations are made for the direction of future research. The need to develop reliable onboard methods to detect lithium plating and mechanical degradation is highlighted. Robust model-based charging optimisation strategies are identified as key to enabling fast charging in all conditions. Thermal management strategies to both cool batteries during charging and preheat them in cold weather are acknowledged as critical, with a particular focus on techniques capable of achieving high speeds and good temperature homogeneities.

Xuning Feng | Minggao Ouyang | Gregory J. Offer | Ruihe Li | Jingyi Chen | Jiuyu Du | Xinhua Liu | Anna Tomaszewska | Zhengyu Chu | Simon E. J. O’Kane | Chenzhen Ji | Elizabeth Elaine Endler | Liu Lishuo | Yalun Li | Zheng Siqi | Sebastian Vetterlein | Ming Gao | Michael A. Parkes | Monica Marinescu | Billy Wu | Xuning Feng | M. Ouyang | M. Marinescu | G. Offer | M. Parkes | Billy Wu | Jiuyu Du | Mingming Gao | Yalun Li | Jingyi Chen | Xinhua Liu | Lishuo Liu | Zhengyu Chu | Siqi Zheng | C. Ji | Ruihe Li | S. O'Kane | A. Tomaszewska | S. Vetterlein | B. Wu | Elizabeth Endler | S. O’Kane

[1] Mahesh Krishnamurthy,et al. Challenges and Advancements in Fast Charging Solutions for EVs: A Technological Review , 2018, 2018 IEEE Transportation Electrification Conference and Expo (ITEC).

[2] Thomas Hanemann,et al. Preventing Li-ion cell explosion during thermal runaway with reduced pressure , 2017 .

[3] Ahmad Pesaran,et al. Thermal Evaluation of Toyota Prius Battery Pack , 2002 .

[4] Kang Xu,et al. Study of the charging process of a LiCoO2-based Li-ion battery , 2006 .

[5] Xuning Feng,et al. Thermal runaway mechanism of lithium ion battery for electric vehicles: A review , 2018 .

[6] Jun Yang,et al. Classification and Review of the Charging Strategies for Commercial Lithium-Ion Batteries , 2019, IEEE Access.

[7] Chaoyang Wang,et al. Lithium-ion battery structure that self-heats at low temperatures , 2016, Nature.

[8] Shanhai Ge,et al. Fast charging of lithium-ion batteries at all temperatures , 2018, Proceedings of the National Academy of Sciences.

[9] P. Notten,et al. A review on various temperature-indication methods for Li-ion batteries , 2019, Applied Energy.

[10] Delphine Riu,et al. A review on lithium-ion battery ageing mechanisms and estimations for automotive applications , 2013 .

[11] J.H.G. Op het Veld,et al. Boostcharging Li-ion batteries: A challenging new charging concept , 2005 .

[12] Ralph E. White,et al. Capacity Fade Mechanisms and Side Reactions in Lithium‐Ion Batteries , 1998 .

[13] Andreas Gruhle,et al. Lithium flow between active area and overhang of graphite anodes as a function of temperature and overhang geometry , 2019, Journal of Energy Storage.

[14] P. Ajayan,et al. Synthesis of nitrogen-doped graphene films for lithium battery application. , 2010, ACS nano.

[15] Marius Bauer,et al. Fast charging of lithium-ion cells: Identification of aging-minimal current profiles using a design of experiment approach and a mechanistic degradation analysis , 2018, Journal of Energy Storage.

[16] Chaoyang Wang,et al. Innovative heating of large-size automotive Li-ion cells , 2017 .

[17] Y. Patel,et al. The effect of cell-to-cell variations and thermal gradients on the performance and degradation of lithium-ion battery packs , 2019, Applied Energy.

[18] Petr Novák,et al. Oxidative Electrolyte Solvent Degradation in Lithium‐Ion Batteries: An In Situ Differential Electrochemical Mass Spectrometry Investigation , 1999 .

[19] Piero Pianetta,et al. Thermally driven mesoscale chemomechanical interplay in Li0.5Ni0.6Mn0.2Co0.2O2 cathode materials , 2018 .

[20] Ilke Arslan,et al. Direct visualization of initial SEI morphology and growth kinetics during lithium deposition by in situ electrochemical transmission electron microscopy. , 2014, Chemical communications.

[21] John Newman,et al. Two-Dimensional Modeling of Lithium Deposition during Cell Charging , 2008 .

[22] Xiaoqing Zhu,et al. Overcharge investigation of large format lithium-ion pouch cells with Li(Ni0.6Co0.2Mn0.2)O2 cathode for electric vehicles: Thermal runaway features and safety management method , 2019, Energy.

[23] P. Kohl,et al. The effects of pulse charging on cycling characteristics of commercial lithium-ion batteries , 2001 .

[24] Zhong Li,et al. Niobium doped lithium titanate as a high rate anode material for Li-ion batteries , 2010 .

[25] Liwen Jin,et al. Thermal Management of Densely-packed EV Battery with Forced Air Cooling Strategies , 2016 .

[26] Ziping Feng,et al. Non-uniform effect on the thermal/aging performance of Lithium-ion pouch battery , 2018 .

[27] Ricardo Martinez-Botas,et al. An easy-to-parameterise physics-informed battery model and its application towards lithium-ion battery cell design, diagnosis, and degradation , 2018 .

[28] Yang Ren,et al. In situ high-energy X-ray diffraction to study overcharge abuse of 18650-size lithium-ion battery , 2013 .

[29] Sheldon S. Williamson,et al. A Closed-Loop Constant-Temperature Constant-Voltage Charging Technique to Reduce Charge Time of Lithium-Ion Batteries , 2019, IEEE Transactions on Industrial Electronics.

[30] Yoyo Hinuma,et al. Lithium Diffusion in Graphitic Carbon , 2010, 1108.0576.

[31] Piero Pianetta,et al. Chemomechanical interplay of layered cathode materials undergoing fast charging in lithium batteries , 2018, Nano Energy.

[32] Reiner Mönig,et al. Comparison of the growth of lithium filaments and dendrites under different conditions , 2015 .

[33] Jianqiu Li,et al. Non-destructive fast charging algorithm of lithium-ion batteries based on the control-oriented electrochemical model , 2017 .

[34] Jin Wang,et al. Charging Strategy Studies for PHEV Batteries based on Power Loss Model , 2010 .

[35] Kevin W. Eberman,et al. Colossal Reversible Volume Changes in Lithium Alloys , 2001 .

[36] Yatish Patel,et al. Preventing lithium ion battery failure during high temperatures by externally applied compression , 2017 .

[37] Shengbo Zhang. The effect of the charging protocol on the cycle life of a Li-ion battery , 2006 .

[38] Zhijia Du,et al. Understanding limiting factors in thick electrode performance as applied to high energy density Li-ion batteries , 2017, Journal of Applied Electrochemistry.

[39] Robert G. Landers,et al. A Single Particle Model for Lithium-Ion Batteries with Electrolyte and Stress-Enhanced Diffusion Physics , 2017 .

[40] Andreas Jossen,et al. Simulation and Measurement of the Current Density Distribution in Lithium-Ion Batteries by a Multi-Tab Cell Approach , 2017 .

[41] Martin Winter,et al. Electrochemical in situ investigations of SEI and dendrite formation on the lithium metal anode. , 2015, Physical chemistry chemical physics : PCCP.

[42] Xuning Feng,et al. Low temperature aging mechanism identification and lithium deposition in a large format lithium iron phosphate battery for different charge profiles , 2015 .

[43] Gregory J. Offer,et al. How Observable Is Lithium Plating? Differential Voltage Analysis to Identify and Quantify Lithium Plating Following Fast Charging of Cold Lithium-Ion Batteries , 2019, Journal of The Electrochemical Society.

[44] Marcello Torchio,et al. Optimising lithium-ion cell design for plug-in hybrid and battery electric vehicles , 2019, Journal of Energy Storage.

[45] D. Sauer,et al. Characterization of high-power lithium-ion batteries by electrochemical impedance spectroscopy. I. Experimental investigation , 2011 .

[46] Ricardo Martinez-Botas,et al. A physically meaningful equivalent circuit network model of a lithium-ion battery accounting for local electrochemical and thermal behaviour, variable double layer capacitance and degradation , 2016 .

[47] Sohel Anwar,et al. Electrochemical model based charge optimization for lithium-ion batteries , 2016 .

[48] Thanh Tu Vo,et al. Charging algorithms of lithium-ion batteries: An overview , 2012, 2012 7th IEEE Conference on Industrial Electronics and Applications (ICIEA).

[49] Chao-Yang Wang,et al. Understanding the trilemma of fast charging, energy density and cycle life of lithium-ion batteries , 2018, Journal of Power Sources.

[50] Kevin G. Gallagher,et al. Optimizing areal capacities through understanding the limitations of lithium-ion electrodes , 2016 .

[51] Chaoyang Wang,et al. Li-Ion Cell Operation at Low Temperatures , 2013 .

[52] Jeonghun Cho,et al. Pulse-Based Fast Battery IoT Charger Using Dynamic Frequency and Duty Control Techniques Based on Multi-Sensing of Polarization Curve , 2016 .

[53] Jianqiu Li,et al. Investigation of Lithium Plating-Stripping Process in Li-Ion Batteries at Low Temperature Using an Electrochemical Model , 2018 .

[54] Andreas Gruhle,et al. A new method for detecting lithium plating by measuring the cell thickness , 2014 .

[55] Lijun Wu,et al. Structural Origin of Overcharge-Induced Thermal Instability of Ni-Containing Layered-Cathodes for High-Energy-Density Lithium Batteries , 2011 .

[56] Moses Ender,et al. In situ detection of lithium metal plating on graphite in experimental cells , 2015 .

[57] Magnus Rohde,et al. Thermal behavior and electrochemical heat generation in a commercial 40 Ah lithium ion pouch cell , 2015 .

[58] Bing Xia,et al. Loss-Minimization-Based Charging Strategy for Lithium-Ion Battery , 2015, IEEE Transactions on Industry Applications.

[59] Xiangyun Song,et al. Correlation between dissolution behavior and electrochemical cycling performance for LiNi1/3Co1/3Mn1/3O2-based cells , 2012 .

[60] Chao-Yang Wang,et al. In-Situ Measurement of Current Distribution in a Li-Ion Cell , 2013 .

[61] Sylvie Grugeon,et al. Deciphering the multi-step degradation mechanisms of carbonate-based electrolyte in Li batteries , 2008 .

[62] Feiyu Kang,et al. Structural and thermal stabilities of layered Li(Ni1/3Co1/3Mn1/3)O2 materials in 18650 high power batteries , 2011 .

[63] M. Wohlfahrt‐Mehrens,et al. Li plating as unwanted side reaction in commercial Li-ion cells - A review , 2018 .

[64] Rolf Findeisen,et al. Electrochemical Model Based Observer Design for a Lithium-Ion Battery , 2013, IEEE Transactions on Control Systems Technology.

[65] Hansu Kim,et al. Improved fast charging capability of graphite anodes via amorphous Al2O3 coating for high power lithium ion batteries , 2019, Journal of Power Sources.

[66] Joeri Van Mierlo,et al. Three-dimensional electro-thermal model of li-ion pouch cell: Analysis and comparison of cell design factors and model assumptions , 2017 .

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

[68] Jianming Zheng,et al. Intragranular cracking as a critical barrier for high-voltage usage of layer-structured cathode for lithium-ion batteries , 2017, Nature Communications.

[69] U. V. Varadaraju,et al. Facile Insertion of Lithium into Nanocrystalline AlNbO4 at Room Temperature. , 2008 .

[70] Edgar Sánchez-Sinencio,et al. Search for Optimal Pulse Charging Parameters for Li-Ion Polymer Batteries Using Taguchi Orthogonal Arrays , 2018, IEEE Transactions on Industrial Electronics.

[71] Thomas J. Richardson,et al. Visualization of Charge Distribution in a Lithium Battery Electrode , 2010 .

[72] W. Craig Carter,et al. Design criteria for electrochemical shock resistant battery electrodes , 2012 .

[73] Zhe Li,et al. Temperature-Adaptive Alternating Current Preheating of Lithium-Ion Batteries with Lithium Deposition Prevention , 2016 .

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

[75] Margret Wohlfahrt-Mehrens,et al. Aging mechanisms of lithium cathode materials , 2004 .

[76] Jeff Dahn,et al. Exploring Classes of Co-Solvents for Fast-Charging Lithium-Ion Cells , 2018 .

[77] Xiaosong Hu,et al. Charging optimization in lithium-ion batteries based on temperature rise and charge time , 2017 .

[78] U. Landau,et al. Rapid Charging of Lithium-Ion Batteries Using Pulsed Currents A Theoretical Analysis , 2006 .

[79] Alan C. West,et al. Effect of Electrolyte Composition on Lithium Dendrite Growth , 2008 .

[80] Shanhai Ge,et al. A look into the voltage plateau signal for detection and quantification of lithium plating in lithium-ion cells , 2018, Journal of Power Sources.

[81] B. Vural,et al. A dynamic lithium-ion battery model considering the effects of temperature and capacity fading , 2009, 2009 International Conference on Clean Electrical Power.

[82] Yang-Tse Cheng,et al. Electrode Side Reactions, Capacity Loss and Mechanical Degradation in Lithium-Ion Batteries , 2015 .

[83] Nikolay Dimov,et al. Suppression of lithium deposition at sub-zero temperatures on graphite by surface modification , 2011 .

[84] Xuning Feng,et al. Influence of aging paths on the thermal runaway features of lithium-ion batteries in accelerating rate calorimetry tests , 2019, International Journal of Electrochemical Science.

[85] M. Verbrugge,et al. The effect of large negative potentials and overcharge on the electrochemical performance of lithiated carbon , 1997 .

[86] Richard Barney Carlson,et al. Enabling fast charging – A battery technology gap assessment , 2017 .

[87] Weige Zhang,et al. Study on battery pack consistency evolutions and equilibrium diagnosis for serial- connected lithium-ion batteries , 2017 .

[88] Seungjun Lee,et al. Mechanical Failure Analysis of Graphite Anode Particles with PVDF Binders in Li-Ion Batteries , 2018 .

[89] Christopher J. Orendorff,et al. How Electrolytes Influence Battery Safety. , 2012 .

[90] E. Roth,et al. Thermal abuse performance of high-power 18650 Li-ion cells , 2004 .

[91] M. Wohlfahrt‐Mehrens,et al. Interaction of cyclic ageing at high-rate and low temperatures and safety in lithium-ion batteries , 2015 .

[92] Marc Doyle,et al. Mathematical Modeling of the Lithium Deposition Overcharge Reaction in Lithium‐Ion Batteries Using Carbon‐Based Negative Electrodes , 1999 .

[93] Minggao Ouyang,et al. Time Sequence Map for Interpreting the Thermal Runaway Mechanism of Lithium-Ion Batteries With LiNixCoyMnzO2 Cathode , 2018, Front. Energy Res..

[94] Florian Bouville,et al. Magnetically aligned graphite electrodes for high-rate performance Li-ion batteries , 2016, Nature Energy.

[95] Bor Yann Liaw,et al. Optimal charging method for lithium ion batteries using a universal voltage protocol accommodating aging , 2015 .

[96] Daniel P. Abraham,et al. Quantifying lithium concentration gradients in the graphite electrode of Li-ion cells using operando energy dispersive X-ray diffraction , 2019, Energy & Environmental Science.

[97] Reza S. Yassar,et al. Real-time observation of lithium fibers growth inside a nanoscale lithium-ion battery , 2011 .

[98] Richard Barney Carlson,et al. Enabling fast charging – Vehicle considerations , 2017 .

[99] Thomas Waldmann,et al. Optimization of Charging Strategy by Prevention of Lithium Deposition on Anodes in high-energy Lithium-ion Batteries – Electrochemical Experiments , 2015 .

[100] Kejie Zhao,et al. Disintegration of Meatball Electrodes for LiNixMnyCozO2 Cathode Materials , 2018 .

[101] Francesco Nobili,et al. Low-temperature behavior of graphite-tin composite anodes for Li-ion batteries , 2010 .

[102] Rolf Findeisen,et al. Optimal charging strategies in lithium-ion battery , 2011, Proceedings of the 2011 American Control Conference.

[103] Ellen Ivers-Tiffée,et al. A novel and precise measuring method for the entropy of lithium-ion cells: ΔS via electrothermal impedance spectroscopy , 2014 .

[104] Geping Yin,et al. Understanding undesirable anode lithium plating issues in lithium-ion batteries , 2016 .

[105] Andreas Jossen,et al. Multi-directional laser scanning as innovative method to detect local cell damage during fast charging of lithium-ion cells , 2016 .

[106] Masahiro Kinoshita,et al. Capacity fade of LiAlyNi1−x−yCoxO2 cathode for lithium-ion batteries during accelerated calendar and cycle life tests (surface analysis of LiAlyNi1−x−yCoxO2 cathode after cycle tests in restricted depth of discharge ranges) , 2014 .

[107] Ting Zhu,et al. Electrochemomechanical degradation of high-capacity battery electrode materials , 2017 .

[108] Li Wang,et al. Probing the heat sources during thermal runaway process by thermal analysis of different battery chemistries , 2018 .

[109] Dongqiang Liu,et al. Lithium Ion Intercalation Performance of Niobium Oxides: KNb5O13 and K6Nb10.8O30 , 2009 .

[110] Byung-Ki Na,et al. Manufacturing and Electrochemical Characteristics of SnO 2 /Li 4 Ti 5 O 12 for Lithium Ion Battery , 2015 .

[111] L. Wang,et al. A rapid low-temperature internal heating strategy with optimal frequency based on constant polarization voltage for lithium-ion batteries , 2016 .

[112] Chaohe Xu,et al. Graphene-based electrodes for electrochemical energy storage , 2013 .

[113] C. Wan,et al. Thermal Stability of the Solid Electrolyte Interface on Carbon Electrodes of Lithium Batteries , 2004 .

[114] Mark W. Verbrugge,et al. Degradation of lithium ion batteries employing graphite negatives and nickel–cobalt–manganese oxide + spinel manganese oxide positives: Part 2, chemical–mechanical degradation model , 2014 .

[115] Javad Askari,et al. A charging method for Lithium-ion battery using Min-max optimal control , 2014, 2014 22nd Iranian Conference on Electrical Engineering (ICEE).

[116] Zhe Li,et al. Modeling the capacity degradation of LiFePO 4/graphite batteries based on stress coupling analysis , 2011 .

[117] K. Jalkanen,et al. Entropy change effects on the thermal behavior of a LiFePO4/graphite lithium-ion cell at different states of charge , 2013 .

[118] Yan Wang,et al. The design of a high-energy Li-ion battery using germanium-based anode and LiCoO2 cathode , 2015 .

[119] Zongping Shao,et al. Synthesis of pristine and carbon-coated Li4Ti5O12 and their low-temperature electrochemical performance , 2010 .

[120] Jianqiu Li,et al. Thermal Runaway of Lithium-Ion Batteries without Internal Short Circuit , 2018, Joule.

[121] John B. Goodenough,et al. 3-V Full Cell Performance of Anode Framework TiNb2O7/Spinel LiNi0.5Mn1.5O4 , 2011 .

[122] Martin Winter,et al. How Do Reactions at the Anode/Electrolyte Interface Determine the Cathode Performance in Lithium-Ion Batteries? , 2013 .

[123] Amartya Mukhopadhyay,et al. Deformation and stress in electrode materials for Li-ion batteries , 2014 .

[124] Masahiro Kinoshita,et al. Capacity fading of LiAlyNi1−x−yCoxO2 cathode for lithium-ion batteries during accelerated calendar and cycle life tests (effect of depth of discharge in charge–discharge cycling on the suppression of the micro-crack generation of LiAlyNi1−x−yCoxO2 particle) , 2014 .

[125] Qiujiang Liu,et al. Evaluation of Acceptable Charging Current of Power Li-Ion Batteries Based on Polarization Characteristics , 2014, IEEE Transactions on Industrial Electronics.

[126] Harald Scholz,et al. Evaluation of Fast Charging Efficiency under Extreme Temperatures , 2018, Energies.

[127] Li Jia,et al. A pseudo three-dimensional electrochemical–thermal model of a prismatic LiFePO4 battery during discharge process , 2015 .

[128] Siamak Farhad,et al. Heat generation in lithium-ion batteries with different nominal capacities and chemistries , 2017 .

[129] Bor Yann Liaw,et al. Fast charge implications: Pack and cell analysis and comparison , 2018 .

[130] Charles Delacourt,et al. Experimental and Modeling Analysis of Graphite Electrodes with Various Thicknesses and Porosities for High-Energy-Density Li-Ion Batteries , 2018 .

[131] Juha Pyrhonen,et al. Determination of the entropy change profile of a cylindrical lithium-ion battery by heat flux measurements , 2016 .

[132] M. Wohlfahrt‐Mehrens,et al. Ageing mechanisms in lithium-ion batteries , 2005 .

[133] Sean Parkin,et al. A fast, inexpensive method for predicting overcharge performance in lithium-ion batteries , 2014 .

[134] Linsen Li,et al. High-performance battery electrodes via magnetic templating , 2016, Nature Energy.

[135] Michael G. Pecht,et al. Tab Design and Failures in Cylindrical Li-ion Batteries , 2019, IEEE Access.

[136] Bernard Bäker,et al. Current density and state of charge inhomogeneities in Li-ion battery cells with LiFePO4 as cathode material due to temperature gradients , 2011 .

[137] M. Dubarry,et al. Operando lithium plating quantification and early detection of a commercial LiFePO 4 cell cycled under dynamic driving schedule , 2017 .

[138] Daniel P. Abraham,et al. First-cycle irreversibility of layered Li–Ni–Co–Mn oxide cathode in Li-ion batteries , 2008 .

[139] J. C. Burns,et al. In-Situ Detection of Lithium Plating Using High Precision Coulometry , 2015 .

[140] Mary Patterson. Chemical Shuttle Additives in Lithium Ion Batteries , 2013 .

[141] Ardalan Vahidi,et al. Maximizing charging efficiency of lithium-ion and lead-acid batteries using optimal control theory , 2015, 2015 American Control Conference (ACC).

[142] M. Wohlfahrt‐Mehrens,et al. Electrochemical, Post-Mortem, and ARC Analysis of Li-Ion Cell Safety in Second-Life Applications , 2017 .

[143] Jun Li,et al. Fast lithium growth and short circuit induced by localized-temperature hotspots in lithium batteries , 2019, Nature Communications.

[144] Zhenan Bao,et al. Fast and reversible thermoresponsive polymer switching materials for safer batteries , 2016, Nature Energy.

[145] Jianqiu Li,et al. Simplification of physics-based electrochemical model for lithium ion battery on electric vehicle. Part II: Pseudo-two-dimensional model simplification and state of charge estimation , 2015 .

[146] Gan Ning,et al. Capacity fade study of lithium-ion batteries cycled at high discharge rates , 2003 .

[147] Joeri Van Mierlo,et al. Influence analysis of static and dynamic fast-charging current profiles on ageing performance of commercial lithium-ion batteries , 2017 .

[148] Zhansheng Guo,et al. Direct in situ observation and explanation of lithium dendrite of commercial graphite electrodes , 2015 .

[149] Kazuma Gotoh,et al. In Situ Solid State 7Li NMR Observations of Lithium Metal Deposition during Overcharge in Lithium Ion Batteries , 2015 .

[150] Jian Li,et al. Efficient thermal management of Li-ion batteries with a passive interfacial thermal regulator based on a shape memory alloy , 2018, Nature Energy.

[151] A. Jossen,et al. Fast and Accurate Measurement of Entropy Profiles of Commercial Lithium-Ion Cells , 2015 .

[152] Qingsong Wang,et al. Thermal runaway caused fire and explosion of lithium ion battery , 2012 .

[153] David Anseán,et al. Fast charging technique for high power lithium iron phosphate batteries: A cycle life analysis , 2013 .

[154] Robert Kostecki,et al. Electrochemical activity of carbon blacks in LiPF6-based organic electrolytes , 2013 .

[155] Wei Zhao,et al. Effect of tab design on large-format Li-ion cell performance , 2014 .

[156] Xiaosong Hu,et al. Optimal charging of batteries via a single particle model with electrolyte and thermal dynamics , 2016, 2016 American Control Conference (ACC).

[157] Minhua Shao,et al. In situ microscopic studies on the structural and chemical behaviors of lithium-ion battery materials , 2014 .

[158] Qingsong Wang,et al. Thermal Behavior of Lithiated Graphite with Electrolyte in Lithium-Ion Batteries , 2006 .

[159] V. K. Peterson,et al. Overcharging a lithium-ion battery: Effect on the LixC6 negative electrode determined by in situ neutron diffraction , 2013 .

[160] Henk Nijmeijer,et al. Battery thermal management by boiling heat-transfer , 2014 .

[161] Vincent Chevrier,et al. In Situ Detection of Lithium Plating on Graphite Electrodes by Electrochemical Calorimetry , 2013 .

[162] Lei Cao,et al. A review on battery thermal management in electric vehicle application , 2017 .

[163] Thomas R. B. Grandjean,et al. Large format lithium ion pouch cell full thermal characterisation for improved electric vehicle thermal management , 2017 .

[164] Philippe Marty,et al. Experimental performances of a battery thermal management system using a phase change material , 2014 .

[165] Yuichi Sato,et al. Overcharge reaction of lithium-ion batteries , 2005 .

[166] Martin Knipper,et al. Hysteresis and current dependence of the graphite anode color in a lithium-ion cell and analysis of lithium plating at the cell edge , 2018 .

[167] F. Chevallier,et al. In situ 7Li nuclear magnetic resonance observation of the electrochemical intercalation of lithium in graphite; 1st cycle , 2007 .

[168] M. Wohlfahrt‐Mehrens,et al. Temperature dependent ageing mechanisms in Lithium-ion batteries – A Post-Mortem study , 2014 .

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

[170] Michael A. Danzer,et al. Nondestructive detection, characterization, and quantification of lithium plating in commercial lithium-ion batteries , 2014 .

[171] Michio Inagaki,et al. Carbon-coated graphite for anode of lithium ion rechargeable batteries: Graphite substrates for carbon coating , 2009 .

[172] Andreas Jossen,et al. Charging protocols for lithium-ion batteries and their impact on cycle life—An experimental study with different 18650 high-power cells , 2016 .

[173] William A Goddard,et al. Dynamics of Lithium Dendrite Growth and Inhibition: Pulse Charging Experiments and Monte Carlo Calculations. , 2014, The journal of physical chemistry letters.

[174] Yi Cui,et al. Challenges and opportunities towards fast-charging battery materials , 2019, Nature Energy.

[175] Michael M. Thackeray,et al. Spinel Anodes for Lithium‐Ion Batteries , 1994 .

[176] Shaojun Guo,et al. MoS2 Nanosheet Assembling Superstructure with a Three-Dimensional Ion Accessible Site: A New Class of Bifunctional Materials for Batteries and Electrocatalysis , 2016 .

[177] Alberto Salvadori,et al. Computational modeling of Li-ion batteries , 2016 .

[178] Marshall C. Smart,et al. Factors Limiting Li + Charge Transfer Kinetics in Li-Ion Batteries , 2017 .

[179] Kristina Edström,et al. Chemical Composition and Morphology of the Elevated Temperature SEI on Graphite , 2001 .

[180] Chaoyang Wang,et al. Heating strategies for Li-ion batteries operated from subzero temperatures , 2013 .

[181] Remi Petibon,et al. Effects of Electrolyte Additives and Solvents on Unwanted Lithium Plating in Lithium-Ion Cells , 2017 .

[182] Simon F. Schuster,et al. Nonlinear aging of cylindrical lithium-ion cells linked to heterogeneous compression , 2016 .

[183] Chris Manzie,et al. PDE battery model simplification for charging strategy evaluation , 2015, 2015 10th Asian Control Conference (ASCC).

[184] She-huang Wu,et al. Preparation of Advanced Carbon Anode Materials from Mesocarbon Microbeads for Use in High C-Rate Lithium Ion Batteries , 2015, Materials.

[185] Gregory J. Offer,et al. Modeling the effects of thermal gradients induced by tab and surface cooling on lithium ion cell performance , 2018 .

[186] Bob R. Powell,et al. Lithium Polyacrylate (LiPAA) as an Advanced Binder and a Passivating Agent for High‐Voltage Li‐Ion Batteries , 2015 .

[187] Kyung Min Jeong,et al. Effects of Capacity Ratios between Anode and Cathode on Electrochemical Properties for Lithium Polymer Batteries , 2015 .

[188] Xiaodong Zheng,et al. High-rate Li4Ti5O12/C composites as anode for lithium-ion batteries , 2013, Ionics.

[189] Jianqiu Li,et al. Simplification of physics-based electrochemical model for lithium ion battery on electric vehicle. Part I: Diffusion simplification and single particle model , 2015 .

[190] Ralph E. White,et al. Maximizing the Life of a Lithium-Ion Cell by Optimization of Charging Rates , 2010 .

[191] Martin Z. Bazant,et al. Toward Optimal Performance and In‐Depth Understanding of Spinel Li4Ti5O12 Electrodes through Phase Field Modeling , 2018 .

[192] Yan Yu,et al. A Review on Lithium-Ion Batteries Safety Issues: Existing Problems and Possible Solutions , 2012 .

[193] Hao Mu,et al. Research on the Battery Charging Strategy With Charging and Temperature Rising Control Awareness , 2018, IEEE Access.

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

[195] Scott J. Moura,et al. BATTERY CHARGE CONTROL WITH AN ELECTRO-THERMAL-AGING COUPLING , 2015 .

[196] Yury Gogotsi,et al. Thickness-independent capacitance of vertically aligned liquid-crystalline MXenes , 2018, Nature.

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

[198] Katsuhito Takei,et al. Gas generation mechanism due to electrolyte decomposition in commercial lithium-ion cell , 1999 .

[199] Minggao Ouyang,et al. Thermal runaway features of large format prismatic lithium ion battery using extended volume accelerating rate calorimetry , 2014 .

[200] Song-Yul Choe,et al. Fast charging method based on estimation of ion concentrations using a reduced order of Electrochemical Thermal Model for lithium ion polymer battery , 2013, 2013 World Electric Vehicle Symposium and Exhibition (EVS27).

[201] Toshiyuki Momma,et al. In situ observation of lithium deposition processes in solid polymer and gel electrolytes , 1997 .

[202] Kyeongse Song,et al. Carbon‐Coated Si Nanoparticles Anchored between Reduced Graphene Oxides as an Extremely Reversible Anode Material for High Energy‐Density Li‐Ion Battery , 2016 .

[203] Christopher D. Rahn,et al. Effects of Non-Uniform Current Distribution on Energy Density of Li-Ion Cells , 2013 .

[204] Zhe Li,et al. Investigating Lithium Plating in Lithium-Ion Batteries at Low Temperatures Using Electrochemical Model with NMR Assisted Parameterization , 2017 .

[205] K. M. Abraham,et al. Thermal stability of lithium-ion battery electrolytes , 2003 .

[206] Gregory L. Plett,et al. Controls oriented reduced order modeling of lithium deposition on overcharge , 2012 .

[207] Nigel P. Brandon,et al. Coupled thermal–electrochemical modelling of uneven heat generation in lithium-ion battery packs , 2013 .

[208] Giannantonio Cibin,et al. Niobium tungsten oxides for high-rate lithium-ion energy storage , 2018, Nature.

[209] Bor Yann Liaw,et al. Lithium Plating Detection and Quantification in Li-Ion Cells from Degradation Behaviors , 2017 .

[210] Haifeng Dai,et al. Experimental investigations of an AC pulse heating method for vehicular high power lithium-ion batteries at subzero temperatures , 2017 .

[211] Yury Gogotsi,et al. Hollow MXene Spheres and 3D Macroporous MXene Frameworks for Na‐Ion Storage , 2017, Advanced materials.

[212] M. Doyle,et al. Simulation and Optimization of the Dual Lithium Ion Insertion Cell , 1994 .

[213] Andreas Jossen,et al. Optimum fast charging of lithium-ion pouch cells based on local volume expansion criteria , 2018, Journal of Power Sources.

[214] P. Ramadass,et al. Analysis of internal short-circuit in a lithium ion cell , 2009 .

[215] Alexander W. Abboud,et al. Communication—Implications of Local Current Density Variations on Lithium Plating Affected by Cathode Particle Size , 2019, Journal of The Electrochemical Society.

[216] Göran Lindbergh,et al. Fast-charging to a partial state of charge in lithium-ion batteries: A comparative ageing study , 2017 .

[217] Ralph E. White,et al. Comparison of the capacity fade of Sony US 18650 cells charged with different protocols , 2003 .

[218] Gregory J. Offer,et al. Surface Cooling Causes Accelerated Degradation Compared to Tab Cooling for Lithium-Ion Pouch Cells , 2016 .

[219] Feng Li,et al. Doped graphene sheets as anode materials with superhigh rate and large capacity for lithium ion batteries. , 2011, ACS nano.

[220] Zhigang Suo,et al. Fracture of electrodes in lithium-ion batteries caused by fast charging , 2010 .

[221] Alexander Michaelis,et al. Local Heat Generation in a Single Stack Lithium Ion Battery Cell , 2015 .

[222] P. Bruce,et al. Degradation diagnostics for lithium ion cells , 2017 .

[223] Chen‐Zi Zhao,et al. Fast Charging Lithium Batteries: Recent Progress and Future Prospects. , 2019, Small.

[224] Ui Seong Kim,et al. Modeling the Thermal Behaviors of a Lithium-Ion Battery during Constant-Power Discharge and Charge Operations , 2013 .

[225] Ulrike Krewer,et al. Identification of Lithium Plating in Lithium-Ion Batteries using Nonlinear Frequency Response Analysis (NFRA) , 2018, Electrochimica Acta.

[226] Takamitsu Tajima,et al. Boiling Liquid Battery Cooling for Electric Vehicle , 2014, 2014 IEEE Conference and Expo Transportation Electrification Asia-Pacific (ITEC Asia-Pacific).

[227] Ningning Wu,et al. Electrochemical and Mechanical Failure of Graphite-Based Anode Materials in Li-Ion Batteries for Electric Vehicles , 2016 .

[228] Feng Lin,et al. Chemomechanical behaviors of layered cathode materials in alkali metal ion batteries , 2018 .

[229] Venkat Srinivasan,et al. Examination of Graphite Particle Cracking as a Failure Mode in Lithium-Ion Batteries: A Model-Experimental Study , 2015 .

[230] Xuemei Zhao,et al. A High Precision Coulometry Study of the SEI Growth in Li/Graphite Cells , 2011 .

[231] Yi Cui,et al. Fracture of crystalline silicon nanopillars during electrochemical lithium insertion , 2012, Proceedings of the National Academy of Sciences.

[232] Aniruddha Jana,et al. Lithium dendrite growth mechanisms in liquid electrolytes , 2017 .

[233] Ottorino Veneri,et al. Technologies and Applications for Smart Charging of Electric and Plug-in Hybrid Vehicles , 2017 .

[234] Jianqiu Li,et al. Model-based thermal runaway prediction of lithium-ion batteries from kinetics analysis of cell components , 2018, Applied Energy.

[235] Alexej Jerschow,et al. Correlating Microstructural Lithium Metal Growth with Electrolyte Salt Depletion in Lithium Batteries Using ⁷Li MRI. , 2015, Journal of the American Chemical Society.

[236] V. Presser,et al. Two‐Dimensional Nanocrystals Produced by Exfoliation of Ti3AlC2 , 2011, Advanced materials.

[237] Bryant J. Polzin,et al. Extreme Fast Charge Challenges for Lithium-Ion Battery: Variability and Positive Electrode Issues , 2019, Journal of The Electrochemical Society.

[238] Jianqiu Li,et al. An electrochemical-thermal coupled overcharge-to-thermal-runaway model for lithium ion battery , 2017 .

[239] Partha P. Mukherjee,et al. Analysis of the Implications of Rapid Charging on Lithium-Ion Battery Performance , 2015 .

[240] Phl Peter Notten,et al. Mathematical modelling of ionic transport in the electrolyte of Li-ion batteries , 2008 .

[241] Marius Bauer,et al. Voltage relaxation and impedance spectroscopy as in-operando methods for the detection of lithium plating on graphitic anodes in commercial lithium-ion cells , 2016 .

[242] John P. Sullivan,et al. Lithium Fiber Growth on the Anode in a Nanowire Lithium Ion Battery During Charging , 2011 .

[243] W. Craig Carter,et al. “Electrochemical Shock” of Intercalation Electrodes: A Fracture Mechanics Analysis , 2010 .

[244] Li Wang,et al. A Coupled Electrochemical-Thermal Failure Model for Predicting the Thermal Runaway Behavior of Lithium-Ion Batteries , 2018 .

[245] Prashant N. Kumta,et al. Interfacial Properties of the a-Si ∕ Cu :Active–Inactive Thin-Film Anode System for Lithium-Ion Batteries , 2006 .

[246] Tsair-Rong Chen,et al. Sinusoidal-Ripple-Current Charging Strategy and Optimal Charging Frequency Study for Li-Ion Batteries , 2013, IEEE Transactions on Industrial Electronics.

[247] Jianqiu Li,et al. Overcharge-induced capacity fading analysis for large format lithium-ion batteries with LiyNi1/3Co1/3Mn1/3O2 + LiyMn2O4 composite cathode , 2015 .

[248] James Francfort,et al. Enabling fast charging – Battery thermal considerations , 2017 .

[249] Jeff Dahn,et al. Quantifying inhomogeneity of lithium ion battery electrodes and its influence on electrochemical performance , 2018 .

[250] Arnulf Latz,et al. Influence of local lithium metal deposition in 3D microstructures on local and global behavior of Lithium-ion batteries , 2016 .

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

[252] M. Doyle,et al. Modeling of Galvanostatic Charge and Discharge of the Lithium/Polymer/Insertion Cell , 1993 .

[253] Kang Xu,et al. Optimization of the forming conditions of the solid-state interface in the Li-ion batteries , 2004 .

[254] Ilias Belharouak,et al. Identifying the limiting electrode in lithium ion batteries for extreme fast charging , 2018, Electrochemistry Communications.

[255] Bo Lu,et al. Stress-limited fast charging methods with time-varying current in lithium-ion batteries , 2018, Electrochimica Acta.

[256] Ralph E. White,et al. Effect of Porosity on the Capacity Fade of a Lithium-Ion Battery Theory , 2004 .

[257] Andreas Jossen,et al. Lithium plating in lithium-ion batteries investigated by voltage relaxation and in situ neutron diffraction , 2017 .

[258] Yi Cui,et al. Composite lithium metal anode by melt infusion of lithium into a 3D conducting scaffold with lithiophilic coating , 2016, Proceedings of the National Academy of Sciences.

[259] M Rosa Palacín,et al. Understanding ageing in Li-ion batteries: a chemical issue. , 2018, Chemical Society reviews.

[260] Michael R Hoffmann,et al. Quantifying the dependence of dead lithium losses on the cycling period in lithium metal batteries. , 2014, Physical chemistry chemical physics : PCCP.