Semi-empirical cyclic aging model for stationary storages based on graphite anode aging mechanisms

[1]  W. Chueh,et al.  Physics-based, reduced order degradation model of lithium-ion batteries , 2022, Journal of Power Sources.

[2]  D. Sauer,et al.  The influence of frequency containment reserve on the cycles of a hybrid stationary large-scale storage system , 2022, Journal of Energy Storage.

[3]  A. Latz,et al.  A four parameter model for the solid-electrolyte interphase to predict battery aging during operation , 2021, Journal of Power Sources.

[4]  C. Agert,et al.  Incremental Capacity Analysis as a State of Health Estimation Method for Lithium-Ion Battery Modules with Series-Connected Cells , 2020, Batteries.

[5]  K. von Maydell,et al.  Optimised capacity and operating strategy for providing frequency containment reserve with batteries and power-to-heat , 2020 .

[6]  M. Dubarry,et al.  Degradation of electric vehicle lithium-ion batteries in electricity grid services , 2020 .

[7]  A. Kwade,et al.  Holistic calendar aging model parametrization concept for lifetime prediction of graphite/NMC lithium-ion cells , 2020 .

[8]  A. Jossen,et al.  Electrochemical Modeling of Linear and Nonlinear Aging of Lithium-Ion Cells , 2020 .

[9]  R. Riedel,et al.  The influence of the anode overhang effect on the capacity of lithium-ion cells – a 0D-modeling approach , 2020 .

[10]  A. Latz,et al.  Solid–Electrolyte Interphase During Battery Cycling: Theory of Growth Regimes , 2020, ChemSusChem.

[11]  Md Sazzad Hosen,et al.  Electro-aging model development of nickel-manganese-cobalt lithium-ion technology validated with light and heavy-duty real-life profiles , 2020 .

[12]  Markus Lienkamp,et al.  Accelerated Aging Characterization of Lithium-ion Cells: Using Sensitivity Analysis to Identify the Stress Factors Relevant to Cyclic Aging , 2020, Batteries.

[13]  Xuning Feng,et al.  Lithium-ion battery fast charging: A review , 2019, eTransportation.

[14]  E. Leiva,et al.  Capacity fading model for a solid electrolyte interface with surface growth , 2019, Electrochimica Acta.

[15]  Jorn M. Reniers,et al.  Review and performance comparison of mechanical-chemical degradation models for lithium-ion batteries , 2019, Journal of The Electrochemical Society.

[16]  Peter M. Attia,et al.  Electrochemical Kinetics of SEI Growth on Carbon Black: Part I. Experiments , 2019, Journal of The Electrochemical Society.

[17]  W. Bessler,et al.  End-of-Life Prediction of a Lithium-Ion Battery Cell Based on Mechanistic Aging Models of the Graphite Electrode , 2018 .

[18]  Kai Peter Birke,et al.  Quantitative validation of calendar aging models for lithium-ion batteries , 2018, Journal of Power Sources.

[19]  Dirk Uwe Sauer,et al.  Irreversible calendar aging and quantification of the reversible capacity loss caused by anode overhang , 2018, Journal of Energy Storage.

[20]  Andreas Jossen,et al.  Analysis and modeling of calendar aging of a commercial LiFePO4/graphite cell , 2018, Journal of Energy Storage.

[21]  Julia Badeda,et al.  Techno-economic evaluation of battery energy storage systems on the primary control reserve market under consideration of price trends and bidding strategies , 2018, Journal of Energy Storage.

[22]  J. Janek,et al.  Volume Changes of Graphite Anodes Revisited: A Combined Operando X-ray Diffraction and In Situ Pressure Analysis Study , 2018 .

[23]  Daniel S. Kirschen,et al.  Modeling of Lithium-Ion Battery Degradation for Cell Life Assessment , 2018, IEEE Transactions on Smart Grid.

[24]  Oleg Wasynczuk,et al.  Applicability of available Li-ion battery degradation models for system and control algorithm design , 2018 .

[25]  Andreas Jossen,et al.  Comprehensive Modeling of Temperature-Dependent Degradation Mechanisms in Lithium Iron Phosphate Batteries , 2017 .

[26]  Joris de Hoog,et al.  Combined cycling and calendar capacity fade modeling of a Nickel-Manganese-Cobalt Oxide Cell with real-life profile validation , 2017 .

[27]  D. Sauer,et al.  Systematic aging of commercial LiFePO4|Graphite cylindrical cells including a theory explaining rise of capacity during aging , 2017 .

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

[29]  Jean-Michel Vinassa,et al.  Lithium battery aging model based on Dakin's degradation approach , 2016 .

[30]  Phl Peter Notten,et al.  Degradation Mechanisms of C6/LiFePO4 Batteries: Experimental Analyses of Cycling-induced Aging , 2016 .

[31]  Valérie Sauvant-Moynot,et al.  Development of an empirical aging model for Li-ion batteries and application to assess the impact of Vehicle-to-Grid strategies on battery lifetime , 2016 .

[32]  Debasish Mohanty,et al.  The state of understanding of the lithium-ion-battery graphite solid electrolyte interphase (SEI) and its relationship to formation cycling , 2016 .

[33]  Dirk Uwe Sauer,et al.  Modeling mechanical degradation in lithium ion batteries during cycling: Solid electrolyte interphase fracture , 2015 .

[34]  Remus Teodorescu,et al.  Degradation behaviour of Lithium-ion batteries based on field measured frequency regulation mission profile , 2015, 2015 IEEE Energy Conversion Congress and Exposition (ECCE).

[35]  G. Yin,et al.  Multi-stress factor model for cycle lifetime prediction of lithium ion batteries with shallow-depth discharge , 2015 .

[36]  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 .

[37]  M. Verbrugge,et al.  Degradation of lithium ion batteries employing graphite negatives and nickel-cobalt-manganese oxide + spinel manganese oxide positives: Part 1, aging mechanisms and life estimation , 2014 .

[38]  M. Dubarry,et al.  Cell degradation in commercial LiFePO4 cells with high-power and high-energy designs , 2014 .

[39]  Dirk Uwe Sauer,et al.  A holistic aging model for Li(NiMnCo)O2 based 18650 lithium-ion batteries , 2014 .

[40]  Alan Millner,et al.  Modeling Lithium Ion battery degradation in electric vehicles , 2010, 2010 IEEE Conference on Innovative Technologies for an Efficient and Reliable Electricity Supply.

[41]  Ralph E. White,et al.  Parameter Estimation and Life Modeling of Lithium-Ion Cells , 2008 .

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

[43]  Andreas Jossen,et al.  Calendar Aging of NCA Lithium-Ion Batteries Investigated by Differential Voltage Analysis and Coulomb Tracking , 2017 .

[44]  Rutooj D. Deshpande,et al.  Modeling Solid-Electrolyte Interphase (SEI) Fracture: Coupled Mechanical/Chemical Degradation of the Lithium Ion Battery , 2017 .

[45]  Vincent Chevrier,et al.  Understanding Anomalous Behavior in Coulombic Efficiency Measurements on Li-Ion Batteries , 2015 .

[46]  Marco Roscher,et al.  Influence of the vehicle-to-grid strategy on the aging behavior of lithium battery electric vehicles , 2015 .

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