Related references
Note: Only part of the references are listed.Thermal runaway modeling of large format high-nickel/silicon-graphite lithium-ion batteries based on reaction sequence and kinetics
Yu Wang et al.
APPLIED ENERGY (2022)
The effect of cell geometry and trigger method on the risks associated with thermal runaway of lithium-ion batteries
William Q. Walker et al.
JOURNAL OF POWER SOURCES (2022)
Heat transfer effects on accelerating rate calorimetry of the thermal runaway of Lithium-ion batteries
Xuanze He et al.
PROCESS SAFETY AND ENVIRONMENTAL PROTECTION (2022)
Analysis on Thermal Runaway Behavior of Prismatic Lithium-Ion Batteries with Autoclave Calorimetry
S. Hoelle et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2021)
A Review of Battery Fires in Electric Vehicles
Peiyi Sun et al.
FIRE TECHNOLOGY (2020)
Improving the Thermal Stability of NMC 622 Li-Ion Battery Cathodes through Doping During Coprecipitation
Albert L. Lipson et al.
ACS APPLIED MATERIALS & INTERFACES (2020)
The critical characteristics and transition process of lithium-ion battery thermal runaway
Peifeng Huang et al.
ENERGY (2020)
Comparing Different Thermal Runaway Triggers for Two Automotive Lithium-Ion Battery Cell Types
C. Essl et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2020)
Analysis of the Effect of Thermal Runaway Initiation Conditions on the Severity of Thermal Runaway-Numerical Simulation and Machine Learning Study
Akos Kriston et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2020)
Modelling and experiments to identify high-risk failure scenarios for testing the safety of lithium-ion cells
Donal P. Finegan et al.
JOURNAL OF POWER SOURCES (2019)
Investigating the thermal runaway mechanisms of lithium-ion batteries based on thermal analysis database
Xuning Feng et al.
APPLIED ENERGY (2019)
Quantification and simulation of thermal decomposition reactions of Li-ion battery materials by simultaneous thermal analysis coupled with gas analysis
Akos Kriston et al.
JOURNAL OF POWER SOURCES (2019)
Decoupling of heat generated from ejected and non-ejected contents of 18650-format lithium-ion cells using statistical methods
William Q. Walker et al.
JOURNAL OF POWER SOURCES (2019)
Review-Understanding the Thermal Runaway Behavior of Li-Ion Batteries through Experimental Techniques
Puneet Jindal et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2019)
Horizons for Li-Ion Batteries Relevant to Electro-Mobility: High-Specific-Energy Cathodes and Chemically Active Separators
Francis Amalraj Susai et al.
ADVANCED MATERIALS (2018)
Model-based thermal runaway prediction of lithium-ion batteries from kinetics analysis of cell components
Dongsheng Ren et al.
APPLIED ENERGY (2018)
The reactivity of charged positive Li1-n[NixMnyCoz]O-2 electrodes with electrolyte at elevated temperatures using accelerating rate calorimetry
Que Huang et al.
JOURNAL OF POWER SOURCES (2018)
Comparative study of Sn-doped Li[Ni0.6Mn0.2Co0.2-xSnx]O-2 cathode active materials (x=0-0.5) for lithium ion batteries regarding electrochemical performance and structural stability
M. Eilers-Rethwisch et al.
JOURNAL OF POWER SOURCES (2018)
Temperature Dependence of Oxygen Release from LiNi0.6Mn0.2Co0.2O2 (NMC622) Cathode Materials for Li-Ion Batteries
Roland Jung et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2018)
Thermal Runaway of Lithium-Ion Batteries without Internal Short Circuit
Xiang Liu et al.
JOULE (2018)
Thermal runaway of large automotive Li-ion batteries
Andrey W. Golubkov et al.
RSC ADVANCES (2018)
Thermal runaway mechanism of lithium ion battery for electric vehicles: A review
Xuning Feng et al.
ENERGY STORAGE MATERIALS (2018)
The Development and Future of Lithium Ion Batteries
George E. Blomgren
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2017)
Rationalizing thermal reactions of C6Lix negative electrode with nonaqueous electrolyte
Kazuhiko Mukai et al.
JOURNAL OF POWER SOURCES (2017)
Roles of positive or negative electrodes in the thermal runaway of lithium-ion batteries: Accelerating rate calorimetry analyses with an all-inclusive microcell
Takao Inoue et al.
ELECTROCHEMISTRY COMMUNICATIONS (2017)
Are All-Solid-State Lithium-Ion Batteries Really Safe?-Verification by Differential Scanning Calorimetry with an All-Inclusive Microcell
Takao Inoue et al.
ACS APPLIED MATERIALS & INTERFACES (2017)
Graphite electrode thermal behavior and solid electrolyte interphase investigations: Role of state-of-the-art binders, carbonate additives and lithium bis(fluorosulfonyl)imide salt
Coralie Forestier et al.
JOURNAL OF POWER SOURCES (2016)
A lumped model of venting during thermal runaway in a cylindrical Lithium Cobalt Oxide lithium-ion cell
Paul T. Coman et al.
JOURNAL OF POWER SOURCES (2016)
Characterization on the exothermic behaviors of cathode materials reacted with ethylene carbonate in lithium-ion battery studied by differential scanning calorimeter (DSC)
Yih-Shing Duh et al.
THERMOCHIMICA ACTA (2016)
In-operando high-speed tomography of lithium-ion batteries during thermal runaway
Donal P. Finegan et al.
NATURE COMMUNICATIONS (2015)
Thermal runaway of commercial 18650 Li-ion batteries with LFP and NCA cathodes - impact of state of charge and overcharge
Andrey W. Golubkov et al.
RSC ADVANCES (2015)
Structural Changes and Thermal Stability of Charged LiNixMnyCozO2 Cathode Materials Studied by Combined In Situ Time-Resolved XRD and Mass Spectroscopy
Seong-Min Bak et al.
ACS APPLIED MATERIALS & INTERFACES (2014)
Thermal runaway features of large format prismatic lithium ion battery using extended volume accelerating rate calorimetry
Xuning Feng et al.
JOURNAL OF POWER SOURCES (2014)
Thermal runaway caused fire and explosion of lithium ion battery
Qingsong Wang et al.
JOURNAL OF POWER SOURCES (2012)
Multi-scale study of thermal stability of lithiated graphite
Zonghai Chen et al.
ENERGY & ENVIRONMENTAL SCIENCE (2011)
A Critical Review of Thermal Issues in Lithium-Ion Batteries
Todd M. Bandhauer et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2011)
A combustion chemistry analysis of carbonate solvents used in Li-ion batteries
Stephen J. Harris et al.
JOURNAL OF POWER SOURCES (2009)
Thermal reactions of lithiated graphite anode in LiPF6-based electrolyte
Nam-Soon Choi et al.
THERMOCHIMICA ACTA (2008)
Thermalgravimetry-mass spectrometry studies on the thermal stability of graphite anodes with electrolyte in lithium-ion battery
I Watanabe et al.
JOURNAL OF POWER SOURCES (2006)
Thermal behavior of lithiated graphite with electrolyte in lithium-ion batteries
QS Wang et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2006)
Thermal stability of LiPF6/EC+DEC electrolyte with charged electrodes for lithium ion batteries
QS Wang et al.
THERMOCHIMICA ACTA (2005)
Investigations of the exothermic reactions of natural graphite anode for Li-ion batteries during thermal runaway
H Yang et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2005)
Thermal decomposition of LiPF6-based electrolytes for lithium-ion batteries
CL Campion et al.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY (2005)
DSC investigation of exothermic reactions occurring at elevated temperatures in lithium-ion anodes containing PVDF-based binders
EP Roth et al.
JOURNAL OF POWER SOURCES (2004)
Abuse behavior of high-power, lithium-ion cells
R Spotnitz et al.
JOURNAL OF POWER SOURCES (2003)
Thermal stability of LiPF6-EC:EMC electrolyte for lithium ion batteries
GG Botte et al.
JOURNAL OF POWER SOURCES (2001)
Share Paper
