Oxygen-Redox Activity in Non-Lithium-Excess Tungsten-Doped LiNiO2

[1]  Liquan Chen,et al.  Anionic redox reaction and structural evolution of Ni-rich layered oxide cathode material , 2022, Nano Energy.

[2]  Zonghai Chen,et al.  Origin and regulation of oxygen redox instability in high-voltage battery cathodes , 2022, Nature Energy.

[3]  Xiangfeng Liu,et al.  Stabilizing the Anionic Redox in 4.6 V LiCoO2 Cathode through Adjusting Oxygen Magnetic Moment , 2022, Advanced Functional Materials.

[4]  K. An,et al.  Improving the oxygen redox reversibility of Li-rich battery cathode materials via Coulombic repulsive interactions strategy , 2022, Nature communications.

[5]  M. Whittingham,et al.  Pushing the limit of 3d transition metal-based layered oxides that use both cation and anion redox for energy storage , 2022, Nature Reviews Materials.

[6]  M. Whittingham,et al.  Oxygen Loss in Layered Oxide Cathodes for Li-Ion Batteries: Mechanisms, Effects, and Mitigation. , 2022, Chemical reviews.

[7]  Chongyin Yang,et al.  Mechanism of Action of the Tungsten Dopant in LiNiO2 Positive Electrode Materials , 2021, Advanced Energy Materials.

[8]  Chongyin Yang,et al.  Tungsten Infused Grain Boundaries Enabling Universal Performance Enhancement of Co-Free Ni-Rich Cathode Materials , 2021, Journal of The Electrochemical Society.

[9]  P. Notten,et al.  A Review of Degradation Mechanisms and Recent Achievements for Ni‐Rich Cathode‐Based Li‐Ion Batteries , 2021, Advanced Energy Materials.

[10]  Yizhou Zhu,et al.  Elucidating and Mitigating High‐Voltage Degradation Cascades in Cobalt‐Free LiNiO2 Lithium‐Ion Battery Cathodes , 2021, Advanced materials.

[11]  H. Gasteiger,et al.  The LiNiO2 Cathode Active Material: A Comprehensive Study of Calcination Conditions and their Correlation with Physicochemical Properties. Part I. Structural Chemistry , 2021, Journal of The Electrochemical Society.

[12]  N. Fleck,et al.  Perspectives for next generation lithium-ion battery cathode materials , 2021, APL Materials.

[13]  P. Chien,et al.  New Insights into Structural Evolution of LiNiO 2 Revealed by Operando Neutron Diffraction , 2021, Batteries & Supercaps.

[14]  Y. Orikasa,et al.  Tomographic reconstruction of oxygen orbitals in lithium-rich battery materials , 2021, Nature.

[15]  P. Bruce,et al.  Covalency does not suppress O2 formation in 4d and 5d Li-rich O-redox cathodes , 2021, Nature Communications.

[16]  P. Bruce,et al.  Bulk O2 formation and Mg displacement explain O-redox in Na0.67Mn0.72Mg0.28O2 , 2021 .

[17]  Y. Meng,et al.  Nanostructure Transformation as a Signature of Oxygen Redox in Li-Rich 3d and 4d Cathodes. , 2021, Journal of the American Chemical Society.

[18]  H. Xin,et al.  Atomic-Scale Observation of O1 Faulted Phase-Induced Deactivation of LiNiO2 at High Voltage. , 2021, Nano letters.

[19]  H. Xin,et al.  Resolving atomic-scale phase transformation and oxygen loss mechanism in ultrahigh-nickel layered cathodes for cobalt-free lithium-ion batteries , 2021, Matter.

[20]  Liquan Chen,et al.  Oxygen-redox reactions in LiCoO2 cathode without O–O bonding during charge-discharge , 2021 .

[21]  Yong‐Mook Kang,et al.  Utilizing Oxygen Redox in Layered Cathode Materials from Multiscale Perspective , 2021, Advanced Energy Materials.

[22]  P. Bruce,et al.  The role of O2 in O-redox cathodes for Li-ion batteries , 2021, Nature Energy.

[23]  M. Whittingham,et al.  Whither Mn Oxidation in Mn-Rich Alkali-Excess Cathodes? , 2021, ACS Energy Letters.

[24]  Chaodi Xu,et al.  Phase Behavior during Electrochemical Cycling of Ni‐Rich Cathode Materials for Li‐Ion Batteries , 2020, Advanced Energy Materials.

[25]  P. Bruce,et al.  Redox Chemistry and the Role of Trapped Molecular O2 in Li-Rich Disordered Rocksalt Oxyfluoride Cathodes , 2020, Journal of the American Chemical Society.

[26]  J. Tarascon,et al.  Elucidation of Active Oxygen Sites upon Delithiation of Li3IrO4 , 2020, ECS Meeting Abstracts.

[27]  Joseph K. Papp,et al.  Correlating the phase evolution and anionic redox in Co-Free Ni-Rich layered oxide cathodes , 2020 .

[28]  J. Janek,et al.  From LiNiO2 to Li2NiO3: Synthesis, Structures and Electrochemical Mechanisms in Li-Rich Nickel Oxides , 2020, Chemistry of Materials.

[29]  P. Bruce,et al.  First-cycle voltage hysteresis in Li-rich 3d cathodes associated with molecular O2 trapped in the bulk , 2020, Nature Energy.

[30]  Chaodi Xu,et al.  Bulk fatigue induced by surface reconstruction in layered Ni-rich cathodes for Li-ion batteries , 2020, Nature Materials.

[31]  William E. Gent,et al.  Design Rules for High-Valent Redox in Intercalation Electrodes , 2020 .

[32]  Yong‐Mook Kang,et al.  Reversible Anionic Redox Activities in Conventional LiNi1/3Co1/3Mn1/3O2 Cathodes. , 2020, Angewandte Chemie.

[33]  F. Pan,et al.  Dissociate lattice oxygen redox reactions from capacity and voltage drops of battery electrodes , 2020, Science Advances.

[34]  M. Whittingham,et al.  Quantifying the Capacity Contributions during Activation of Li2MnO3 , 2020 .

[35]  Liquan Chen,et al.  Local structure adaptability through multi cations for oxygen redox accommodation in Li-Rich layered oxides , 2020, Energy Storage Materials.

[36]  F. Pan,et al.  Full Energy Range Resonant Inelastic X-ray Scattering of O2 and CO2: Direct Comparison with Oxygen Redox State in Batteries. , 2019, The journal of physical chemistry letters.

[37]  Evan M. Erickson,et al.  Thermodynamics of Antisite Defects in Layered NMC Cathodes: Systematic Insights from High-Precision Powder Diffraction Analyses , 2019, Chemistry of Materials.

[38]  P. Bruce,et al.  Superstructure control of first-cycle voltage hysteresis in oxygen-redox cathodes , 2019, Nature.

[39]  Joseph K. Papp,et al.  Unraveling the Cationic and Anionic Redox Reactions in a Conventional Layered Oxide Cathode , 2019, ACS Energy Letters.

[40]  A. Van der Ven,et al.  Manganese oxidation as the origin of the anomalous capacity of Mn-containing Li-excess cathode materials , 2019, Nature Energy.

[41]  Liquan Chen,et al.  Trace doping of multiple elements enables stable battery cycling of LiCoO2 at 4.6 V , 2019, Nature Energy.

[42]  Tongchao Liu,et al.  Ni/Li Disordering in Layered Transition Metal Oxide: Electrochemical Impact, Origin, and Control. , 2019, Accounts of chemical research.

[43]  J. Janek,et al.  Phase Transformation Behavior and Stability of LiNiO2 Cathode Material for Li-Ion Batteries Obtained from In Situ Gas Analysis and Operando X-Ray Diffraction. , 2019, ChemSusChem.

[44]  M. Ben Yahia,et al.  Unified picture of anionic redox in Li/Na-ion batteries , 2019, Nature Materials.

[45]  William E. Gent,et al.  Fingerprint Oxygen Redox Reactions in Batteries through High-Efficiency Mapping of Resonant Inelastic X-ray Scattering , 2018, Condensed Matter.

[46]  William E. Gent,et al.  High Reversibility of Lattice Oxygen Redox Quantified by Direct Bulk Probes of Both Anionic and Cationic Redox Reactions , 2018, Joule.

[47]  Devon R. Mortensen,et al.  An improved laboratory-based x-ray absorption fine structure and x-ray emission spectrometer for analytical applications in materials chemistry research. , 2018, The Review of scientific instruments.

[48]  J. Janek,et al.  There and Back Again-The Journey of LiNiO2 as a Cathode Active Material. , 2019, Angewandte Chemie.

[49]  Wanli Yang,et al.  Anionic and cationic redox and interfaces in batteries: Advances from soft X-ray absorption spectroscopy to resonant inelastic scattering , 2018, Journal of Power Sources.

[50]  Jean-Marie Tarascon,et al.  Fundamental understanding and practical challenges of anionic redox activity in Li-ion batteries , 2018 .

[51]  Jun Lu,et al.  Elucidating anionic oxygen activity in lithium-rich layered oxides , 2018, Nature Communications.

[52]  Min-jae Choi,et al.  Cation Ordering of Zr-Doped LiNiO2 Cathode for Lithium-Ion Batteries , 2018 .

[53]  P. Bruce,et al.  Oxygen redox chemistry without excess alkali-metal ions in Na2/3[Mg0.28Mn0.72]O2. , 2018, Nature chemistry.

[54]  J. Dahn,et al.  Updating the Structure and Electrochemistry of LixNiO2 for 0 ≤ x ≤ 1 , 2018 .

[55]  William E. Gent,et al.  Coupling between oxygen redox and cation migration explains unusual electrochemistry in lithium-rich layered oxides , 2017, Nature Communications.

[56]  A. Yamada,et al.  Molecular Orbital Principles of Oxygen-Redox Battery Electrodes. , 2017, ACS applied materials & interfaces.

[57]  M. Whittingham,et al.  Narrowing the Gap between Theoretical and Practical Capacities in Li‐Ion Layered Oxide Cathode Materials , 2017 .

[58]  C. Yoon,et al.  Structural Stability of LiNiO2 Cycled above 4.2 V , 2017 .

[59]  Zahid Hussain,et al.  High-efficiency in situ resonant inelastic x-ray scattering (iRIXS) endstation at the Advanced Light Source. , 2017, The Review of scientific instruments.

[60]  Xiao‐Qing Yang,et al.  Understanding the Degradation Mechanism of Lithium Nickel Oxide Cathodes for Li-Ion Batteries. , 2016, ACS applied materials & interfaces.

[61]  P. Bruce,et al.  Anion Redox Chemistry in the Cobalt Free 3d Transition Metal Oxide Intercalation Electrode Li[Li0.2Ni0.2Mn0.6]O2. , 2016, Journal of the American Chemical Society.

[62]  Rahul Malik,et al.  The structural and chemical origin of the oxygen redox activity in layered and cation-disordered Li-excess cathode materials. , 2016, Nature chemistry.

[63]  K. Edström,et al.  Charge-compensation in 3d-transition-metal-oxide intercalation cathodes through the generation of localized electron holes on oxygen. , 2016, Nature chemistry.

[64]  Jung-Hyun Kim,et al.  Direct Experimental Probe of the Ni(II)/Ni(III)/Ni(IV) Redox Evolution in LiNi0.5Mn1.5O4 Electrodes , 2015 .

[65]  Yoyo Hinuma,et al.  Effect of High Voltage on the Structure and Electrochemistry of LiNi0.5Mn0.5O2: A Joint Experimental and Theoretical Study , 2006 .

[66]  G. Ceder,et al.  In-Situ X-ray Absorption Spectroscopic Study on Variation of Electronic Transitions and Local Structure of LiNi1/3Co1/3Mn1/3O2 Cathode Material during Electrochemical Cycling , 2005 .

[67]  I. Swainson,et al.  Investigation of possible superstructure and cation disorder in the lithium battery cathode material LiMn1/3Ni1/3Co1/3O2 using neutron and anomalous dispersion powder diffraction , 2005 .

[68]  John T. Vaughey,et al.  The significance of the Li2MnO3 component in ‘composite’ xLi2MnO3 · (1 − x)LiMn0.5Ni0.5O2 electrodes , 2004 .

[69]  K. Takei,et al.  Structural and Thermal Characteristics of Nickel Dioxide Derived from LiNiO2 , 2002 .

[70]  C. Delmas,et al.  Structural characterisation of the highly deintercalatedLixNi1.02O2 phases (with x ≤ 0.30) , 2001 .

[71]  Xiao‐Qing Yang,et al.  In Situ X‐Ray Absorption Spectroscopy Study of Li ( 1 − z ) Ni ( 1 + z ) O 2 ( z ≤ 0.02 ) Cathode Material , 2000 .

[72]  J. Tarascon,et al.  In Situ Structural and Electrochemical Study of Ni1-xCoxO2 Metastable Oxides Prepared by Soft Chemistry , 1999 .

[73]  W. O'grady,et al.  In Situ X‐Ray Absorption Near‐Edge Structure Evidence for Quadrivalent Nickel in Nickel Battery Electrodes , 1996 .

[74]  C. Delmas,et al.  Optimization of the Composition of the Li1 − z Ni1 + z O 2 Electrode Materials: Structural, Magnetic, and Electrochemical Studies , 1996 .

[75]  P. Hagenmuller,et al.  Structural classification and properties of the layered oxides , 1980 .

[76]  A. Weber,et al.  The Raman spectrum of gaseous oxygen , 1960 .