Computational Design and Preparation of Cation‐Disordered Oxides for High‐Energy‐Density Li‐Ion Batteries

Urban, Alexander; Matts, Ian L; Abdellahi, Aziz; Ceder, Gerbrand

doi:10.1002/aenm.201600488

Cited by 116 publications

(110 citation statements)

References 74 publications

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“…The trends in disordering temperature are in line with previous DFT results on the stoichiometric LMOs [32,39] and with the experimental observation that the titanium compound forms in a disordered state upon solid-state synthesis. Since the high temperature miscibility gap is between two compositions of the disordered rock salt phase, above the eutectic point this phase boundary is identical between the equilibrium and disordered phase diagrams.…”

Section: Resultssupporting

confidence: 90%

Fluorination of Lithium‐Excess Transition Metal Oxide Cathode Materials

Richards

Dacek

Kitchaev

et al. 2017

Advanced Energy Materials

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do not require lithium ions to pass directly adjacent to a transition metal (0-TM channels). [3] These pathways are present only at high lithium concentrations, with the percolation threshold a function of the crystal structure and degree of cation disorder. The Li-excess requires high-valent metals for charge compensation and typically reduces the active TM content of the compound. Thus, a key aspect of the design and optimization of this class of cathode materials is the maximization of transition metal redox capacity, while maintaining the Li-excess level greater than the percolation threshold to ensure acceptable rate capability.Early work in disordered lithium-excess rock salt materials focused on the vanadium systems Li 3 V 2 O 5[4] and Li 2−x VO 3 , [5] where the large lithium concentration is charge compensated by the high-valence states of vanadium. More recently, a number of studies have reported lithiumexcess compositions of a range of lithium transition metal oxide (LMO) cathodes through the substitution of a high-valent cation on the metal site, forming a solid solution between LiMO 2 and Li 2 MoO 3 , [1] Li 4 MoO 5 , [6][7][8] Li 3 NbO 4 , [9][10][11] Li 3 SbO 4 , [12] or Li 2 TiO 3 . [13,14] The disadvantages of this strategy for introducing lithium excess are the high atomic mass of the high-valent metal substitutions and their redox inactivity at useful voltages, both of which reduce the theoretical TM capacity of this class of materials. For example, the composition Li 1.1 Co 0.833 Mo 0.066 O 2 , which is at the threshold for 0-TM percolation in the disordered rock salt structure, decreases the theoretical gravimetric TMcapacity from 275 mA h g −1 for pristine LiCoO 2 to 235 mA h g −1 for the Co 3+/4+ redox couple. While in some cases, reversible oxygen redox can add extra capacity, [15] too much oxygen redox is likely to lead to oxygen loss at the surface, accompanied by capacity loss and/or impedance growth. [16] An alternative strategy to ensure charge balance at a lithiumexcess composition is the substitution of a lower valence halide for the oxygen anion. Fluorine substitution to the same lithium-excess level as in the previously considered Mo-substituted compound results in the composition Li 1.1 Co 0.9 O 1.8 F 0.2 , which has a theoretical TM-capacity of 260 mA h g −1 , significantly higher than when Li excess is compensated by a high-valent metal as in Li 1.1 Co 0.833 Mo 0.066 O 2 . In early demonstrations of this strategy, Chen et al. have reported high initial capacity in the Li 2 VO 2 F [17] and Li 2 CrO 2 F [18] disordered rock salt compounds, Fluorination of Li-ion cathode materials is of significant interest as it is claimed to lead to significant improvements in long-term reversible capacity. However, the mechanism by which LiF incorporates and improves performance remains uncertain. Indeed, recent evidence suggests that fluorine is often present as a coating layer rather than incorporated into the bulk of the material. In this work, first-principles calculations are used to inves...

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Section: Resultssupporting

confidence: 90%

Fluorination of Lithium‐Excess Transition Metal Oxide Cathode Materials

Richards

Dacek

Kitchaev

et al. 2017

Advanced Energy Materials

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135

204

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“…[33] Changes during discharge, charge and upon extended cycling could thus contribute to deviations. Liion diffusion, which could change upon cycling due to disorder [5,34] may increase the kinetic polarization. Besides these reversible changes in LiVO 2 , irreversible changes could also occur during cycling: e. g., vanadium dissolution and electrolyte degradation.…”

Section: Resultsmentioning

confidence: 99%

Reversible Delithiation of Disordered Rock Salt LiVO₂

et al. 2018

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A rigid crystal lattice, in which cations occupy specific positions, is generally regarded as a critical requirement to enable Li+ diffusion in the bulk of conventional cathode materials, whereas disorder is generally considered as detrimental. Herein, we demonstrate that facile and reversible insertion and extraction of Li+ is possible with LiVO2, a new cation‐disordered rock salt compound (space group: Fmtrue3‾ m), which is, to the best of our knowledge, described for the first time. This new polymorph of LiVO2 is synthesized by mechanical alloying. Rietveld refinements of the X‐ray diffractions patterns and SAED (selected‐area electron diffraction) patterns attested the formation of the disordered LiVO2 rock salt phase. Galvanostatic cycling experiments were employed to characterize the electrochemical performance of the material, demonstrating that reversible cycling over 100 cycles with a discharge capacity around 100 mAh g−1 is possible.

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“…Now, real‐time collaboration of theorists and experimentalists is commonplace in efforts to understand the mechanism of battery reactions. Density functional theory (DFT) provides insight into essential battery properties such as average voltages, activation energy of ion‐diffusion, thermodynamic stability, spatial distribution of electrons, lattice vibrations, elastic properties, and spectroscopic assignments . These features are determined from static calculations through total energy and/or Kohn‐Sham orbitals with moderate calculation costs.…”

Section: Introductionmentioning

confidence: 99%

Combined Theoretical and Experimental Studies of Sodium Battery Materials

Watanabe

Chung

Nishimura

et al. 2019

The Chemical Record

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Owing to developments in theoretical chemistry and computer power, the combination of calculations and experiments is now standard practice in understanding and developing new materials for battery systems. Here, we briefly review our recent combined studies based on density functional theory and molecular dynamics calculations for electrode and electrolyte materials for sodium‐ion batteries. These findings represent case studies of successful combinations of experimental and theoretical methods.

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Computational Design and Preparation of Cation‐Disordered Oxides for High‐Energy‐Density Li‐Ion Batteries

Cited by 116 publications

References 74 publications

Fluorination of Lithium‐Excess Transition Metal Oxide Cathode Materials

Fluorination of Lithium‐Excess Transition Metal Oxide Cathode Materials

Reversible Delithiation of Disordered Rock Salt LiVO₂

Combined Theoretical and Experimental Studies of Sodium Battery Materials

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Computational Design and Preparation of Cation‐Disordered Oxides for High‐Energy‐Density Li‐Ion Batteries

Cited by 116 publications

References 74 publications

Fluorination of Lithium‐Excess Transition Metal Oxide Cathode Materials

Fluorination of Lithium‐Excess Transition Metal Oxide Cathode Materials

Reversible Delithiation of Disordered Rock Salt LiVO2

Combined Theoretical and Experimental Studies of Sodium Battery Materials

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Reversible Delithiation of Disordered Rock Salt LiVO₂