Kwang Nam Kim scite author profile

Li 2 OHCl is an exemplar of the antiperovskite family of ionic conductors, for which high ionic conductivities have been reported, but in which the atomic-level mechanism of ion migration is unclear. The stable phase is both crystallographically defective and disordered, having ∼1/3 of the Li sites vacant, while the presence of the OH − anion introduces the possibility of rotational disorder that may be coupled to cation migration. Here, complementary experimental and computational methods are applied to understand the relationship between the crystal chemistry and ionic conductivity in Li 2 OHCl, which undergoes an orthorhombic to cubic phase transition near 311 K (≈38 °C) and coincides with the more than a factor of 10 change in ionic conductivity (from 1.2 × 10 −5 mS/cm at 37 °C to 1.4 × 10 −3 mS/cm at 39 °C). X-ray and neutron experiments conducted over the temperature range 20−200 °C, including diffraction, quasi-elastic neutron scattering (QENS), the maximum entropy method (MEM) analysis, and ab initio molecular dynamics (AIMD) simulations, together show conclusively that the high lithium ion conductivity of cubic Li 2 OHCl is correlated to "paddlewheel" rotation of the dynamic OH − anion. The present results suggest that in antiperovskites and derivative structures a high cation vacancy concentration combined with the presence of disordered molecular anions can lead to high cation mobility.

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Material Design Strategy for Halide Solid Electrolytes Li₃MX₆ (X = Cl, Br, and I) for All-Solid-State High-Voltage Li-Ion Batteries

Kim

Park

Jung

et al. 2021

Chem. Mater.

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Although several solid electrolyte (SE) candidates have been explored, achieving the necessary combination of performance, stability, and processability has been challenging. Recently, several lithium ternary halides have attracted increasing attention for SEs because of their favorable combination of high ionic conductivity and wide electrochemical window. This study aims to provide a material design strategy for lithium halides Li3MX6 (X = Cl, Br, and I) for high-voltage all-solid-state Li-ion batteries, achieved by the systematic investigation of crystal structures, phase and electrochemical stabilities, electronic and mechanical properties, and ionic conductivities. Calculation results reveal that the electronegativity difference between M and X affects structural properties and stabilities. Weak Coulomb interactions in Li3MX6 result in the preference of the monoclinic phase, and the oxidation potential and chemical stability against the cathode materials of Li3MX6 increase for relatively small X. Chlorides exhibit the highest oxidation potential (∼4.3 V) among Li3MX6, suggesting that chlorides are appropriate SEs for high-voltage cathodes. The band gap and elastic moduli increase for relatively small X, suggesting the relatively low electronic conductivity and elastic deformability of chlorides. Chlorides with transition metals typically exhibit trigonal phases, a wider electrochemical stability window, a larger band gap, and higher elastic moduli compared to other types of halides. Additionally, chloride Li3MCl6 is expected to have relatively high ionic conductivities with the aliovalent substitution of M3+ to Zr4+ and the anion mixing of Cl with Br. The findings of this study will provide fundamental guidelines for the development of lithium halide SEs for high-voltage all-solid-state Li-ion batteries.

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Lattice Boltzmann simulation of liquid water transport in microporous and gas diffusion layers of polymer electrolyte membrane fuel cells

Kim

Kang

Lee

et al. 2015

Journal of Power Sources

124

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Kwang Nam Kim

Correlating lattice distortions, ion migration barriers, and stability in solid electrolytes

Dynamics of Hydroxyl Anions Promotes Lithium Ion Conduction in Antiperovskite Li₂OHCl

Material Design Strategy for Halide Solid Electrolytes Li₃MX₆ (X = Cl, Br, and I) for All-Solid-State High-Voltage Li-Ion Batteries

Lattice Boltzmann simulation of liquid water transport in microporous and gas diffusion layers of polymer electrolyte membrane fuel cells

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Kwang Nam Kim

Correlating lattice distortions, ion migration barriers, and stability in solid electrolytes

Dynamics of Hydroxyl Anions Promotes Lithium Ion Conduction in Antiperovskite Li2OHCl

Material Design Strategy for Halide Solid Electrolytes Li3MX6 (X = Cl, Br, and I) for All-Solid-State High-Voltage Li-Ion Batteries

Lattice Boltzmann simulation of liquid water transport in microporous and gas diffusion layers of polymer electrolyte membrane fuel cells

Contact Info

Product

Resources

About

Dynamics of Hydroxyl Anions Promotes Lithium Ion Conduction in Antiperovskite Li₂OHCl

Material Design Strategy for Halide Solid Electrolytes Li₃MX₆ (X = Cl, Br, and I) for All-Solid-State High-Voltage Li-Ion Batteries