Your search keyword '"Jue Liu"' showing total 6 results

1. A Series of Ternary Metal Chloride Superionic Conductors for High-Performance All-Solid-State Lithium Batteries

Author

Jianwen Liang, Eveline Maas, Jing Luo, Xiaona Li, Ning Chen, Keegan R. Adair, Weihan Li, Junjie Li, Yongfeng Hu, Jue Liu, Li Zhang, Shangqian Zhao, Shigang Lu, Jiantao Wang, Huan Huang, Wenxuan Zhao, Steven Parnell, Ronald I. Smith, Swapna Ganapathy, Marnix Wagemaker, and Xueliang Sun

Subjects

halides, superionic conductors, Renewable Energy, Sustainability and the Environment, energy storage, solid-state electrolytes, General Materials Science, all-solid-state Li batteries

Abstract

Understanding the relationship between structure, ionic conductivity, and synthesis is the key to the development of superionic conductors. Here, a series of Li3-3xM1+xCl6 (−0.14 < x ≤ 0.5, M = Tb, Dy, Ho, Y, Er, Tm) solid electrolytes with orthorhombic and trigonal structures are reported. The orthorhombic phase of Li–M–Cl shows an approximately one order of magnitude increase in ionic conductivities when compared to their trigonal phase. Using the Li–Ho–Cl components as an example, their structures, phase transition, ionic conductivity, and electrochemical stability are studied. Molecular dynamics simulations reveal the facile diffusion in the z-direction in the orthorhombic structure, rationalizing the improved ionic conductivities. All-solid-state batteries of NMC811/Li2.73Ho1.09Cl6/In demonstrate excellent electrochemical performance at both 25 and −10 °C. As relevant to the vast number of isostructural halide electrolytes, the present structure control strategy guides the design of halide superionic conductors.

Published

2022

2. Double Paddle‐Wheel Enhanced Sodium Ion Conduction in an Antiperovskite Solid Electrolyte (Adv. Energy Mater. 7/2023)

Author

Ping‐Chun Tsai, Sunil Mair, Jeffrey Smith, David M. Halat, Po‐Hsiu Chien, Kwangnam Kim, Duhan Zhang, Yiliang Li, Liang Yin, Jue Liu, Saul H. Lapidus, Jeffrey A. Reimer, Nitash P. Balsara, Donald J. Siegel, and Yet‐Ming Chiang

Subjects

Renewable Energy, Sustainability and the Environment, General Materials Science

Published

2023

3. Probing Dopant Redistribution, Phase Propagation, and Local Chemical Changes in the Synthesis of Layered Oxide Battery Cathodes

Author

Dennis Nordlund, Cheng-Jun Sun, Jue Liu, Zhijie Yang, Feng Lin, Zhengrui Xu, Xianghui Xiao, Dong Hou, Muhammad Mominur Rahman, and Linqin Mu

Subjects

Materials science, Dopant, Renewable Energy, Sustainability and the Environment, Scattering, Doping, Oxide, Cathode, law.invention, chemistry.chemical_compound, chemistry, Oxidation state, law, Chemical physics, General Materials Science, Calcination, Redistribution (chemistry)

Abstract

Achieving the targeted control of layered oxide properties calls for more fundamental studies to mechanistically probe their evolution during their synthesis. Herein, dopant distribution, phase propagation, and local chemical changes as well as their interplay in multielement‐doped LiNiO2 materials are investigated using spectroscopic, imaging, and scattering techniques. It is shown that dopants undergo dynamic redistribution in the Ni(OH)2 host lattice at the early stage of calcination (below 300 °C). Such redistribution behavior exhibits strong dopant‐dependent characteristics, allowing for targeted surface and bulk doping control. The Ni oxidation process exhibits depth‐dependent characteristics and the most rapid Ni oxidation takes place between 300 and 700 °C. Using Ni oxidation state as the proxy for the phase transformation, the buildup of heterogenous phase propagation in the early stage of calcination is shown, especially along the radial direction of secondary particles. The radial heterogenous phase distribution gradually decreases upon completing the calcination. However, a high degree of mosaic‐like heterogeneity may still be present in the final product, departing from the perfect layered oxide. The present study offers fundamental insights into manipulating multiscale materials properties during calcination for obtaining stable, high‐energy layered oxide cathodes.

Published

2020

4. KVOPO 4 : A New High Capacity Multielectron Na‐Ion Battery Cathode

Author

Karena W. Chapman, Iek-Heng Chu, Jatinkumar Rana, Hui Zhou, Yuh-Chieh Lin, Shyue Ping Ong, Natasha A. Chernova, Louis F. J. Piper, M. Stanley Whittingham, Jue Liu, Fredrick Omenya, Hanlei Zhang, Jia Ding, and Kamila M. Wiaderek

Subjects

Battery (electricity), Materials science, Renewable Energy, Sustainability and the Environment, Inorganic chemistry, High capacity, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Cathode, 0104 chemical sciences, law.invention, law, General Materials Science, 0210 nano-technology

Published

2018

5. KVOPO4: A New High Capacity Multielectron Na-Ion Battery Cathode.

Author

Jia Ding, Yuh-Chieh Lin, Jue Liu, Rana, Jatinkumar, Hanlei Zhang, Hui Zhou, Iek-Heng Chu, Wiaderek, Kamila M., Omenya, Fredrick, Chernova, Natasha A., Chapman, Karena W., Piper, Louis F. J., Shyue Ping Ong, and Whittingham, M. Stanley

Subjects

STORAGE batteries, ENERGY density, CATHODES, OXIDATION-reduction reaction, DENSITY functional theory

Abstract

Sodium ion batteries have attracted much attention in recent years, due to the higher abundance and lower cost of sodium, as an alternative to lithium ion batteries. However, a major challenge is their lower energy density. In this work, we report a novel multi-electron cathode material, KVOPO4, for sodium ion batteries. Due to the unique polyhedral framework, the V3+ ↔ V4+ ↔ V5+ redox couple was for the first time fully activated by sodium ions in a vanadyl phosphate phase. The KVOPO4 based cathode delivered reversible multiple sodium (i.e. maximum 1.66 Na+ per formula unit) storage capability, which leads to a high specific capacity of 235 Ah kg-1. Combining an average voltage of 2.56 V vs. Na/Na+, a high practical energy density of over 600 Wh kg-1 was achieved, the highest yet reported for any sodium cathode material. The cathode exhibits a very small volume change upon cycling (1.4% for 0.64 sodium and 8.0% for 1.66 sodium ions). Density functional theory (DFT) calculations indicate that the KVOPO4 framework is a 3D ionic conductor with a reasonably, low Na+ migration energy barrier of ≈450 meV, in line with the good rate capability obtained. [ABSTRACT FROM AUTHOR]

Published

2018

6. Utilizing Environmental Friendly Iron as a Substitution Element in Spinel Structured Cathode Materials for Safer High Energy Lithium-Ion Batteries

Author

Peter G. Khalifah, Xiao-Qing Yang, Jigang Zhou, Yong-Ning Zhou, Xiqian Yu, Yijin Liu, Seong-Min Bak, Kyung-Wan Nam, Enyuan Hu, Kingo Ariyoshi, and Jue Liu

Subjects

Battery (electricity), Materials science, Thermal runaway, Renewable Energy, Sustainability and the Environment, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Lithium-ion battery, Energy storage, 0104 chemical sciences, chemistry, Chemical engineering, General Materials Science, Lithium, Thermal stability, 0210 nano-technology

Abstract

Suppressing oxygen release from lithium ion battery cathodes during heating is a critical issue for the improvement of the battery safety characteristics because oxygen can exothermically react with the flammable electrolyte and cause thermal runaway. Previous studies have shown that oxygen release can be reduced by the migration of transition metal cations from octahedral sites to tetrahedral sites during heating. Such site-preferred migration is determined by the electronic structure of cations. Taking advantage of the unique electronic structure of the environmental friendly Fe, this is selected as substitution element in a high energy density material LiNi0.5Mn1.5O4 to improve the thermal stability. The optimized LiNi0.33Mn1.33Fe0.33O4 material shows significantly improved thermal stability compared with the unsubstituted one, demonstrated by no observed oxygen release at temperatures as high as 500°C. Due to the electrochemical contribution of Fe, the high energy density feature of LiNi0.5Mn1.5O4 is well preserved.

Published

2015