Pressure-Induced Li+ Migration and Second-Order Phase Transition in LiNbO3: Yb/Er Nanocrystals Revealed by Variable-Pressure Optical and Impedance Studies

Pressure-Induced Li+ Migration and Second-Order Phase Transition in LiNbO3: Yb/Er Nanocrystals Revealed by Variable-Pressure Optical and Impedance Studies

Pressure is a key thermodynamic parameter for modulating the crystal lattice and physical properties of ionic conductors. It is essential to probe the pressure-induced ion migration and the resulting structure variation in ionic conductors; yet, it remains a challenge to date. Herein, we report an i...

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Veröffentlicht in:Journal of physical chemistry. C 2024-01, Vol.128 (1), p.613-622
Hauptverfasser: Tao, Zhengren, Cheng, Fangrui, Wang, Yinghan, Wang, Yonggang, Zhang, Jiang, Tang, Lingyun, Ye, Shi
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container_issue 1
container_start_page 613
container_title Journal of physical chemistry. C
container_volume 128
creator Tao, Zhengren
Cheng, Fangrui
Wang, Yinghan
Wang, Yonggang
Zhang, Jiang
Tang, Lingyun
Ye, Shi
description Pressure is a key thermodynamic parameter for modulating the crystal lattice and physical properties of ionic conductors. It is essential to probe the pressure-induced ion migration and the resulting structure variation in ionic conductors; yet, it remains a challenge to date. Herein, we report an in situ study on the ionic conductor of LiNbO3: Yb/Er nanocrystals were characterized with variable-pressure optical and impedance spectroscopy. It is found that LiNbO3: Yb/Er nanocrystals undergo a second-order phase transition near 6 GPa, which is triggered by Li+ migration. The surge of impedance upon elevated pressure may be dominated by the fracture of the symbiotic catenuliform nanocrystals and the rearrangement of the nanocrystals. The diffusion coefficient of Li+ should be combinedly influenced by the dynamic interface among nanocrystals, phase transition, and the newly formed defects. The study not only presents an alternative optical technique to probe the pressure-induced ion migration but also gives a perspective on the influence of crystal morphology on pressure-induced Li+ ion diffusion in ionic conductors.
doi_str_mv 10.1021/acs.jpcc.3c07058
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title Pressure-Induced Li+ Migration and Second-Order Phase Transition in LiNbO3: Yb/Er Nanocrystals Revealed by Variable-Pressure Optical and Impedance Studies
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