Anomalous thermal conductivity in 2D silica nanocages of immobilizing noble gas atom

Yang Wang; Zhibin Gao; Xiaoying Wang; Jinping Sun; Minxuan Feng; Yuzhou Hao; Xuejie Li; Yinchang Zhao; Xiangdong Ding

doi:10.1063/5.0200462

Anomalous thermal conductivity in 2D silica nanocages of immobilizing noble gas atom

Yang Wang
, Zhibin Gao
, Xiaoying Wang
, Jinping Sun
, Minxuan Feng
, Yuzhou Hao
, Xuejie Li
, Yinchang Zhao
, Xiangdong Ding

材料科学与工程学院

Xi'an Jiaotong University
Harbin Institute of Technology at Weihai
Yantai University

科研成果: 期刊稿件 › 文章 › 同行评审

5 引用（Scopus）

摘要

Noble gas atoms such as Kr and Xe are byproducts of nuclear fission in nuclear plants. How to trap and confine these volatile even radioactive gases is particularly challenging. Recent studies have shown that they can be trapped in nanocages of ultrathin silica. Here, we exhibit with self-consistent phonon theory and four-phonon (4ph) scattering where the adsorption of noble gases results in an anomalous increase in lattice thermal conductivity (κ_L), while the presence of Cu atoms doping leads to a reduction in κ_L. We trace this behavior in host-guest 2D silica to an interplay of tensile strain, rattling phonon modes, and redistribution of electrons. We also find that 4ph scatterings play indispensable roles in κ_L of 2D silica.

源语言	英语
文章编号	122205
期刊	Applied Physics Letters
卷	124
期	12
DOI	https://doi.org/10.1063/5.0200462
出版状态	已出版 - 18 3月 2024

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abstract = "Noble gas atoms such as Kr and Xe are byproducts of nuclear fission in nuclear plants. How to trap and confine these volatile even radioactive gases is particularly challenging. Recent studies have shown that they can be trapped in nanocages of ultrathin silica. Here, we exhibit with self-consistent phonon theory and four-phonon (4ph) scattering where the adsorption of noble gases results in an anomalous increase in lattice thermal conductivity (κL), while the presence of Cu atoms doping leads to a reduction in κL. We trace this behavior in host-guest 2D silica to an interplay of tensile strain, rattling phonon modes, and redistribution of electrons. We also find that 4ph scatterings play indispensable roles in κL of 2D silica.",

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T1 - Anomalous thermal conductivity in 2D silica nanocages of immobilizing noble gas atom

AU - Wang, Yang

AU - Gao, Zhibin

AU - Wang, Xiaoying

AU - Sun, Jinping

AU - Feng, Minxuan

AU - Hao, Yuzhou

AU - Li, Xuejie

AU - Zhao, Yinchang

AU - Ding, Xiangdong

PY - 2024/3/18

Y1 - 2024/3/18

N2 - Noble gas atoms such as Kr and Xe are byproducts of nuclear fission in nuclear plants. How to trap and confine these volatile even radioactive gases is particularly challenging. Recent studies have shown that they can be trapped in nanocages of ultrathin silica. Here, we exhibit with self-consistent phonon theory and four-phonon (4ph) scattering where the adsorption of noble gases results in an anomalous increase in lattice thermal conductivity (κL), while the presence of Cu atoms doping leads to a reduction in κL. We trace this behavior in host-guest 2D silica to an interplay of tensile strain, rattling phonon modes, and redistribution of electrons. We also find that 4ph scatterings play indispensable roles in κL of 2D silica.

AB - Noble gas atoms such as Kr and Xe are byproducts of nuclear fission in nuclear plants. How to trap and confine these volatile even radioactive gases is particularly challenging. Recent studies have shown that they can be trapped in nanocages of ultrathin silica. Here, we exhibit with self-consistent phonon theory and four-phonon (4ph) scattering where the adsorption of noble gases results in an anomalous increase in lattice thermal conductivity (κL), while the presence of Cu atoms doping leads to a reduction in κL. We trace this behavior in host-guest 2D silica to an interplay of tensile strain, rattling phonon modes, and redistribution of electrons. We also find that 4ph scatterings play indispensable roles in κL of 2D silica.

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SN - 0003-6951

VL - 124

JO - Applied Physics Letters

JF - Applied Physics Letters

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Anomalous thermal conductivity in 2D silica nanocages of immobilizing noble gas atom

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