Kirigami-Inspired Thermal Regulator

Hongyi Ouyang; Yuanqing Gu; Zhibin Gao; Lei Hu; Zhen Zhang; Jie Ren; Baowen Li; Jun Sun; Yan Chen; Xiangdong Ding

doi:10.1103/PhysRevApplied.19.L011001

Kirigami-Inspired Thermal Regulator

Hongyi Ouyang
, Yuanqing Gu
, Zhibin Gao
, Lei Hu
, Zhen Zhang
, Jie Ren
, Baowen Li
, Jun Sun
, Yan Chen
, Xiangdong Ding

School of Materials Science and Engineering

Xi'an Jiaotong University
Tianjin University
Tongji University
Southern University of Science and Technology
International Quantum Academy
University of Colorado Boulder

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

One of the current challenges in nanoscience is tailoring phononic devices, such as thermal regulators and thermal computing. This has long been a rather elusive task because the thermal-switching ratio is not as high as electronic analogs. Mapping from a topological kirigami assembly, nitrogen-doped porous graphene metamaterials on the nanoscale are inversely designed with a thermal-switching ratio of 27.79, which is more than double the value of previous work. We trace this behavior to the chiral folding-unfolding deformation, resulting in a metal-insulator transition. This study provides a nanomaterial design paradigm to bridge the gap between kinematics and functional metamaterials that motivates the development of high-performanc.

Original language	English
Article number	L011001
Journal	Physical Review Applied
Volume	19
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevApplied.19.L011001
State	Published - Jan 2023

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10.1103/PhysRevApplied.19.L011001

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title = "Kirigami-Inspired Thermal Regulator",

abstract = "One of the current challenges in nanoscience is tailoring phononic devices, such as thermal regulators and thermal computing. This has long been a rather elusive task because the thermal-switching ratio is not as high as electronic analogs. Mapping from a topological kirigami assembly, nitrogen-doped porous graphene metamaterials on the nanoscale are inversely designed with a thermal-switching ratio of 27.79, which is more than double the value of previous work. We trace this behavior to the chiral folding-unfolding deformation, resulting in a metal-insulator transition. This study provides a nanomaterial design paradigm to bridge the gap between kinematics and functional metamaterials that motivates the development of high-performanc.",

author = "Hongyi Ouyang and Yuanqing Gu and Zhibin Gao and Lei Hu and Zhen Zhang and Jie Ren and Baowen Li and Jun Sun and Yan Chen and Xiangdong Ding",

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T1 - Kirigami-Inspired Thermal Regulator

AU - Ouyang, Hongyi

AU - Gu, Yuanqing

AU - Gao, Zhibin

AU - Hu, Lei

AU - Zhang, Zhen

AU - Ren, Jie

AU - Li, Baowen

AU - Sun, Jun

AU - Chen, Yan

AU - Ding, Xiangdong

PY - 2023/1

Y1 - 2023/1

N2 - One of the current challenges in nanoscience is tailoring phononic devices, such as thermal regulators and thermal computing. This has long been a rather elusive task because the thermal-switching ratio is not as high as electronic analogs. Mapping from a topological kirigami assembly, nitrogen-doped porous graphene metamaterials on the nanoscale are inversely designed with a thermal-switching ratio of 27.79, which is more than double the value of previous work. We trace this behavior to the chiral folding-unfolding deformation, resulting in a metal-insulator transition. This study provides a nanomaterial design paradigm to bridge the gap between kinematics and functional metamaterials that motivates the development of high-performanc.

AB - One of the current challenges in nanoscience is tailoring phononic devices, such as thermal regulators and thermal computing. This has long been a rather elusive task because the thermal-switching ratio is not as high as electronic analogs. Mapping from a topological kirigami assembly, nitrogen-doped porous graphene metamaterials on the nanoscale are inversely designed with a thermal-switching ratio of 27.79, which is more than double the value of previous work. We trace this behavior to the chiral folding-unfolding deformation, resulting in a metal-insulator transition. This study provides a nanomaterial design paradigm to bridge the gap between kinematics and functional metamaterials that motivates the development of high-performanc.

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DO - 10.1103/PhysRevApplied.19.L011001

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SN - 2331-7019

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JO - Physical Review Applied

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Kirigami-Inspired Thermal Regulator

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