Roadmap on thermodynamics and thermal metamaterials

Yuguang Qiu; Masahiro Nomura; Zhongwei Zhang; Shuang Lu; Sebastian Volz; Jie Chen; Jian Zhang; Haochun Zhang; Lilia M. Woods; Gaole Dai; Shuzhe Zhang; Xiangying Shen; S. L. Sobolev; Wenrui Liao; Fubao Yang; Liujun Xu; Shunan Li; Bingyang Cao; Yichao Liu; Tinglong Hou; Fei Sun; Kezhao Xiong; Hang Dong; Zonghua Liu; Hengli Xie; Chunzhen Fan; Xinran Li; Yungui Ma; Xinqiao Lin; Ousi Pan; Zhimin Yang; Yanchao Zhang; Jincan Chen; Shanhe Su; Qingxiang Ji; Muamer Kadic; Garuda Fujii; Zhaochen Wang; Run Hu; Junyi Nangong; Kaihuai Wen; Tiancheng Han; Qiangkailai Huang; Ying Li; Peichao Cao; Xuefeng Zhu; Zi Wang; Jie Ren; Xiuhua Zhao; Yuhan Ma; Yue Liu; Yuqi Han; Dahai He; Jiping Huang

doi:10.15302/frontphys.2025.065500

Roadmap on thermodynamics and thermal metamaterials

Yuguang Qiu
, Masahiro Nomura^*
, Zhongwei Zhang
, Shuang Lu
, Sebastian Volz^*
, Jie Chen^*
, Jian Zhang
, Haochun Zhang^*
, Lilia M. Woods^*
, Gaole Dai^*
, Shuzhe Zhang
, Xiangying Shen^*
, S. L. Sobolev^*
, Wenrui Liao
, Fubao Yang
, Liujun Xu^*
, Shunan Li
, Bingyang Cao^*
, Yichao Liu
, Tinglong Hou

Fei Sun^*, Kezhao Xiong, Hang Dong, Zonghua Liu^*, Hengli Xie, Chunzhen Fan^*, Xinran Li, Yungui Ma^*, Xinqiao Lin, Ousi Pan, Zhimin Yang, Yanchao Zhang, Jincan Chen, Shanhe Su^*, Qingxiang Ji, Muamer Kadic^*, Garuda Fujii^*, Zhaochen Wang, Run Hu^*, Junyi Nangong, Kaihuai Wen, Tiancheng Han^*, Qiangkailai Huang, Ying Li^*, Peichao Cao, Xuefeng Zhu^*, Zi Wang, Jie Ren^*, Xiuhua Zhao, Yuhan Ma^*, Yue Liu, Yuqi Han, Dahai He^*, Jiping Huang^*

^*Corresponding author for this work

School of Physics and Electronic Science

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

8 Scopus citations

Abstract

Thermal metamaterials represent a transformative paradigm in modern physics, synergizing thermodynamic principles with metamaterial engineering to master heat flow at will. As next-generation technologies demand multi-scale thermal control, this field urgently requires systematic frameworks to unify its multidisciplinary advances. Curated through a global collaboration involving over 50 specialists across 25 subdisciplines, this review primarily summarizes two decades of advancements, ranging from theoretical breakthroughs to functional implementations. The review reveals groundbreaking innovations in heat manipulation through the exploration of both classical and non-classical transport regimes, topological thermal control mechanisms, and quantum-informed phonon engineering strategies. By bridging physical insights like non-Hermitian thermal dynamics and valleytronic phonon transport with cutting-edge applications, we demonstrate paradigm-shifting capabilities: environment-adaptive thermal cloaks, AI-optimized metamaterials, and nonlinear thermal circuits enabling heat-based computation. Experimental milestones include 3D thermal null media with reconfigurable invisibility and thermal designs breaking classical conductivity limits. This collaborative effort establishes an indispensable roadmap for physicists, highlighting pathways to quantum thermal management, entropy-controlled energy systems, and topological devices. As thermal metamaterials transition from laboratory marvels to technological cornerstones, this work provides the foundational lexicon and design principles for the coming era of intelligent thermal matter.

Original language	English
Article number	065500
Journal	Frontiers of Physics
Volume	20
Issue number	6
DOIs	https://doi.org/10.15302/frontphys.2025.065500
State	Published - Dec 2025

Keywords

heat conduction control
heat transfer
thermal cloaking
thermal metamaterials
thermal rectification
topological thermotics
transformation thermotics

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10.15302/frontphys.2025.065500

Cite this

@article{02264ee4f3ee4da295f4881da9de4348,

title = "Roadmap on thermodynamics and thermal metamaterials",

abstract = "Thermal metamaterials represent a transformative paradigm in modern physics, synergizing thermodynamic principles with metamaterial engineering to master heat flow at will. As next-generation technologies demand multi-scale thermal control, this field urgently requires systematic frameworks to unify its multidisciplinary advances. Curated through a global collaboration involving over 50 specialists across 25 subdisciplines, this review primarily summarizes two decades of advancements, ranging from theoretical breakthroughs to functional implementations. The review reveals groundbreaking innovations in heat manipulation through the exploration of both classical and non-classical transport regimes, topological thermal control mechanisms, and quantum-informed phonon engineering strategies. By bridging physical insights like non-Hermitian thermal dynamics and valleytronic phonon transport with cutting-edge applications, we demonstrate paradigm-shifting capabilities: environment-adaptive thermal cloaks, AI-optimized metamaterials, and nonlinear thermal circuits enabling heat-based computation. Experimental milestones include 3D thermal null media with reconfigurable invisibility and thermal designs breaking classical conductivity limits. This collaborative effort establishes an indispensable roadmap for physicists, highlighting pathways to quantum thermal management, entropy-controlled energy systems, and topological devices. As thermal metamaterials transition from laboratory marvels to technological cornerstones, this work provides the foundational lexicon and design principles for the coming era of intelligent thermal matter.",

keywords = "heat conduction control, heat transfer, thermal cloaking, thermal metamaterials, thermal rectification, topological thermotics, transformation thermotics",

author = "Yuguang Qiu and Masahiro Nomura and Zhongwei Zhang and Shuang Lu and Sebastian Volz and Jie Chen and Jian Zhang and Haochun Zhang and Woods, \{Lilia M.\} and Gaole Dai and Shuzhe Zhang and Xiangying Shen and Sobolev, \{S. L.\} and Wenrui Liao and Fubao Yang and Liujun Xu and Shunan Li and Bingyang Cao and Yichao Liu and Tinglong Hou and Fei Sun and Kezhao Xiong and Hang Dong and Zonghua Liu and Hengli Xie and Chunzhen Fan and Xinran Li and Yungui Ma and Xinqiao Lin and Ousi Pan and Zhimin Yang and Yanchao Zhang and Jincan Chen and Shanhe Su and Qingxiang Ji and Muamer Kadic and Garuda Fujii and Zhaochen Wang and Run Hu and Junyi Nangong and Kaihuai Wen and Tiancheng Han and Qiangkailai Huang and Ying Li and Peichao Cao and Xuefeng Zhu and Zi Wang and Jie Ren and Xiuhua Zhao and Yuhan Ma and Yue Liu and Yuqi Han and Dahai He and Jiping Huang",

note = "Publisher Copyright: {\textcopyright} Higher Education Press 2025.",

year = "2025",

month = dec,

doi = "10.15302/frontphys.2025.065500",

language = "英语",

volume = "20",

journal = "Frontiers of Physics",

issn = "2095-0462",

publisher = "Higher Education Press Limited Company",

number = "6",

}

Qiu, Y, Nomura, M, Zhang, Z, Lu, S, Volz, S, Chen, J, Zhang, J, Zhang, H, Woods, LM, Dai, G, Zhang, S, Shen, X, Sobolev, SL, Liao, W, Yang, F, Xu, L, Li, S, Cao, B, Liu, Y, Hou, T, Sun, F, Xiong, K, Dong, H, Liu, Z, Xie, H, Fan, C, Li, X, Ma, Y, Lin, X, Pan, O, Yang, Z, Zhang, Y, Chen, J, Su, S, Ji, Q, Kadic, M, Fujii, G, Wang, Z, Hu, R, Nangong, J, Wen, K, Han, T, Huang, Q, Li, Y, Cao, P, Zhu, X, Wang, Z, Ren, J, Zhao, X, Ma, Y, Liu, Y, Han, Y, He, D & Huang, J 2025, 'Roadmap on thermodynamics and thermal metamaterials', Frontiers of Physics, vol. 20, no. 6, 065500. https://doi.org/10.15302/frontphys.2025.065500

TY - JOUR

T1 - Roadmap on thermodynamics and thermal metamaterials

AU - Qiu, Yuguang

AU - Nomura, Masahiro

AU - Zhang, Zhongwei

AU - Lu, Shuang

AU - Volz, Sebastian

AU - Chen, Jie

AU - Zhang, Jian

AU - Zhang, Haochun

AU - Woods, Lilia M.

AU - Dai, Gaole

AU - Zhang, Shuzhe

AU - Shen, Xiangying

AU - Sobolev, S. L.

AU - Liao, Wenrui

AU - Yang, Fubao

AU - Xu, Liujun

AU - Li, Shunan

AU - Cao, Bingyang

AU - Liu, Yichao

AU - Hou, Tinglong

AU - Sun, Fei

AU - Xiong, Kezhao

AU - Dong, Hang

AU - Liu, Zonghua

AU - Xie, Hengli

AU - Fan, Chunzhen

AU - Li, Xinran

AU - Ma, Yungui

AU - Lin, Xinqiao

AU - Pan, Ousi

AU - Yang, Zhimin

AU - Zhang, Yanchao

AU - Chen, Jincan

AU - Su, Shanhe

AU - Ji, Qingxiang

AU - Kadic, Muamer

AU - Fujii, Garuda

AU - Wang, Zhaochen

AU - Hu, Run

AU - Nangong, Junyi

AU - Wen, Kaihuai

AU - Han, Tiancheng

AU - Huang, Qiangkailai

AU - Li, Ying

AU - Cao, Peichao

AU - Zhu, Xuefeng

AU - Wang, Zi

AU - Ren, Jie

AU - Zhao, Xiuhua

AU - Ma, Yuhan

AU - Liu, Yue

AU - Han, Yuqi

AU - He, Dahai

AU - Huang, Jiping

PY - 2025/12

Y1 - 2025/12

N2 - Thermal metamaterials represent a transformative paradigm in modern physics, synergizing thermodynamic principles with metamaterial engineering to master heat flow at will. As next-generation technologies demand multi-scale thermal control, this field urgently requires systematic frameworks to unify its multidisciplinary advances. Curated through a global collaboration involving over 50 specialists across 25 subdisciplines, this review primarily summarizes two decades of advancements, ranging from theoretical breakthroughs to functional implementations. The review reveals groundbreaking innovations in heat manipulation through the exploration of both classical and non-classical transport regimes, topological thermal control mechanisms, and quantum-informed phonon engineering strategies. By bridging physical insights like non-Hermitian thermal dynamics and valleytronic phonon transport with cutting-edge applications, we demonstrate paradigm-shifting capabilities: environment-adaptive thermal cloaks, AI-optimized metamaterials, and nonlinear thermal circuits enabling heat-based computation. Experimental milestones include 3D thermal null media with reconfigurable invisibility and thermal designs breaking classical conductivity limits. This collaborative effort establishes an indispensable roadmap for physicists, highlighting pathways to quantum thermal management, entropy-controlled energy systems, and topological devices. As thermal metamaterials transition from laboratory marvels to technological cornerstones, this work provides the foundational lexicon and design principles for the coming era of intelligent thermal matter.

AB - Thermal metamaterials represent a transformative paradigm in modern physics, synergizing thermodynamic principles with metamaterial engineering to master heat flow at will. As next-generation technologies demand multi-scale thermal control, this field urgently requires systematic frameworks to unify its multidisciplinary advances. Curated through a global collaboration involving over 50 specialists across 25 subdisciplines, this review primarily summarizes two decades of advancements, ranging from theoretical breakthroughs to functional implementations. The review reveals groundbreaking innovations in heat manipulation through the exploration of both classical and non-classical transport regimes, topological thermal control mechanisms, and quantum-informed phonon engineering strategies. By bridging physical insights like non-Hermitian thermal dynamics and valleytronic phonon transport with cutting-edge applications, we demonstrate paradigm-shifting capabilities: environment-adaptive thermal cloaks, AI-optimized metamaterials, and nonlinear thermal circuits enabling heat-based computation. Experimental milestones include 3D thermal null media with reconfigurable invisibility and thermal designs breaking classical conductivity limits. This collaborative effort establishes an indispensable roadmap for physicists, highlighting pathways to quantum thermal management, entropy-controlled energy systems, and topological devices. As thermal metamaterials transition from laboratory marvels to technological cornerstones, this work provides the foundational lexicon and design principles for the coming era of intelligent thermal matter.

KW - heat conduction control

KW - heat transfer

KW - thermal cloaking

KW - thermal metamaterials

KW - thermal rectification

KW - topological thermotics

KW - transformation thermotics

UR - https://www.scopus.com/pages/publications/105008042654

U2 - 10.15302/frontphys.2025.065500

DO - 10.15302/frontphys.2025.065500

M3 - 文章

AN - SCOPUS:105008042654

SN - 2095-0462

VL - 20

JO - Frontiers of Physics

JF - Frontiers of Physics

IS - 6

M1 - 065500

ER -

Roadmap on thermodynamics and thermal metamaterials

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Keywords

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