Controlling mass and energy diffusion with metamaterials

Yang, Fubao; Zhang, Zeren; Xu, Liujun; Liu, Zhoufei; Jin, Peng; Zhuang, Pengfei; Lei, Min; Liu, Jinrong; Jiang, Jian-Hua; Ouyang, Xiaoping; Marchesoni, Fabio; Huang, Jiping

doi:10.1103/revmodphys.96.015002

Cited by 36 publications

(3 citation statements)

References 550 publications

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“…In contrast to wave processes, diffusion systems have distinctly different governing equations and application scenarios. Diffusionics 10,11 has emerged to manipulate heat 12 and other energy 13 and mass diffusions. Diffusion metamaterials [14][15][16] usually feature timedependent yet frequency-independent characteristic lengths.…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal diffusion metamaterials: Theories and applications

Liu,

Xu,

Huang

2024

Applied Physics Letters

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Diffusion metamaterials with artificial spatial structures have significant potential in controlling energy and mass transfer. Those static structures may lead to functionality and tunability constraints, impeding the application scope of diffusion metamaterials. Dynamic structures, adding the temporal dimension, have recently provided a new possibility for electric charge and heat diffusion regulation. This perspective introduces the fundamental theories and practical constructions of spatiotemporal diffusion metamaterials for achieving nonreciprocal, topological, or tunable properties. Compared with traditional static design, spatiotemporal modulation is promising to manipulate diffusion processes dynamically, with applications of real-time thermal coding and programming. Existing spatiotemporal diffusion explorations are primarily at macroscopic systems, and we may envision extending these results to microscale and other physical domains like thermal radiation and mass diffusion shortly.

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Section: Introductionmentioning

confidence: 99%

Spatiotemporal diffusion metamaterials: Theories and applications

Liu,

Xu,

Huang

2024

Applied Physics Letters

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“…The emergence of thermal metamaterials, coupled with their ongoing evolution and application, has fundamentally transformed the landscape of research in the manipulation of thermal transport behavior. [1][2][3][4][5][6][7][8][9] This evolution has given rise to a myriad of intriguing and practical applications, including thermal cloaks, [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] thermal concentrators, [14,25,26] thermal camouflage, [27][28][29][30][31][32][33][34][35] and thermal transparency. [36][37][38][39][40][41][42][43][44][45][46] In recent years, the exploration of thermal metamaterials and their applications has experienced a considerable boost thanks to the introduction of ma...…”

Section: Introductionmentioning

confidence: 99%

A graph neural network approach to the inverse design for thermal transparency with periodic interparticle system

Liu 刘,

Wang 王

2024

Chinese Phys. B

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Recent years have witnessed significant advancements in utilizing machine learningbased techniques for thermal metamaterial-based structures and devices to attain favorable thermal transport behavior. Among the various thermal transport behaviors, achieving thermal transparency stands out as particularly desirable and intriguing. Our earlier work demonstrated the use of a thermal metamaterial-based periodic interparticle system as the underlying structure for manipulating thermal transport behavior and achieving thermal transparency. In this paper, we introduce an approach based on graph neural network to address the complex inverse design problem of determining the design parameters for a thermal metamaterial-based periodic interparticle system with the desired thermal transport behavior. Our work demonstrates that combining graph neural network modeling and inference is an effective approach for solving inverse design problems associated with attaining desirable thermal transport behaviors using thermal metamaterials.

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“…[1,2] To enable daytime radiative cooling, near-zero solar energy absorption and ultra-high long-wave infrared (LWIR) emission are required. In recent years, the utilization of photonic crystals, [3][4][5][6] random particles, [7][8][9] porous films [10][11][12] and metamaterials [13][14][15][16][17] has been demonstrated to achieve effective radiative cooling. However, these static radiative coolers are only effective in high temperatures and are not suitable for low-temperature environments.…”

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Realization of an Adaptive Radiative Cooler with a Multilayer-Filter VO₂-Based Fabry–Pérot Cavity

Xie 谢,

Yin 殷,

Fan 范

2024

Chinese Phys. Lett.

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A high-performance adaptive radiative cooler comprising of multilayer filter and VO2-based Fabry-Perot (FP) cavity has been proposed. The bottom FP cavity adopts four layers of VO2/NaCl/PVC/Ag. Based on the phase transition of VO2, the average emissivity in the transparent window can be switched from 3.7% to 96.3%. Additionally, the average emissivity can also be adjusted with external strain to the PVC layer, providing another way to attain the desired cooling effect. The upper filter is included to block most of the solar radiation and provide a transmittance of 96.7% in the atmospheric window. At high temperature, the adaptive emitter automatically activates radiative cooling. The net cooling power is up to 156.4 W/m2 at an ambient temperature of 303 K. Our adaptive emitter still exhibits stable selective emissivity at different incident angle and heat transfer coefficient. At low temperature, the radiative cooling automatically deactivates, and the average emissivity decreases to only 3.8%. Therefore, our work not only provides new insights into the design of high-performance adaptive radiative coolers, but also advances the development of intelligent thermal management.

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Controlling mass and energy diffusion with metamaterials

Cited by 36 publications

References 550 publications

Spatiotemporal diffusion metamaterials: Theories and applications

Spatiotemporal diffusion metamaterials: Theories and applications

A graph neural network approach to the inverse design for thermal transparency with periodic interparticle system

Realization of an Adaptive Radiative Cooler with a Multilayer-Filter VO₂-Based Fabry–Pérot Cavity

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Controlling mass and energy diffusion with metamaterials

Cited by 36 publications

References 550 publications

Spatiotemporal diffusion metamaterials: Theories and applications

Spatiotemporal diffusion metamaterials: Theories and applications

A graph neural network approach to the inverse design for thermal transparency with periodic interparticle system

Realization of an Adaptive Radiative Cooler with a Multilayer-Filter VO2-Based Fabry–Pérot Cavity

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Realization of an Adaptive Radiative Cooler with a Multilayer-Filter VO₂-Based Fabry–Pérot Cavity