News Release

New thermal dome concept revolutionizes heat invisibility technology

Peer-Reviewed Publication

Higher Education Press

The schematic representation of the thermal dome and cross-sectional view

image: 

(a) The schematic representation of the thermal dome and (b) its cross-sectional view. (c) The cross-sectional view of a single-layer hemispherical thermal dome. (d) The thickness of a single-layer hemispherical thermal dome d is shown as a function of lc and r.

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Credit: Yuhong Zhou et al.

In a recent development, a research team from multiple institutions in China has proposed a novel concept of a thermal dome that could significantly advance the field of thermal invisibility technology. The study, published in Engineering, offers a potential solution to long-standing limitations in traditional thermal cloaking devices.

Thermal metamaterials have been a subject of extensive research for controlling heat conduction, with thermal invisibility being a crucial aspect. However, existing thermal invisibility schemes face challenges in practical applications. Traditional cloaks often fully enclose objects, making them difficult to use and unsuitable for objects with heat sources. Moreover, while some theoretical designs for dynamic invisibility exist, they are complex and rigid, limiting their large-scale use in real three-dimensional (3D) spaces.

The newly proposed thermal dome concept aims to address these issues. It features an open functional area, enhancing usability and applicability, especially for objects with heat sources. The dome’s reconfigurable structure, inspired by Lego blocks, allows for easy assembly and adaptation to different environments, which is a significant improvement over conventional thermal cloaks.

The design principles of the thermal dome involve careful consideration of shape and material. The semi-ellipsoidal shape was chosen for its symmetry and flexibility in meeting design requirements. By solving differential equations, the researchers determined the necessary conditions for the thermal dome to achieve thermal invisibility, including specific relationships between the thermal conductivities of the dome, core, and background.

The functionality of the reconfigurable thermal dome was confirmed through simulations and experiments. Commercial software COMSOL Multiphysics was used for finite-element simulations, validating the theoretical design. Experimental validation was also conducted using hemispherical thermal domes with different background materials and configurations. The results demonstrated the dome’s effectiveness in shielding objects and maintaining stable internal temperatures, even in the presence of heat sources.

This research represents a significant step forward in the development of thermal invisibility technology. The thermal dome concept not only overcomes previous limitations but also offers a practical and adaptable solution for various engineering applications. It could potentially inspire further research in other physical domains, such as direct current electric fields and magnetic fields, opening new avenues for innovation in heat management and cloaking technologies.

The paper “Reconfigurable Three-Dimensional Thermal Dome,” authored by Yuhong Zhou, Fubao Yang, Liujun Xu, Pengfei Zhuang, Dong Wang, Xiaoping Ouyang, Ying Li, Jiping Huang. Full text of the open access paper: https://doi.org/10.1016/j.eng.2024.07.021. For more information about the Engineering, follow us on X (https://twitter.com/EngineeringJrnl) & like us on Facebook (https://www.facebook.com/EngineeringJrnl).


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