Author
Listed:
- Ji-Xiang Wang
(Chinese Academy of Sciences
Hebei Vocational University of Technology and Engineering
Clear Water Bay
Shanghai Golden Deep Technology Corporation)
- Mingliang Zhong
(Chinese Academy of Sciences
Chinese Academy of Sciences
Chinese Academy of Sciences
University of Chinese Academy of Sciences)
- Jia-Xin Li
(Beijing Institute of Astronautics System Engineering)
- Shaolong Wang
(Yangzhou University)
- Jiang Bian
(Chinese Academy of Sciences
Chinese Academy of Sciences)
- Yufeng Mao
(Chinese Academy of Sciences
Chinese Academy of Sciences)
- Hongmei Wang
(Shanghai Golden Deep Technology Corporation
Hong Kong Metropolitan University
Taizhou Wavexploration Energy Corporation Ltd.)
Abstract
Heat barrier, the unrestricted increase in airplane or rocket speeds caused by aerodynamic heating, which—without adequate provisions for cooling the exposed surfaces—can lead to the loss of a hypersonic vehicle’s reusability, maneuverability, and cost-effectiveness. To date, indirect thermal protection methods, such as regenerative cooling, film cooling, and transpiration cooling, have proven to be complex and inefficient. Here, we propose a direct liquid cooling system to mitigate the heat barrier, utilizing a blunt-sharp structured thermal armor (STA)—a recently proposed material [36] to elevate the Leidenfrost point. The fiber-metal nano-/micro-STA withstands rigorous simulated hypersonic aerodynamic heating using butane and acetylene flames, ensuring effective temperature management in scenarios where flame temperatures reach up to 3000 °C—far exceeding the melting point of the STA substrate. Systematic cycling and durability tests further confirm the STA’s exceptional tolerance and robustness under extreme conditions. This work offers an efficient thermal protection method for hypersonic vehicles.
Suggested Citation
Ji-Xiang Wang & Mingliang Zhong & Jia-Xin Li & Shaolong Wang & Jiang Bian & Yufeng Mao & Hongmei Wang, 2025.
"Mitigating hypersonic heat barrier via direct cooling enhanced by leidenfrost inhibition,"
Nature Communications, Nature, vol. 16(1), pages 1-12, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-62120-2
DOI: 10.1038/s41467-025-62120-2
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