Carbon nanotube films with ultrahigh thermal-shock and thermal-shock-fatigue resistance characterized by ultra-fast ascending shock testing

The exploration of material failure behavior not only involves defining its limits and underlying mechanisms but also entails devising strategies for improvement and protection in extreme conditions. We’ve pioneered an advanced multi-scale, high-speed ascending thermal shock testing platform capable...

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Bibliographic Details
Published in:Nano research 2024-08, Vol.17 (8), p.6777-6784
Main Authors: Zhu, Mingquan, Wang, Shijun, Bai, Yunxiang, Gao, Feng, Zhu, Zhenxing, Wang, Congying, Zhang, Peng, Jin, Hao, Zhang, Hui, Liu, Luqi, Xu, Zhiping, Zhang, Xinghong, Wei, Fei, Zhang, Zhong
Format: Article
Language:English
Subjects:
Atomic/Molecular Structure and Spectra
Biomedicine
Biotechnology
Carbon
Carbon nanotubes
Chemistry and Materials Science
Composite materials
Condensed Matter Physics
Critical temperature
Energy consumption
Exploratory behavior
Failure mechanisms
Fatigue failure
Fatigue strength
Fatigue tests
Glass substrates
Heaters
Laboratories
Materials failure
Materials fatigue
Materials Science
Microscopy
Nanoscience
Nanotechnology
Power supply
Research Article
Shock
Shock resistance
Spectrum analysis
Temperature
Thermal resistance
Thermal shock
Thermal stress
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Summary:The exploration of material failure behavior not only involves defining its limits and underlying mechanisms but also entails devising strategies for improvement and protection in extreme conditions. We’ve pioneered an advanced multi-scale, high-speed ascending thermal shock testing platform capable of inducing unprecedented heat shocks at rates surpassing 10 5 °C/s. Through meticulous examination of the thermal shock responses of carbon nanotube (CNT) films, we’ve achieved remarkable breakthroughs. By employing an innovative macro-scale synchronous tightening and relaxing approach, we’ve attained a critical temperature differential in CNT films that exceeds an exceptional 2500 °C—surpassing any previously reported metric for high-performance, thermal-shock-resistant materials. Notably, these samples have demonstrated exceptional resilience, retaining virtually unchanged strength even after enduring 10,000 thermal shock cycles at temperatures exceeding 1000 °C. Furthermore, our research has revealed a novel thermal shock/fatigue failure mechanism that fundamentally diverges from conventional theories centered on thermal stress.
ISSN:1998-0124
1998-0000
DOI:10.1007/s12274-024-6684-4