A discovery by UCLA researchers and their colleagues on heat transfer through materials contradicts the conventional wisdom that heat always moves faster as pressure increases.
That conventional wisdom held true in observations and scientific experiments involving materials such as gases, liquids and solids. However, the research team observed that with boron arsenide, heat started to move slower under extreme pressure, suggesting a possible interference caused by the ways heat vibrates through a structure as pressure mounts.
The research was supported by the U.S. National Science Foundation, and results are published in Nature. The scientists found that boron arsenide, which has been viewed as a promising material for heat management and advanced electronics, has a unique property. After reaching a pressure hundreds of times greater than the pressure found at the bottom of the ocean, boron arsenide's thermal conductivity begins to decrease.
The results suggest that other materials might experience the same phenomenon under extreme conditions and may lead to novel materials that could be developed for smart energy systems.
"This finding shows that the general rule of pressure dependence starts to fail under extreme conditions," said study leader Yongjie Hu, a mechanical and aerospace engineer at UCLA. "We expect that this study will not only provide a benchmark for potentially revising the current understanding of heat movement, but could impact established modeling predictions for extreme conditions, such as those found in the Earth's interior, where direct measurements are not possible."
According to Hu, the breakthrough may lead to a retooling of standard techniques used in shock wave studies.
The work used computational and storage services associated with the NSF-supported Extreme Science and Engineering Discovery Environment, or XSEDE.
