Affiliation:
1. School of Mechanical Electrical and Information Engineering Shandong University Weihai 264209 China
2. Suzhou Research Institute Shandong University 388 Ruoshui Road Suzhou 215123 China
3. School of Science RMIT University 124 La Trobe Street Melbourne Victoria 3000 Australia
Abstract
AbstractEffective and rapid heat transfer is critical to improving electronic components' performance and operational stability, particularly for highly integrated and miniaturized devices in complex scenarios. However, current thermal manipulation approaches, including the recent advancement in thermal metamaterials, cannot realize fast and unidirectional heat flow control. In addition, any defects in thermal conductive materials cause a significant decrease in thermal conductivity, severely degrading heat transfer performance. Here, the utilization of silicon‐based valley photonic crystals (VPCs) is proposed and numerically demonstrated to facilitate ultrafast, unidirectional heat transfer through thermal radiation on a microscale. Utilizing the infrared wavelength region, the approach achieves a significant thermal rectification effect, ensuring continuous heat flow along designed paths with high transmission efficiency. Remarkably, the process is unaffected by temperature gradients due to the unidirectional property, maintaining transmission directionality. Furthermore, the VPCs' inherent robustness affords defect‐immune heat transfer, overcoming the limitations of traditional conduction methods that inevitably cause device heating, performance degradation, and energy waste. The design is fully CMOS compatible, thus will find broad applications, particularly for integrated optoelectronic devices.
Funder
Australian Research Council Industrial Transformation Training Centre for Functional Grains
Australian Research Council
Natural Science Foundation of Shandong Province
Key Technology Research and Development Program of Shandong Province
Science and Technology Program of Suzhou