影响因子：4.3

DOI码：10.1021/acsomega.5c08859

所属单位：西南交通大学

教研室：微纳制造及智能传感技术

发表刊物：ACS Omega

项目来源：国家自然科学基金（52575673、52375578）

摘要：High-temperature sensors are irreplaceable for extreme-environment monitoring in aerospace, automotive, marine, and industry applications. This review synthesizes critical advances in materials, sensing principles, drift compensation, signal transmission, and encapsulation reliability. We analyze high-temperature-resistant ceramics, metals, crystalline materials, wide-band gap semiconductors, and high-entropy alloys, highlighting their operational mechanisms under high-temperature conditions. Subsequently, seven typical high-temperature sensing principles including fiber Bragg grating, LC resonance, Hall effect, magnetostriction, piezoelectric effect, Seebeck effect, and thermoelectric effect are expounded. Furthermore, the roles of software compensation strategies (curve fitting and neural networks) and hardware compensation approaches (material optimization and circuit design) in suppressing temperature drift are discussed. In addition, the thermomechanical reliability design of packaging technologies such as high-temperature tubular encapsulation, solid-state isolation encapsulation, substrate encapsulation, and leadless encapsulation is comprehensively reviewed. Finally, the operational performance of high-temperature sensors in high-temperature scenarios, such as automotive powertrains, aircraft engines, and marine turbines, is detailed. This review provides theoretical guidance and technical references for material selection, sensing principle innovation, and engineering implementation of high-temperature sensors.

合写作者：宋斌,毛宇聪,赵志俊,余丙军,钱林茂

第一作者：黄熙鸿

论文类型：SCI

通讯作者：汪红波*

学科门类：工学

文献类型：J

卷号：11

期号：4

页面范围：4843–4867

是否译文：否

发表时间：2026-01-21

收录刊物：SCI

发布期刊链接：https://pubs.acs.org/doi/full/10.1021/acsomega.5c08859