材料科学
自愈
可穿戴计算机
可穿戴技术
自愈材料
纳米技术
热电效应
复合材料
计算机科学
嵌入式系统
物理
热力学
医学
替代医学
病理
作者
Youngshang Han,Halil Tetik,Mohammad H. Malakooti
标识
DOI:10.1002/adma.202407073
摘要
Abstract Flexible thermoelectric devices (TEDs) exhibit adaptability to curved surfaces, holding significant potential for small‐scale power generation and thermal management. However, they often compromise stretchability, energy conversion, or robustness, thus limiting their applications. Here, the implementation of 3D soft architectures, multifunctional composites, self‐healing liquid metal conductors, and rigid semiconductors is introduced to overcome these challenges. These TEDs are extremely stretchable, functioning at strain levels as high as 230%. Their unique design, verified through multiphysics simulations, results in a considerably high power density of 115.4 µW cm⁻ 2 at a low‐temperature gradient of 10 °C. This is achieved through 3D printing multifunctional elastomers and examining the effects of three distinct thermal insulation infill ratios (0%, 12%, and 100%) on thermoelectric energy conversion and structural integrity. The engineered structure is lighter and effectively maintains the temperature gradient across the thermoelectric semiconductors, thereby resulting in higher output voltage and improved heating and cooling performance. Furthermore, these thermoelectric generators show remarkable damage tolerance, remaining fully functional even after multiple punctures and 2000 stretching cycles at 50% strain. When integrated with a 3D‐printed heatsink, they can power wearable sensors, charge batteries, and illuminate LEDs by scavenging body heat at room temperature, demonstrating their application as self‐sustainable electronics.
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