数码产品
热电材料
可穿戴技术
可穿戴计算机
计算机科学
纳米技术
材料科学
热电效应
电气工程
嵌入式系统
工程类
物理
热力学
作者
Lin Zhang,Xiao‐Lei Shi,Hongjing Shang,Hongwei Gu,Wenyi Chen,Meng Li,Daxing Huang,Hao Dong,Xiaolei Wang,Fazhu Ding,Zhi‐Gang Chen
标识
DOI:10.1038/s41467-025-60284-5
摘要
Flexible thermoelectric materials and devices hold enormous potential for wearable electronics but are hindered by inadequate material properties and inefficient assembly techniques, leading to suboptimal performance. Herein, we developed a flexible thermoelectric film, comprising Ag2Se nanowires as the primary material, a nylon membrane as a flexible scaffold, and reduced graphene oxide as a conductive network, achieving a record-high room-temperature ZT of 1.28. Hot-pressed Ag2Se nanowires exhibited strong (013) orientation, enhancing carrier mobility and electrical conductivity. Dispersed reduced graphene oxide further boosts electrical conductivity and induces an energy-filtering effect, decoupling electrical conductivity and the Seebeck coefficient to achieve an impressive power factor of 37 μW cm−1 K−2 at 300 K. The high-intensity between Ag2Se and reduced graphene oxide interfaces enhance phonon scattering, effectively reducing thermal conductivity to below 0.9 W m−1 K−1 and enabling the high ZT value. The nylon membrane endowed the film with exceptional flexibility. A large-scale out-of-plane device with 100 pairs of thermoelectric legs, assembled from these films, delivers an ultrahigh normalized power density of >9.8 μW cm−2 K−2, outperforming all reported Ag2Se-based flexible devices. When applied to the human body, the device generated sufficient power to operate a thermo-hygrometer and a wristwatch, demonstrating its practical potential for wearable electronics. The authors report a flexible thermoelectric film, comprising Ag2Se and reduced graphene oxide, achieving a power factor of 37 μW cm−1 K−2 in the film and a normalized power density of over 9.8 μW cm−2 K−2 in the out-of-plane device.
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