Transferable, highly crystalline covellite membrane for multifunctional thermoelectric systems
Myungwoo Choi,
Geonhee Lee,
Yea‐Lee Lee,
Hyejeong Lee,
Jin‐Hoon Yang,
Hanhwi Jang,
Hyeonseok Han,
MinSoung Kang,
Seonggwang Yoo,
A‐Rang Jang,
Yong Suk Oh,
Inkyu Park,
Min‐Wook Oh,
Hosun Shin,
Seokwoo Jeon,
Jeong‐O Lee,
Donghwi Cho
Affiliations
Myungwoo Choi
Department of Materials Science and Engineering Korea University Seoul Republic of Korea
Geonhee Lee
Thin Film Materials Research Center Korea Research Institute of Chemical Technology Daejeon Republic of Korea
Yea‐Lee Lee
Chemical Data‐Driven Research Center Korea Research Institute of Chemical Technology Daejeon Republic of Korea
Hyejeong Lee
Division of Chemical and Material Metrology Korea Research Institute of Standards and Science Daejeon Republic of Korea
Jin‐Hoon Yang
Chemical Data‐Driven Research Center Korea Research Institute of Chemical Technology Daejeon Republic of Korea
Hanhwi Jang
Department of Materials Science and Engineering Korea Advanced Institute of Science and Technology Daejeon Republic of Korea
Hyeonseok Han
Department of Mechanical Engineering Korea Advanced Institute of Science and Technology Daejeon Republic of Korea
MinSoung Kang
Therapeutics & Biotechnology Division, Drug Discovery Platform Research Center Korea Research Institute of Chemical Technology Daejeon Republic of Korea
Seonggwang Yoo
Querry Simpson Institute for Bioelectronics Northwestern University Evanston Illinois USA
A‐Rang Jang
Division of Electrical, Electronic and Control Engineering Kongju National University Cheonan Republic of Korea
Yong Suk Oh
Department of Mechanical Engineering Changwon National University Changwon Republic of Korea
Inkyu Park
Department of Mechanical Engineering Korea Advanced Institute of Science and Technology Daejeon Republic of Korea
Min‐Wook Oh
Department of Materials Science and Engineering Hanbat National University Daejeon Republic of Korea
Hosun Shin
Division of Chemical and Material Metrology Korea Research Institute of Standards and Science Daejeon Republic of Korea
Seokwoo Jeon
Department of Materials Science and Engineering Korea University Seoul Republic of Korea
Jeong‐O Lee
Thin Film Materials Research Center Korea Research Institute of Chemical Technology Daejeon Republic of Korea
Donghwi Cho
Thin Film Materials Research Center Korea Research Institute of Chemical Technology Daejeon Republic of Korea
Abstract Emerging freestanding membrane technologies, especially using inorganic thermoelectric materials, demonstrate the potential for advanced thermoelectric platforms. However, using rare and toxic elements during material processing must be circumvented. Herein, we present a scalable method for synthesizing highly crystalline CuS membranes for thermoelectric applications. By sulfurizing crystalline Cu, we produce a highly percolated and easily transferable network of submicron CuS rods. The CuS membrane effectively separates thermal and electrical properties to achieve a power factor of 0.50 mW m−1 K−2 and thermal conductivity of 0.37 W m−1 K−1 at 650 K (estimated value). This yields a record‐high dimensionless figure‐of‐merit of 0.91 at 650 K (estimated value) for covellite. Moreover, integrating 12 CuS devices into a module resulted in a power generation of ~4 μW at ΔT of 40 K despite using a straightforward configuration with only p‐type CuS. Furthermore, based on the temperature‐dependent electrical characteristics of CuS, we develop a wearable temperature sensor with antibacterial properties.
