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An Organic–Inorganic Superlattice with Nanocrystal-Amorphous Composite Nanolayers for Ultrahigh Thermoelectric Performanceopen accessAn Organic-Inorganic Superlattice with Nanocrystal-Amorphous Composite Nanolayers for Ultrahigh Thermoelectric Performance

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An Organic-Inorganic Superlattice with Nanocrystal-Amorphous Composite Nanolayers for Ultrahigh Thermoelectric Performance
Authors
Palani, IndirajithNguyen, Duyen ThiKim, JongchanNguyen, Quang KhanhNguyen, Long VanSong, Da SomLim, Jong SunKim, Chang GyonCho, KyeongjaeSung, Myung Mo
Issue Date
Oct-2024
Publisher
WILEY
Keywords
hybrid superlattices; nanocrystal-amorphous composites; thermoelectric materials; ultrahigh ZT values
Citation
Small Structures, v.6, no.10, pp 1 - 8
Pages
8
Indexed
SCIE
SCOPUS
Journal Title
Small Structures
Volume
6
Number
10
Start Page
1
End Page
8
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/211211
DOI
10.1002/sstr.202400201
ISSN
2688-4062
2688-4062
Abstract
Thermoelectric materials play a crucial role in converting heat into electricity, offering significant potential for applications in waste heat recovery and cooling. Herein, an innovative approach that combines an organic–inorganic hybrid superlattice structure with nanocrystal-amorphous composite nanolayers is introduced. The nanocrystal-amorphous composite enhances the Seebeck coefficient resulting in a notable twofold improvement in the power factor. The superlattice, alternating self-assembled organic monolayers and inorganic nanolayers, effectively reduces lattice thermal conductivity by creating multiple interfaces that scatter phonons effectively. The integration of the nanocrystal-amorphous composite nanolayers into the superlattice provides a dual advantage, simultaneously boosting the power factor and suppressing thermal conductivity. This synergistic effect leads to exceptional thermoelectric performance in the 4-mercaptophenol/Sb2Te3 superlattice, with achieved figure of merit (ZT) values of 3.48 at 300 K and reaching a peak ZT value exceeding 4.0 at 400 K while surpassing 2.5 over the temperature range from 300 to 500 K. These results suggest that this innovative approach paves the way for the development of highly efficient thermoelectric materials, propelling efforts toward more energy-efficient and environmentally friendly solutions.
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