Scalable and environmentally friendly MXene-tetrahedrites for next-generation flexible thermoelectrics
- Authors
- Banerjee, Priyanshu; Huang, Jiyuan; Lombardo, Jacob; Ambade, Swapnil B.; Ambade, Rohan B.; Han, Tae Hee; Kulkarni, Srushti; Sengupta, Shreyasi; Rosenzweig, Zeev; Fairbrother, Howard; Li, Sichao; Shin, Sunmi; Madan, Deepa
- Issue Date
- Dec-2024
- Publisher
- Royal Society of Chemistry
- Citation
- Journal of Materials Chemistry A, v.13, no.1, pp 654 - 668
- Pages
- 15
- Indexed
- SCIE
SCOPUS
- Journal Title
- Journal of Materials Chemistry A
- Volume
- 13
- Number
- 1
- Start Page
- 654
- End Page
- 668
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/202211
- DOI
- 10.1039/d4ta05056h
- ISSN
- 2050-7488
2050-7496
- Abstract
- Traditional thermoelectric generators (TEGs) face scalability challenges due to high-temperature, long-duration curing processes and rare-earth/toxic chalcogenides such as bismuth telluride. Additive manufacturing has been investigated as a more time-, energy- and cost-efficient method that offers greater flexibility than traditional manufacturing techniques. Additionally, tetrahedrites are promising thermoelectric materials in high-temperature applications because they are non-toxic and earth-abundant. Herein, this work demonstrates the fabrication of scalable and sustainable Cu12Sb4S13 (CAS) based composite films and flexible TEG devices (f-TEGs) with 2D MXene nanosheets using a low-thermal budget additive manufacturing approach for room temperature applications. 2D MXene nanosheets introduced energy-barrier scattering and nanoscale features to effectively increase the room-temperature ZT to 0.22, 10% higher than bulk CAS, by decoupling electrical conductivity, Seebeck coefficient, and thermal conductivity. CAS and 2D MXenes were found to be environmentally safe through a bacterial viability study. The process is used to create a 5-leg f-TEG device producing a power of 5.3 mu W and a power density of 140 mu W cm-2 at a Delta T of 25 K. Therefore, this work demonstrates that combining scalable and sustainable materials and methods is an effective strategy for high-performance room-temperature f-TEGs that could potentially harvest the low waste heat energy of the human body.
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