Theja Vaskuri C S, Karthikeyan Vaithinathan, Assi Dani S, Gopalan Saianand, Roy Vellaisamy A L
Department of Materials Science and Engineering, City University of Hong Kong, Kowloon Tong, Hong Kong.
Department of Electronics and Nanoscale Engineering, James Watt School of Engineering, University of Glasgow, G12 8QQGlasgow, United Kingdom.
ACS Omega. 2022 Dec 15;7(51):48484-48492. doi: 10.1021/acsomega.2c06823. eCollection 2022 Dec 27.
Recently, copper-based chalcogenides, especially sulfides, have attracted considerable attention due to their inexpensive, earth-abundance, nontoxicity, and good thermoelectric performance. CuSbS is one such kind with p-type conductivity and high phase stability for potential medium-temperature applications. In this article, the effect of a multiwalled carbon nanotube (MWCNT) on the thermoelectric parameters of CuSbS is studied. A facile synthesis route of mechanical alloying (MA), followed by hot pressing (HP) was utilized to achieve dense and fine-grain samples. Adding the optimal amount of MWCNT nanoinclusions in CuSbS enhanced the Seebeck coefficient by carrier energy filtering and reduced the thermal conductivity by strong phonon scattering mechanisms. This synergistic optimization helped achieve the maximum figure of merit () of 0.43 in the 3 mol % MWCNT nanoinclusion composite sample, which is 70% higher than the pristine CuSbS at 623 K. In addition, enhancement in mechanical stability is observed with the increasing nanoinclusion concentration. Dispersion strengthening and grain boundary hardening mechanisms help improve mechanical stability in the nanocomposite samples. Apart from the enhanced mechanical stability, our study highlights that the incorporation of multiwalled CNT nanoinclusions boosted the thermoelectric performance of CuSbS, and the same strategy can be extended to other next-generation and conventional thermoelectric materials.
最近,铜基硫族化合物,尤其是硫化物,因其价格低廉、储量丰富、无毒且具有良好的热电性能而备受关注。CuSbS就是其中一种具有p型导电性和高相稳定性的化合物,适用于潜在的中温应用。在本文中,研究了多壁碳纳米管(MWCNT)对CuSbS热电参数的影响。采用了一种简便的合成路线,即机械合金化(MA)后进行热压(HP),以获得致密且细晶粒的样品。在CuSbS中添加最佳量的MWCNT纳米夹杂物,通过载流子能量过滤提高了塞贝克系数,并通过强声子散射机制降低了热导率。这种协同优化有助于在3 mol% MWCNT纳米夹杂物复合样品中实现0.43的最大优值(),在623 K时比原始CuSbS高出70%。此外,随着纳米夹杂物浓度的增加,观察到机械稳定性有所提高。弥散强化和晶界硬化机制有助于提高纳米复合样品的机械稳定性。除了增强的机械稳定性外,我们的研究还强调,多壁碳纳米管纳米夹杂物的掺入提高了CuSbS的热电性能,并且相同的策略可以扩展到其他下一代和传统热电材料。