Enhanced Thermoelectric Properties of 2D Janus Ferromagnetic LaBrI with Strain-induced Valley Degeneracy
Autor: | Kumari, Anuja, Nag, Abhinav, Maiti, Santanu K., Kumar, Jagdish |
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Rok vydání: | 2024 |
Předmět: | |
Druh dokumentu: | Working Paper |
Popis: | Since the successful synthesis of the MoSSe monolayer, which violated the out-of-plane mirror symmetry of TMDs monolayers, considerable and systematic research has been conducted on Janus monolayer materials. By systematically analyzing the LaBrI monolayer, we are able to learn more about the novel Janus material by focusing on the halogen family next to group VIA (S, Se, Te). The structural optimizations have been carried out using the FP-LAPW (Full Potential Linear Augmented Plane Wave) basis, as implemented in the ELK using tb-mBJ exchange correlation potential. Computed structural parameters are in good comparison with literature reports. Further, optimized crystal structures were used for computing effect of strain on electronic and thermoelectric properties using pseudo potential based Quantum espresso code. Dynamical stability predicts material can withstand strain upto 10% strain. Computed electronic structure reveals material to be indirect wide bandgap ferromagnetic material with magnetic moment 1{\mu}B. With increase in the biaxial tensile strain the band gap increases. Furthermore, the computed magneto-thermoelectric properties predicts high Seebeck coefficient of ~ 400 {\mu}V/K and low thermal conductivity of ~ 1.13 X 1014 W/msK in LaBrI which results high ZT of ~ 1.92 with 8% strain at 800 K with p-type doping. Thus, present study supports the fact that tensile strain on ferromagnetic LaBrI material can further enhance TE properties and making it to be a promising material for TE applications at higher temperature. Comment: 20 pages, 7 figures, Comments are Welcome |
Databáze: | arXiv |
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