The 67th JSAP Spring Meeting 2020

Presentation information

Oral presentation

11 Superconductivity » 11.1 Fundamental properties

[13p-B408-1~16] 11.1 Fundamental properties

Fri. Mar 13, 2020 1:15 PM - 5:45 PM B408 (2-408)

Masanori Nagao(Univ. of Yamanashi), Hiraku Ogino(AIST), FUYUKI NABESHIMA(The University of Tokyo )

2:45 PM - 3:00 PM

[13p-B408-6] First Principles Calculations of Superconducting Transition Temperature of ThCr$_2$Si$_2$-type Structure

〇(M1)Gewinner Senderanto Sinaga1, Keishu Utimura1, Kousuke Nakano2, Kenta Hongo2,3,4,5, Ryo Maezono2,6 (1.Mater. Sci., JAIST, 2.Info. Sci., JAIST, 3.RCACI, JAIST, 4.NIMS, 5.PRESTO, 6.RIKEN)

Keywords:superconductivity, first-principles calculations, ThCr2Si2-type structure

High superconducting transition temperature (Tc) superconductors have a great potential in many industrial applications. However, discovering a compound having high Tc is still remaining a big challenge for experimental approach due to time-consuming and high cost. In this talk, we focus on ThCr2Si2-type compounds with a I4/mmm symmetry and predict their Tc values by combining first-principles phonon simulations with models based on the Bardeen-Cooper-Schrieffer (BCS) theory [1]. Although thousand compounds belong to this structure, no comprehensive and systematic study has been done so far. Referring to the NIMS database [2], our Tc results showed a fairly good agreement with the experimental data. Finally, our exploration within the ThCr2Si2 family revealed that ThCu2Si2 and ThAu2Si2 could be newly possible conventional superconductors having Tc around 3.88 K and 4.27 K, respectively [3]. Here our first principles phonon simulations confirmed that both of compounds have non-negative frequencies indicating the dynamical stability of the compounds at ambient temperature. In addition, we found that Fe or Co based compounds could not be explained just by electron-phonon interaction. This discrepancy between theory and experiment implies that those compounds are unconventional superconductors.
[1] K. Nakano, K. Hongo, and R. Maezono, Sci. Rep. 6, 29661 (2016).
[2] “Superconducting material database (supercon),” https://supercon.nims.go.jp/supercon/material_search, accessed: 2019-11-17
[3] G.S Sinaga, K. Uchimura, K. Nakano, K. Hongo, and R. Maezono, arXiv:1911.10716