Institute for Solid State Physics, The University of Tokyo1
The layered pnictide oxides, ATi2Pn2O (A = Ba, (SrF)2, Na2; Pn = As, Sb, Bi), consist of alternating stacked (Ti2Pn2O)2– and A2+ layers, the former of which contains a Ti2O suare lattice. Among them, BaTi2Sb2O and BaTi2Bi2O exhibit superconductivity at 1.2 and 4.6 K, respectively. In contrast, the isostructural nonsuperconducting compound BaTi2As2O shows an electronic nematic-like transition at Ta = 200 K. The nematic phase is suppressed by isovalent pnictide substitution (As3–→Sb3–), resulting in the emergence of superconductivity. Further isovalent substitution (Sb3–→Bi3–) results in the disappearance of the neamatic phase and a two-dome structure in Tc is observed, which is similar as that of the iron-based superconductors1. The role of the electronic nematic phase in the superconductivity and the origin of the two-dome structure in BaTi2Pn2O have not been clarified yet, but may provide a helpful clue to the high-Tc superconductivity.
To tackle this issue, we have studied the superconductivity and electronic nematic phases of BaTi2Pn2O. In the solid solutions of BaTi2(As1‒xSbx)2O, with decreasing temperature, the superconducting samples (x = 0.9 and 1) showed a sign change in the Seebeck coefficient from negative to positive at Ta whereas As-rich side of x ≤ 0.8 did not. Thus, this change in the electronic state must be important to the emergence of superconductivity. In BaTi2Bi2O, another nematic phase was found by 209Bi-NMR/NQR measurements and X-ray diffraction2. Though the Ta is similar to that of BaTi2Sb2O, the orthorhombicity of BaTi2Bi2O was much larger than that of BaTi2Sb2O, implying a significant difference for the nematic phases of both compounds. Hence, the two different nematic phases may be responsible for the emergence of the two-dome structure in BaTi2Pn2O.
1) T. Yajima, Condens. Matter, 2, 4 (2017).
2) S. Kitagawa, K. Ishida, W. Ishii, T. Yajima, and Z. Hiroi, Phys. Rev. B, 98, 220507(R) (2018).
Keywords: Titanium pnictide oxides, Superconductivity, Electronic nematic phase