The iron chalcogenide superconductor, Fe(Se,Te), has been attracting broad interests because of its potential ability for high-T_c superconductivity, the absence of the magnetic order under the ambient pressure, and the topological nature. In the Fe(Se,Te) film, it has been revealed that the superconducting transition temperature, T_c, increases almost twice when the nematic order disappears with increasing Te content [1]. In addition, the close correlation between the carrier density in the normal state and the T_c was observed in the Fe(Se,Te) and Fe(Se,S) film irrespective with the nematic order, indicating that the existence of the nematic order has less dominant contribution to the T_c than the carrier density [2]. However, it is still unclear whether the same trend exists in the superfluid density or not. Hence, in order to clarify the impact of the Te substitution on the electronic structure of Fe(Se,Te) and its relation to Tc, we measured the complex conductivity of FeSe_1-xTe_x­ (x=0.1-0.5) film in the superconducting state.

The real part of the complex conductivity, σ₁, was measured using the cavity perturbation technique. The quasiparticle scattering time, τ, was calculated from σ₁. Comparing the temperature dependence of τ among different compositions, no significant systematic changes were observed with increasing Te content in the temperature range, 0.2 T_c-0.75 T_c. On the other hand, the imaginary part of the complex conductivity, σ²∝λ^-2, measured by the superconducting coplanar resonator fabricated from the Fe(Se,Te) film, was found to correlate with T_c, and the so-called “Uemura relation” was observed. This indicates that the superfluid density, n_s∝λ^-2, plays a crucial role in the determination of T_c. The trend is consistent with the correlation found between T_c and the carrier density in the normal state. These results suggest that although the nematic order can change the electronic structure of the iron chalcogenide superconductors, the amount of the (superfluid) carrier density has the most direct correlation with T_c.

【References】
[1] Y. Imai et al., PNAS 112, 1937 (2015).
[2] F. Nabeshima et al., PRB 101, 184517 (2020).

Keywords: iron chalcogenide superconductor, microwave, complex conductivity, penetration depth