Temperature-dependent evolutions of excitonic superfluid plasma frequency in a srong excitonic insulator candidate, Ta2NiSe5

Abstract

We investigate an interesting anisotropic van der Waals material, Ta2NiSe5, using optical spectroscopy. Ta2NiSe5 has been known as one of the few excitonic insulators proposed over 50 years ago. Ta2NiSe5 has quasi-one dimensional chains along the a-axis. We have obtained anisotropic optical properties of a single crystal Ta2NiSe5 along the a- and c-axes. The measured a- and c-axis optical conductivities exhibit large anisotropic electronic and phononic properties. With regard to the a-axis optical conductivity, a sharp peak near 3050 cm-1 at 9 K, with a well-defined optical gap (EI 1800 cm-1) and a strong temperature-dependence, is observed. With an increase in temperature, this peak broadens and the optical energy gap closes around 325 K(TcEI). The spectral weight redistribution with respect to the frequency and temperature indicates that the normalized optical energy gap (EI(T)/EI(0)) is 1-(T/TcEI)2. The temperature-dependent superfluid plasma frequency of the excitonic condensation in Ta2NiSe5 has been determined from measured optical data. Our findings may be useful for future research on excitonic insulators.