Superconductivity in a new layered nickel-selenide CsNi2Se2

Abstract

The physical properties of CsNi2Se2 were characterized by electrical resistivity, magnetization and specific heat measurements. We found that the stoichiometric CsNi2Se2 compound is a superconductor with a transition temperature Tc=2.7K. A large Sommerfeld coefficient γn (77.90 mJ/mol·K-2), was obtained from the normal state electronic specific heat. However, the Kadowaki-Woods ratio of CsNi2Se2 was estimated to be about 0.041×10-5 μ·cm(mol·K/mJ)2, indicating the absence of strong electron-electron correlations in this compound. In the superconducting state, we found that the zero-field electronic specific heat data, Ces(T) (0.5K ≤ T < 2.6K), can be well fitted with a two-gap BCS model. The comparison with the results of the density functional theory (DFT) calculations suggested that the large γn in the nickel-selenide superconductors may be related to the large Density of States (DOS) at the fermi surface.