Superconducting gap evolution in overdoped BaFe2(As1-xPx)2 single crystals through nanocalorimetry

Abstract

We report on specific heat measurements on clean overdoped BaFe2(As1-xPx)2 single crystals performed with a high resolution membrane-based nanocalorimeter. A nonzero residual electronic specific heat coefficient at zero temperature γr=C/T|T 0 is seen for all doping compositions, indicating a considerable fraction of the Fermi surface ungapped or having very deep minima. The remaining superconducting electronic specific heat is analyzed through a two-band s-wave α model in order to investigate the gap structure. Close to optimal doping we detect a single zero-temperature gap of 0 5.3\,meV, corresponding to 0 / kB Tc 2.2. Increasing the phosphorus concentration x, the main gap reduces till a value of 0 1.9\,meV for x = 0.55 and a second weaker gap becomes evident. From the magnetic field effect on γr, all samples however show similar behavior [γr(H) - γr(H=0) Hn, with n between 0.6 and 0.7]. This indicates that, despite a considerable redistribution of the gap weights, the total degree of gap anisotropy does not change drastically with doping.