Thermal conductivity study of KFe2As2 single crystal: clear evidence for unconventional superconducting gap with nodes

Abstract

The in-plane resistivity and thermal conductivity of extremely overdoped KFe2As2 (Tc = 3.0 K) single crystal were studied. It is found that T1.5 at low temperature, a typical non-Fermi liquid behavior of electrons scattered by antiferromagnetic spin fluctuations. In zero field, we observed a large residual linear term 0/T, about one third of the normal-state value. In low magnetic fields, 0/T(H) increases very fast. Such a behavior of 0/T mimics the d-wave cuprate superconductors, therefore provides clear evidence for nodes in the superconducting gap of KFe2As2. Based on the Fermi surface topology of KFe2As2, it is believed that the dominant intraband pairing via antiferromagnetic spin fluctuations results in the unconventional superconducting gap with nodes.