Upper Critical Field and Specific Heat of Cuprates

Abstract

A representative set of magnetotransport measurements in novel superconductors is analyzed. The resistive upper critical field, H c2 (T) of many cuprates, of superconducting spin-ladders, and organic (TMTSF)2X systems has a universal nonlinear temperature dependence H c2 (T c -T) 3/2 in a wide temperature interval near T c , while its low-temperature behavior depends on the chemical formula and sample quality. The unusual H c2 (T) is described as the Bose-Einstein condensation field of preformed pairs. Its universal temperature dependence follows from the scaling arguments. Controversy in the determination of H c2 (T) from the resistivity and specific heat measurements is resolved in the framework of the charged Bose-gas model with the impurity scattering. It is shown that specific heat shows two anomalies. The high-temperature anomaly is strong and shows only weak shift with applied field. The low-temperature anomaly corresponds to resistive transition and is very weak in agreement with the experiments. Both anomalies coincide at H = 0.