Revisiting the electronic phase diagram of YBa2Cu3Oy via temperature derivative of in-plane resistivity

Abstract

We have re-examined the temperature-doping (T-p) phase diagram of YBa2Cu3Oy (YBCO) to address several issues therein by using the temperature derivative of in-plane resistivity, d\rhoab/dT. For p less than about 0.15, a temperature Tf has been defined to mark the onset of an upturn in d\rhoab/dT at T>Tc, which, in light of prior studies on another cuprate La2-xSrxCuO4, is attributed to the onset of superconducting fluctuations in normal state. The Tf exhibits a doping dependence similar to Tc, and the interval between Tf and Tc is about 5-30 K across the underdoped regime, showing agreement with a variety of other measurements to probe a restricted temperature range of superconducting fluctuations. Above Tf, the d\rhoab/dT increases linearly as T increases up to a value denoted as T2, which is about half the T* and falls roughly in parallel with T* as p rises up to about 0.13, indicating a prominent T2-dependent \rhoab in this T-p region. The d\rhoab/dT helps reveal that, at Tf<T<T2, the \rhoab also involves an insulating-like component for p<0.08, or a T-linear component for p>0.10-0.11, thereby leaving a narrow window of doping for \rhoab to show a pure T2 dependence. As T increases further, the d\rhoab/dT reaches a local maximum at a temperature TR, signifying the known curvature change (inflection point) in \rhoab. With the derivatives, it is illustrated that, in the vicinity of TR, the in-plane Hall coefficient RH and thermopower Sab of YBCO display curvature changes as well, suggesting a correlation of the three transport properties. It is also found that the dSab/dT shows the onset of an upturn at a temperature coinciding with the Tf, which, backing the identification of Tf with the onset of superconducting fluctuations, demonstrates further the virtue of using the temperature derivative to unveil information helpful for the study of high-Tc cuprates.