| الوصف: |
Shortly after the discovery of high-temperature superconducting cuprates, Anderson proposed that Mott physics is instrumental in understanding their phase diagrams. Specifically, he suggested that, similar to the 'almost-localized' Fermi liquid in 3He, the effective mass renormalization in the cuprates is characteristic of a doped Mott insulator, scaling inversely with doping p away from half-filling. However, Mott physics has struggled to account for the 'strange metal' behavior, characterized by a linear-in-temperature (T) 'Planckian' resistivity that extends to very high temperatures, casting doubt on the relevance of Mott physics in the cuprates. Here, we report a comprehensive survey of calorimetry and resistivity data spanning broad doping and temperature ranges. We find that the entropy at high temperatures closely adheres to that of an almost-localized Fermi liquid, implying that Mott physics remains relevant at high energies. We find that the strong doping dependence of the coefficient of the T-linear resistivity at high temperatures also scales inversely with p, suggesting a true universality of the Planckian relaxation rate across the entire phase diagram. Thus, the physics of the cuprates over their entire phase diagram is determined by the joint action of Mott physics and Planckian relaxation physics, with each operating at very different energy scales. |
