Abstract
We formulate a model describing the doping (x) and temperature (T) dependence of the and c-axis penetration depth of a cuprate superconductor. The model incorporates the suppression of the superfluid density with underdoping as the system approaches the Mott-Hubbard insulating state by augmenting a d-wave BCS model with a phenomenological charge renormalization factor that is vanishingly small for states away from the nodes of the d-wave pair potential but close to unity in the vicinity of the nodes. The c-axis penetration depth is captured within a model of incoherent electron tunneling between the planes. Application of this model to the recent experimental data on the high-purity single crystals of implies existence of a “nodal protectorate,” a k-space region in the vicinity of the nodes whose size decreases in proportion to x, in which d-wave quasiparticles remain sharp even as the system teeters on the brink of becoming an insulator. The superfluid density, which is extremely small for these samples, also appears to come exclusively from these protected nodal regions.
- Received 18 December 2003
DOI:https://doi.org/10.1103/PhysRevB.70.054510
©2004 American Physical Society