Weak phase stiffness and nature of the quantum critical point in underdoped cuprates

We demonstrate that the zero-temperature superconducting phase diagram of underdoped cuprates can be quantitatively understood in the strong binding limit, using only the experimental spectral function of the "normal" pseudo-gap phase without any free parameter. In the prototypical (La\(_{1-x}\)Sr\(_x\))\(_2\)CuO\(_4\), a kinetics-driven \(d\)-wave superconductivity is obtained above the critical doping \(\delta_c\sim 5.2\%\), below which complete loss of superfluidity results from local quantum fluctuation involving local \(p\)-wave pairs. Near the critical doping, a enormous mass enhancement of the local pairs is found responsible for the observed rapid decrease of phase stiffness. Finally, a striking mass divergence is predicted at \(\delta_c\) that dictates the occurrence of the observed quantum critical point and the abrupt suppression of the Nernst effects in the nearby region.