Valence bond glass -- A unified theory of electronic disorder and pseudogap phenomena in high temperature superconductors

Abstract

We show that the low-energy fluctuations of the valence bond in underdoped high-Tc cuprates, originating from quantum fluctuations of the superexchange interaction, are pinned by the electronic disorder due to off-stoichiometric dopants, leading to a valence bond glass (VBG) pseudogap phase. The antinodal Fermi surface sections are gapped out, giving rise to a normal state Fermi arc whose length shrinks with underdoping. Below Tc, the superexchange interaction induces a d-wave superconducting gap that coexists with the VBG pseudogap. The evolution of the local and momentum-space spectroscopy with doping and temperature captures the salient properties of the pseudogap phenomena and the electronic disorder. The unified theory elucidates the important interplay between strong correlation and the intrinsic electronic disorder in doped transition metal oxides.