Atomic-scale Electronic Structure of the Cuprate d-Symmetry Form Factor Density Wave State

Abstract

Extensive research into high temperature superconducting cuprates is now focused upon identifying the relationship between the classic 'pseudogap' phenomenon1,2 and the more recently investigated density wave state3-13. This state always exhibits wave vector Q parallel to the planar Cu-O-Cu bonds4-13 along with a predominantly d-symmetry form factor14-17 (dFF-DW). Finding its microscopic mechanism has now become a key objective18-30 of this field. To accomplish this, one must identify the momentum-space (k-space) states contributing to the dFF-DW spectral weight, determine their particle-hole phase relationship about the Fermi energy, establish whether they exhibit a characteristic energy gap, and understand the evolution of all these phenomena throughout the phase diagram. Here we use energy-resolved sublattice visualization14 of electronic structure and show that the characteristic energy of the dFF-DW modulations is actually the 'pseudogap' energy 1. Moreover, we demonstrate that the dFF-DW modulations at E=-1 (filled states) occur with relative phase π compared to those at E=1 (empty states). Finally, we show that the dFF-DW Q corresponds directly to scattering between the 'hot frontier' regions of k-space beyond which Bogoliubov quasiparticles cease to exist31,32,33. These data demonstrate that the dFF-DW state is consistent with particle-hole interactions focused at the pseudogap energy scale and between the four pairs of 'hot frontier' regions in k-space where the pseudogap opens.