The Effect of Pointlike Impurities on dx2-y2 Charge Density Waves in Cuprate Superconductors

Abstract

Many cuprate superconductors possess an unusual charge-ordered phase that is characterized by an approximate dx2-y2 intra-unit cell form factor and a finite modulation wavevector . We study the effects impurities on this charge ordered phase via a single-band model in which bond order is the analogue of charge order in the cuprates. Impurities are assumed to be pointlike and are treated within the self-consistent t-matrix approximation (SCTMA). We show that suppression of bond order by impurities occurs through the local disruption of the dx2-y2 form factor near individual impurities. Unlike d-wave superconductors, where the sensitivity of Tc to impurities can be traced to a vanishing average of the dx2-y2 order parameter over the Fermi surface, the response of bond order to impurities is dictated by a few Fermi surface "hotspots". The bond order transition temperature Tbo thus follows a different universal dependence on impurity concentration ni than does the superconducting Tc. In particular, Tbo decreases more rapidly than Tc with increasing ni when there is a nonzero Fermi surface curvature at the hotspots. Based on experimental evidence that the pseudogap is insensitive to Zn doping, we conclude that a direct connection between charge order and the pseudogap is unlikely. Furthermore, the enhancement of stripe correlations in the La-based cuprates by Zn doping is evidence that this charge order is also distinct from stripes.