Theory of Fluctuating Charge Ordering in the Pseudogap Phase of the Cuprates Via A Preformed Pair Approach

Abstract

We study the static and dynamic behavior of charge ordering within a d-wave pair pseudogap (pg) scenario. This is addressed using a density-density correlation function derived from the standard pg self energy, and compatible with the longitudinal and transverse sum rules. The broadening factor γ in reflects the breaking of pairs into constituent fermions. We apply this form for (derived elsewhere for high fields) to demonstrate the existence of quantum oscillations in a non-Fermi liquid pg state. Our conclusion is that the pseudogap-induced pairbreaking, via γ, allows the underlying fermiology to be revealed; in YBCO, finite ω and γ enable antinodal fluctuations, despite the competition with a d-wave gap in the static and superconducting limits.