Nodal Quasiparticle Dispersion in Strongly Correlated d-wave Superconductors

TL;DR

This paper investigates how momentum-dependent self-energy affects quasiparticle dispersion in high Tc cuprates, revealing that high energy dispersion increases with underdoping and aligns with experimental photoemission data.

Contribution

It provides a detailed analysis of nodal quasiparticle dispersion considering momentum-dependent self-energy effects, connecting variational results with experimental observations.

Findings

High energy MDC dispersion is much larger than the bare velocity.

High energy dispersion increases strongly with underdoping.

Results are consistent with recent photoemission experiments.

Abstract

We analyze the effects of a momentum-dependent self-energy on the photoemission momentum distribution curve (MDC) lineshape, dispersion and linewidth. We illustrate this general analysis by a detailed examination of nodal quasiparticles in high Tc cuprates. We use variational results for the nodal quasiparticle weight Z (which varies rapidly with hole doping x) and the low energy Fermi velocity $v_F^{low}$ (which is independent of x), to show that the high energy MDC dispersion $v_{high} = v_F^{low}/Z$, so that it is much larger than the bare (band structure) velocity and also increases strongly with underdoping. We also present arguments for why the low energy Fermi velocity and the high energy dispersion are independent of the bare band structure at small x. All of these results are in good agreement with earlier and recent photoemission data [Zhou et al, Nature 423, 398 (2003)].