Quantum Monte Carlo fermion spectroscopy of a non-compact CP$^1$ model

TL;DR

This study uses Quantum Monte Carlo simulations to analyze a non-compact CP$^1$ model with suppressed hedgehogs, revealing electron spectral properties and fractionalized excitations relevant to high-temperature superconductors.

Contribution

It provides the first detailed quantum Monte Carlo analysis of a hedgehog-suppressed electron-boson model with fractionalized excitations on a bilayer lattice.

Findings

Electron gap resembles mean-field dispersion in an antiferromagnetic background.

System preserves translation and spin rotation symmetry.

Results suggest implications for high-temperature superconductivity.

Abstract

We study a model describing electrons coupled to anti-ferromagnetic spin fluctuations, and consider the situation where hedgehog defects in the order parameter field are suppressed. Without hedgehogs, the bosonic sector of the theory can be taken to realize the physics of the non-compact CP$^1$ theory with a deconfined U$(1)$ gauge field. After strongly coupling the boson to fermion spins, we simulate the single-particle spectral properties of a hedgehog-suppressed electron-boson model defined on a bilayer square lattice with Quantum Monte Carlo, and interpret the results in terms of an effective theory with fractionalized spinon and chargon excitations. As one of our main results we show that the electron gap on top of the half-filled insulator with gapless photon fluctuations closely resembles the mean-field dispersion of an electron in an anti-ferromagnetic spin background, even though the system fully preserves both the translation and spin rotation symmetry. Finally, we discuss potential implications of our results for the high-temperature superconductors.