Photoinduced enhancement of superconductivity in the plaquette Hubbard model

TL;DR

This study uses real-time dynamics techniques to demonstrate that photoexcitation can significantly enhance superconductivity in a two-dimensional plaquette Hubbard model, providing insights into out-of-equilibrium superconducting states.

Contribution

It introduces a novel application of unbiased time-resolved exact diagonalization to explore photoinduced superconductivity in the plaquette Hubbard model.

Findings

Significant enhancement of d-wave superconductivity observed.

Extension of pairing amplitude analysis to frequency-anisotropy plane.

Potential for experimental engineering of out-of-equilibrium states.

Abstract

Real-time dynamics techniques have proven increasingly useful in understanding strongly correlated systems both theoretically and experimentally. By employing unbiased time-resolved exact diagonalization, we study pump dynamics in the two-dimensional plaquette Hubbard model, where distinct hopping integrals $t_h$ and $t_h^\prime$ are present within and between plaquettes. In the intermediate coupling regime, a significant enhancement of $d$-wave superconductivity is observed and compared with that obtained by simple examination of expectation values with the eigenstates of the Hamiltonian. Our work provides further understanding of superconductivity in the Hubbard model, extends the description of the pairing amplitude to the frequency-anisotropy plane, and offers a promising approach for experimentally engineering emergent out-of-equilibrium states.