Theory of nonequilibrium dynamics of multiband superconductors

TL;DR

This paper investigates the nonequilibrium dynamics of multiband superconductors under ultrashort pulses, revealing oscillatory behaviors in the order parameters influenced by interband interactions.

Contribution

It introduces a density-matrix theoretical framework to analyze ultrafast dynamics in two-band superconductors with different interband interaction regimes.

Findings

Oscillations in superconducting gaps after ultrashort pulses.

Two distinct oscillatory frequencies depend on long-term gap values.

Interband interaction strength influences the oscillation characteristics.

Abstract

We study the nonequilibrium dynamics of multiband BCS superconductors subjected to ultrashort pump pulses. Using density-matrix theory, the time evolution of the Bogoliubov quasiparticle densities and the superconducting order parameters are computed as a function of pump pulse frequency, duration, and intensity. Focusing on two-band superconductors, we consider two different model systems. The first one, relevant for iron-based superconductors, describes two-band superconductors with a repulsive interband interaction $V_{12}$ which is much larger than the intraband pairing terms. The second model, relevant for MgB$_2$, deals with the opposite limit where the intraband interactions are dominant and the interband pair scattering $V_{12}$ is weak but attractive. For ultrashort pump pulses, both of these models exhibit a nonadiabatic behavior which is characterized by oscillations of the superconducting order parameters. We find that for nonvanishing $V_{12}$, the superconducting gap on each band exhibits two oscillatory frequencies which are determined by the long-time asymptotic values of the gaps. The relative strength of these two frequency components depends sensitively on the magnitude of the interband interaction $V_{12}$.