# Absence of Landau damping in driven three-component Bose-Einstein   condensate in optical lattices

**Authors:** Gavriil Shchedrin, Daniel Jaschke, and Lincoln D. Carr

arXiv: 1705.10199 · 2018-08-28

## TL;DR

This paper investigates a three-component Bose-Einstein condensate in optical lattices driven by laser fields, revealing a laser-induced energy gap and suppression of Landau damping of collective modes due to laser-induced roton modes.

## Contribution

The study provides exact analytical solutions for the energy spectrum and elementary excitations, highlighting the effects of laser driving on damping mechanisms in multi-component BECs.

## Key findings

- Laser fields induce a gap in the Bogoliubov spectrum.
- Landau damping is suppressed above the energy gap.
- Laser-induced roton modes carry damping above the gap.

## Abstract

We explore the quantum many-body physics of a three-component Bose-Einstein condensate (BEC) in an optical lattices driven by laser fields in $V$ and $\Lambda$ configurations. We obtain exact analytical expressions for the energy spectrum and amplitudes of elementary excitations, and discover symmetries among them. We demonstrate that the applied laser fields induce a gap in the otherwise gapless Bogoliubov spectrum. We find that Landau damping of the collective modes above the energy of the gap is carried by laser-induced roton modes and is considerably suppressed compared to the phonon-mediated damping endemic to undriven scalar BECs.

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Source: https://tomesphere.com/paper/1705.10199