Quantum turbulence: From superfluid helium to atomic Bose-Einstein condensates

TL;DR

This review explores recent advances in quantum turbulence within superfluid helium and atomic Bose-Einstein condensates, highlighting vortex dynamics, energy spectra, and visualization techniques to understand quantum fluid behavior.

Contribution

It provides a comprehensive overview of recent experimental and theoretical developments in quantum turbulence across different quantum fluids.

Findings

Quantum turbulence involves quantized vortices with topological defects.

Energy spectra and dissipation mechanisms in superfluid helium have been characterized.

Visualization techniques have advanced understanding of vortex dynamics.

Abstract

This article reviews recent developments in quantum fluid dynamics and quantum turbulence (QT) for superfluid helium and atomic Bose-Einstein condensates. Quantum turbulence was discovered in superfluid $^4$He in the 1950s, but the field moved in a new direction starting around the mid 1990s. Quantum turbulence is comprised of quantized vortices that are definite topological defects arising from the order parameter appearing in Bose-Einstein condensation. Hence QT is expected to yield a simpler model of turbulence than does conventional turbulence. A general introduction to this issue and a brief review of the basic concepts are followed by a description of vortex lattice formation in a rotating atomic Bose-Einstein condensate, typical of quantum fluid dynamics. Then we discuss recent developments in QT of superfluid helium such as the energy spectra and dissipative mechanisms at low temperatures, QT created by vibrating structures, and the visualization of QT. As an application of these ideas, we end with a discussion of QT in atomic Bose-Einstein condensates.