# Exact surface-wave spectrum of a dilute quantum liquid

**Authors:** Peter V. Pikhitsa, Uwe R. Fischer

arXiv: 1812.08002 · 2019-05-13

## TL;DR

This paper derives the exact surface-wave spectrum of a dilute Bose-Einstein condensate near a boundary, revealing precise dispersion relations for all wavenumbers and connecting theoretical predictions with experimental observations.

## Contribution

It provides the first exact analytical solutions for the surface excitation spectrum of a dilute quantum liquid for all wavevectors.

## Key findings

- Exact dispersion relations for surface excitations at all wavenumbers.
- Identification of a maximal binding energy for surface modes.
- Close agreement of theoretical binding energy with experimental data.

## Abstract

We consider a dilute gas of bosons with repulsive contact interactions, described on the mean-field level by the Gross-Pitaevskii equation, and bounded by an impenetrable "hard" wall (either rigid or flexible). We solve the Bogoliubov-de Gennes equations for excitations on top of the Bose-Einstein condensate analytically, by using matrix-valued hypergeometric functions. This leads to the exact spectrum of gapless Bogoliubov excitations localized near the boundary. The dispersion relation for the surface excitations represents for small wavenumbers $k$ a ripplon mode with fractional power law dispersion for a flexible wall, and a phonon mode (linear dispersion) for a rigid wall. For both types of excitation we provide, for the first time, the exact dispersion relations of the dilute quantum liquid for all $k$ along the surface, extending to $k \rightarrow \infty$. The small wavelength excitations are shown to be bound to the surface with a maximal binding energy $\Delta= \frac18 (\sqrt{17}-3)^2 mc^2 \simeq 0.158\, mc^2$, which both types of excitation asymptotically approach, where $m$ is mass of bosons and $c$ bulk speed of sound. We demonstrate that this binding energy is close to the experimental value obtained for surface excitations of helium II confined in nanopores, reported in Phys. Rev. B 88, 014521 (2013).

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1812.08002/full.md

## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/1812.08002/full.md

## References

37 references — full list in the complete paper: https://tomesphere.com/paper/1812.08002/full.md

---
Source: https://tomesphere.com/paper/1812.08002