# The low-energy Goldstone mode in a trapped dipolar supersolid

**Authors:** Mingyang Guo, Fabian B\"ottcher, Jens Hertkorn, Jan-Niklas Schmidt,, Matthias Wenzel, Hans Peter B\"uchler, Tim Langen, Tilman Pfau

arXiv: 1906.04633 · 2019-11-05

## TL;DR

This paper demonstrates the existence of a low-energy Goldstone mode in a trapped dipolar supersolid, confirming its superfluid nature through direct observation of collective excitations, thus establishing a genuine supersolid phase.

## Contribution

It provides experimental evidence of a Goldstone mode in a dipolar supersolid, confirming its superfluidity and genuine supersolid properties beyond previous indirect observations.

## Key findings

- Observation of a low-energy Goldstone mode
- Out-of-phase oscillation of crystal and superfluid density
- Confirmation of superfluidity in the supersolid

## Abstract

A supersolid is a counter-intuitive state of matter that combines the frictionless flow of a superfluid with the crystal-like periodic density modulation of a solid. Since the first prediction in the 1950s, experimental efforts to realize this state have focussed mainly on Helium, where supersolidity remains elusive. Recently, supersolidity has also been studied intensively in ultracold quantum gases, and some of its defining properties have been induced in spin-orbit coupled Bose-Einstein condensates (BECs) and BECs coupled to two crossed optical cavities. However, the periodicity of the crystals in both systems is fixed to the wavelength of the applied periodic optical potentials. Recently, hallmark properties of a supersolid -- the periodic density modulation and simultaneous global phase coherence -- have been observed in arrays of dipolar quantum droplets, where the crystallization happens in a self-organized manner due to intrinsic interactions. In this letter, we prove the genuine supersolid nature of these droplet arrays by directly observing the low-energy Goldstone mode. The dynamics of this mode is reminiscent of the effect of second sound in other superfluid systems and features an out-ofphase oscillation of the crystal array and the superfluid density. This mode exists only due to the phase rigidity of the experimentally realized state, and therefore confirms the genuine superfluidity of the supersolid.

## Full text

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## Figures

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## References

48 references — full list in the complete paper: https://tomesphere.com/paper/1906.04633/full.md

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Source: https://tomesphere.com/paper/1906.04633