A Luttinger Liquid Core Inside Helium-4 Filled Nanopores

TL;DR

This paper uses quantum Monte Carlo simulations to explore helium-4 in nanopores, revealing a Luttinger liquid core that could be experimentally observed, indicating a novel low-dimensional quantum state.

Contribution

It provides the first large-scale simulation evidence of a Luttinger liquid core in helium-4 confined within nanopores, bridging theory and potential experiments.

Findings

Helium-4 forms concentric shells with a Luttinger liquid core.

The core exhibits power-law decay of correlations at low temperature.

Results support the feasibility of detecting Luttinger liquid behavior experimentally.

Abstract

As helium-4 is cooled below 2.17 K it undergoes a phase transition to a fundamentally new state of matter known as a superfluid which supports flow without viscosity. This type of dissipationless transport can be observed by forcing helium to travel through a narrow constriction that the normal liquid could not penetrate. Recent experiments have highlighted the feasibility of fabricating smooth pores with nanometer radii, that approach the truly one dimensional limit where it is believed that a system of bosons (like helium-4) may have startlingly different behavior than in three dimensions. The one dimensional system is predicted to have a linear hydrodynamic description known as Luttinger liquid theory, where no type of long range order can be sustained. In the limit where the pore radius is small, Luttinger liquid theory would predict that helium inside the channel behaves as a sort of quasi-supersolid with all correlations decaying as power-law functions of distance at zero temperature. We have performed large scale quantum Monte Carlo simulations of helium-4 inside nanopores of varying radii at low temperature with realistic helium-helium and helium-pore interactions. The results indicate that helium inside the nanopore forms concentric cylindrical shells surrounding a core that can be described via Luttinger liquid theory and provides insights into the exciting possibility of the experimental detection of this intriguing low dimensional state of matter.