L. V. Levitin scite author profile

The superfluid phases of helium-3 ((3)He) are predicted to be strongly influenced by mesoscopic confinement. However, mapping out the phase diagram in a confined geometry has been experimentally challenging. We confined a sample of (3)He within a nanofluidic cavity of precisely defined geometry, cooled it, and fingerprinted the order parameter using a sensitive nuclear magnetic resonance spectrometer. The measured suppression of the p-wave order parameter arising from surface scattering was consistent with the predictions of quasi-classical theory. Controlled confinement of nanofluidic samples provides a new laboratory for the study of topological superfluids and their surface- and edge-bound excitations.

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Surface-Induced Order Parameter Distortion in SuperfluidHe3−BMeasured by Nonlinear NMR

Levitin

Bennett

Surovtsev

et al. 2013

Phys. Rev. Lett.

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The B phase of superfluid 3He is a three-dimensional time-reversal invariant topological superfluid, predicted to support gapless Majorana surface states. We confine superfluid 3He into a thin nanofluidic slab geometry. In the presence of a weak symmetry-breaking magnetic field, we have observed two possible states of the confined 3He-B phase manifold, through the small tipping angle NMR response. Large tipping angle nonlinear NMR has allowed the identification of the order parameter of these states and enabled a measurement of the surface-induced gap distortion. The results for two different quasiparticle surface scattering boundary conditions are compared with the predictions of weak-coupling quasiclassical theory. We identify a textural domain wall between the two B phase states, the edge of which at the cavity surface is predicted to host gapless states, protected in the magnetic field.

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Longitudinal NMR and spin states in the A-like phase of 3He in aerogel

et al. 2006

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The A-B transition in superfluid helium-3 under confinement in a thin slab geometry

Zhelev¹,

Abhilash²,

Smith³

et al. 2017

Nat Commun

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The influence of confinement on the phases of superfluid helium-3 is studied using the torsional pendulum method. We focus on the transition between the A and B phases, where the A phase is stabilized by confinement and a spatially modulated stripe phase is predicted at the A–B phase boundary. Here we discuss results from superfluid helium-3 contained in a single 1.08-μm-thick nanofluidic cavity incorporated into a high-precision torsion pendulum, and map the phase diagram between 0.1 and 5.6 bar. We observe only small supercooling of the A phase, in comparison to bulk or when confined in aerogel, with evidence for a non-monotonic pressure dependence. This suggests that an intrinsic B-phase nucleation mechanism operates under confinement. Both the phase diagram and the relative superfluid fraction of the A and B phases, show that strong coupling is present at all pressures, with implications for the stability of the stripe phase.

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L. V. Levitin

Phase Diagram of the Topological Superfluid ³ He Confined in a Nanoscale Slab Geometry

Surface-Induced Order Parameter Distortion in SuperfluidHe3−BMeasured by Nonlinear NMR

Longitudinal NMR and spin states in the A-like phase of 3He in aerogel

The A-B transition in superfluid helium-3 under confinement in a thin slab geometry

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L. V. Levitin

Phase Diagram of the Topological Superfluid 3 He Confined in a Nanoscale Slab Geometry

Surface-Induced Order Parameter Distortion in SuperfluidHe3−BMeasured by Nonlinear NMR

Longitudinal NMR and spin states in the A-like phase of 3He in aerogel

The A-B transition in superfluid helium-3 under confinement in a thin slab geometry

Contact Info

Product

Resources

About

Phase Diagram of the Topological Superfluid ³ He Confined in a Nanoscale Slab Geometry