Supercooling of the A phase of 3He

Y. Tian; D.  Lotnyk; A. Eyal; K. Zhang; N.  Zhelev; T.S. Abhilash; A. Chavez; E.N.  Smith; M. Hindmarsh; J. Saunders; E. Mueller; J.M. Parpia

doi:10.1038/s41467-022-35532-7

Supercooling of the A phase of ³He

Y. Tian
, D. Lotnyk
, A. Eyal
, K. Zhang
, N. Zhelev
, T.S. Abhilash
, A. Chavez
, E.N. Smith
, M. Hindmarsh
, J. Saunders
, E. Mueller
, J.M. Parpia^*

^*Corresponding author for this work

BA6201 RF microsystems

Cornell University
Technion-Israel Institute of Technology
University of Helsinki
Northwestern University
Royal Holloway University of London

Research output: Contribution to journal › Article › Scientific › peer-review

6 Citations (Scopus)

Abstract

Because of the extreme purity, lack of disorder, and complex order parameter, the first-order superfluid ³He A–B transition is the leading model system for first order transitions in the early universe. Here we report on the path dependence of the supercooling of the A phase over a wide range of pressures below 29.3 bar at nearly zero magnetic field. The A phase can be cooled significantly below the thermodynamic A–B transition temperature. While the extent of supercooling is highly reproducible, it depends strongly upon the cooling trajectory: The metastability of the A phase is enhanced by transiting through regions where the A phase is more stable. We provide evidence that some of the additional supercooling is due to the elimination of B phase nucleation precursors formed upon passage through the superfluid transition. A greater understanding of the physics is essential before ³He can be exploited to model transitions in the early universe.

Original language	English
Article number	148
Number of pages	9
Journal	Nature Communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-35532-7
Publication status	Published - 10 Jan 2023
MoE publication type	A1 Journal article-refereed

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10.1038/s41467-022-35532-7Licence: CC BY

Cite this

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title = "Supercooling of the A phase of 3He",

abstract = "Because of the extreme purity, lack of disorder, and complex order parameter, the first-order superfluid 3He A–B transition is the leading model system for first order transitions in the early universe. Here we report on the path dependence of the supercooling of the A phase over a wide range of pressures below 29.3 bar at nearly zero magnetic field. The A phase can be cooled significantly below the thermodynamic A–B transition temperature. While the extent of supercooling is highly reproducible, it depends strongly upon the cooling trajectory: The metastability of the A phase is enhanced by transiting through regions where the A phase is more stable. We provide evidence that some of the additional supercooling is due to the elimination of B phase nucleation precursors formed upon passage through the superfluid transition. A greater understanding of the physics is essential before 3He can be exploited to model transitions in the early universe.",

author = "Y. Tian and D. Lotnyk and A. Eyal and K. Zhang and N. Zhelev and T.S. Abhilash and A. Chavez and E.N. Smith and M. Hindmarsh and J. Saunders and E. Mueller and J.M. Parpia",

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TY - JOUR

T1 - Supercooling of the A phase of 3He

AU - Tian, Y.

AU - Lotnyk, D.

AU - Eyal, A.

AU - Zhang, K.

AU - Zhelev, N.

AU - Abhilash, T.S.

AU - Chavez, A.

AU - Smith, E.N.

AU - Hindmarsh, M.

AU - Saunders, J.

AU - Mueller, E.

AU - Parpia, J.M.

PY - 2023/1/10

Y1 - 2023/1/10

N2 - Because of the extreme purity, lack of disorder, and complex order parameter, the first-order superfluid 3He A–B transition is the leading model system for first order transitions in the early universe. Here we report on the path dependence of the supercooling of the A phase over a wide range of pressures below 29.3 bar at nearly zero magnetic field. The A phase can be cooled significantly below the thermodynamic A–B transition temperature. While the extent of supercooling is highly reproducible, it depends strongly upon the cooling trajectory: The metastability of the A phase is enhanced by transiting through regions where the A phase is more stable. We provide evidence that some of the additional supercooling is due to the elimination of B phase nucleation precursors formed upon passage through the superfluid transition. A greater understanding of the physics is essential before 3He can be exploited to model transitions in the early universe.

AB - Because of the extreme purity, lack of disorder, and complex order parameter, the first-order superfluid 3He A–B transition is the leading model system for first order transitions in the early universe. Here we report on the path dependence of the supercooling of the A phase over a wide range of pressures below 29.3 bar at nearly zero magnetic field. The A phase can be cooled significantly below the thermodynamic A–B transition temperature. While the extent of supercooling is highly reproducible, it depends strongly upon the cooling trajectory: The metastability of the A phase is enhanced by transiting through regions where the A phase is more stable. We provide evidence that some of the additional supercooling is due to the elimination of B phase nucleation precursors formed upon passage through the superfluid transition. A greater understanding of the physics is essential before 3He can be exploited to model transitions in the early universe.

UR - https://www.scopus.com/pages/publications/85146104981

U2 - 10.1038/s41467-022-35532-7

DO - 10.1038/s41467-022-35532-7

M3 - Article

C2 - 36627275

SN - 2041-1723

VL - 14

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 148

ER -

Supercooling of the A phase of ³He

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Supercooling of the A phase of ³He