Topological superfluid defects with discrete point group symmetries

Y. Xiao; M. O. Borgh; A. Blinova; T. Ollikainen; J. Ruostekoski; D. S. Hall

doi:10.1038/s41467-022-32362-5

Topological superfluid defects with discrete point group symmetries

Y. Xiao, M. O. Borgh, A. Blinova, T. Ollikainen, J. Ruostekoski, D. S. Hall^*

^*Corresponding author for this work

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

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Abstract

Discrete symmetries are spatially ubiquitous but are often hidden in internal states of systems where they can have especially profound consequences. In this work we create and verify exotic magnetic phases of atomic spinor Bose–Einstein condensates that, despite their continuous character and intrinsic spatial isotropy, exhibit complex discrete polytope symmetries in their topological defects. Using carefully tailored spinor rotations and microwave transitions, we engineer singular line defects whose quantization conditions, exchange statistics, and dynamics are fundamentally determined by these underlying symmetries. We show how filling the vortex line singularities with atoms in a variety of different phases leads to core structures that possess magnetic interfaces with rich combinations of discrete and continuous symmetries. Such defects, with their non-commutative properties, could provide unconventional realizations of quantum information and interferometry.

Original language	English
Article number	4635
Pages (from-to)	1-8
Number of pages	8
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-32362-5
Publication status	Published - 8 Aug 2022
MoE publication type	A1 Journal article-refereed

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Topological superfluid defects with discrete point group symmetriesFinal published version, 5.47 MBLicence: CC BY

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title = "Topological superfluid defects with discrete point group symmetries",

abstract = "Discrete symmetries are spatially ubiquitous but are often hidden in internal states of systems where they can have especially profound consequences. In this work we create and verify exotic magnetic phases of atomic spinor Bose–Einstein condensates that, despite their continuous character and intrinsic spatial isotropy, exhibit complex discrete polytope symmetries in their topological defects. Using carefully tailored spinor rotations and microwave transitions, we engineer singular line defects whose quantization conditions, exchange statistics, and dynamics are fundamentally determined by these underlying symmetries. We show how filling the vortex line singularities with atoms in a variety of different phases leads to core structures that possess magnetic interfaces with rich combinations of discrete and continuous symmetries. Such defects, with their non-commutative properties, could provide unconventional realizations of quantum information and interferometry.",

author = "Y. Xiao and Borgh, {M. O.} and A. Blinova and T. Ollikainen and J. Ruostekoski and Hall, {D. S.}",

note = "Funding Information: The authors are grateful for experimental assistance from L. Reuter. D.S.H. and T.O. thank M. M{\"o}tt{\"o}nen for helpful discussions. D.S.H. acknowledges financial support from the National Science Foundation (Grant No. PHY–1806318), J.R. from the UK EPSRC (Grant Nos. EP/P026133/1, EP/S002952/1), and T.O. from the Emil Aaltonen Foundation and the Kaupallisten ja teknillisten tieteiden tukis{\"a}{\"a}ti{\"o} (KAUTE) foundation through its Researchers Abroad program. Publisher Copyright: {\textcopyright} 2022, The Author(s).",

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AU - Hall, D. S.

N1 - Funding Information: The authors are grateful for experimental assistance from L. Reuter. D.S.H. and T.O. thank M. Möttönen for helpful discussions. D.S.H. acknowledges financial support from the National Science Foundation (Grant No. PHY–1806318), J.R. from the UK EPSRC (Grant Nos. EP/P026133/1, EP/S002952/1), and T.O. from the Emil Aaltonen Foundation and the Kaupallisten ja teknillisten tieteiden tukisäätiö (KAUTE) foundation through its Researchers Abroad program. Publisher Copyright: © 2022, The Author(s).

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AB - Discrete symmetries are spatially ubiquitous but are often hidden in internal states of systems where they can have especially profound consequences. In this work we create and verify exotic magnetic phases of atomic spinor Bose–Einstein condensates that, despite their continuous character and intrinsic spatial isotropy, exhibit complex discrete polytope symmetries in their topological defects. Using carefully tailored spinor rotations and microwave transitions, we engineer singular line defects whose quantization conditions, exchange statistics, and dynamics are fundamentally determined by these underlying symmetries. We show how filling the vortex line singularities with atoms in a variety of different phases leads to core structures that possess magnetic interfaces with rich combinations of discrete and continuous symmetries. Such defects, with their non-commutative properties, could provide unconventional realizations of quantum information and interferometry.

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Topological superfluid defects with discrete point group symmetries

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Source Data for Xiao et al., Topological Superfluid Defects with Discrete Point Group Symmetries , Nature Communications 13, 4635 (2022).

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Topological superfluid defects with discrete point group symmetries

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Source Data for Xiao et al., Topological Superfluid Defects with Discrete Point Group Symmetries , Nature Communications 13, 4635 (2022).

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