Core Structure and Non-Abelian Reconnection of Defects in a Biaxial Nematic Spin-2 Bose-Einstein Condensate

Borgh, Magnus O.; Ruostekoski, Janne

doi:10.1103/physrevlett.117.275302

Cited by 33 publications

(35 citation statements)

References 65 publications

(147 reference statements)

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“…Many such high-spin Bose-Einstein condensates, including rubidium (Stamper-Kurn and Ueda, 2013), chromium (Griesmaier et al, 2005), erbium (Aikawa et al, 2012), strontium (Stellmer et al, 2009), ytterbium (Takasu et al, 2003 and dysprosium (Lian et al, 2012;Lu et al, 2011) atoms have already been produced. Such spinor Bose-Einstein condensates may host non-Abelian fractional vortices (Borgh and Ruostekoski, 2016;Huhtamäki et al, 2009;Kobayashi et al, 2009;Kobayashi and Ueda, 2016;Mawson et al, 2017;Semenoff and Zhou, 2007) whose topological invariants (Mermin, 1979;Thouless, 1998) are described by finite non-Abelian symmetry groups. Notwithstanding the finiteness of their underlying symmetry groups, such condensates may possess experimentally realizable ground states with non-Abelian vortex anyons with the capacity to be harnessed for topological quantum computation.…”

Section: Physical Realizationmentioning

confidence: 99%

Introduction to topological quantum computation with non-Abelian anyons

Field

Simula

2018

Quantum Sci. Technol.

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Topological quantum computers promise a fault tolerant means to perform quantum computation. Topological quantum computers use particles with exotic exchange statistics called non-Abelian anyons, and the simplest anyon model which allows for universal quantum computation by particle exchange or braiding alone is the Fibonacci anyon model. One classically hard problem that can be solved efficiently using quantum computation is finding the value of the Jones polynomial of knots at roots of unity. We aim to provide a pedagogical, self-contained, review of topological quantum computation with Fibonacci anyons, from the braiding statistics and matrices to the layout of such a computer and the compiling of braids to perform specific operations. Then we use a simulation of a topological quantum computer to explicitly demonstrate a quantum computation using Fibonacci anyons, evaluating the Jones polynomial of a selection of simple knots. In addition to simulating a modular circuit-style quantum algorithm, we also show how the magnitude of the Jones polynomial at specific points could be obtained exactly using Fibonacci or Ising anyons. Such an exact algorithm seems ideally suited for a proof of concept demonstration of a topological quantum computer.

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Section: Physical Realizationmentioning

confidence: 99%

Introduction to topological quantum computation with non-Abelian anyons

Field

Simula

2018

Quantum Sci. Technol.

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“…In a biaxial-nematic spin-2 BEC, the related but simpler dihedral-4 point-group symmetry already leads to highly complex core structures of a half-quantum vortex [32]. As a result of the D 6 symmetry, the spin-3 A-phase vortices are also non-Abelian (i.e., the different topological charges do not all commute), leading to the restricted reconnection dynamics of vortices also predicted in the cyclic and biaxial-nematic spin-2 phases [32,70]. The A-phase D 6 order parameter supports a halfquantum vortex where the π winding of the condensate phase is compensated by a π/3 spin rotation.…”

Section: B Precession-averaged Dipolar Interaction In a Magnetic Fieldmentioning

confidence: 99%

“…The DI gives rise to a new spin-dependent healing length, adding to the hierarchy of characteristic length scales arising form the contact interaction to determine the structure of singular-vortex cores [27,32,56]. We analyze the interplay of these length scales and demonstrate how the size of a singular-vortex core is determined by the shorter of the spin-dependent healing lengths when the DI and contact interaction both restrict breaking of the ground-state spin condition (the ground-state phase of the bulk superfluid), e.g., in the ferromagnetic (FM) spin-1 BEC.…”

Section: Introductionmentioning

confidence: 99%

Internal structure and stability of vortices in a dipolar spinor Bose-Einstein condensate

2017

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We demonstrate how dipolar interactions can have pronounced effects on the structure of vortices in atomic spinor Bose-Einstein condensates and illustrate generic physical principles that apply across dipolar spinor systems. We then find and analyze the cores of singular vortices with non-Abelian charges in the point-group symmetry of a spin-3 52Cr condensate. Using a simpler model system, we analyze the underlying dipolar physics and show how a characteristic length scale arising from the magnetic dipolar coupling interacts with the hierarchy of healing lengths of the s-wave scattering and leads to simple criteria for the core structure: When the interactions both energetically favor the ground-state spin condition, such as in the spin-1 ferromagnetic phase, the size of singular vortices is restricted to the shorter spin-dependent healing length (s-wave or dipolar). Conversely, when the interactions compete (e.g., in the spin-1 polar phase), we find that the core of a singular vortex is enlarged by increasing dipolar coupling. We further demonstrate how the spin alignment arising from the interaction anisotropy is manifest in the appearance of a ground-state spin-vortex line that is oriented perpendicularly to the condensate axis of rotation, as well as in potentially observable internal core spin textures. We also explain how it leads to an interaction-dependent angular momentum in nonsingular vortices as a result of competition with rotation-induced spin ordering. When the anisotropy is modified by a strong magnetic field, we show how it gives rise to a symmetry-breaking deformation of a vortex core into a spin-domain wall

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“…Spin-2 BECs exhibit two magnetic phases that have no spin-1 counterparts, namely, the biaxial nematic (BN) and the cyclic (C) phases. To date, research on topological defects in these phases has been restricted to the study of surface solitons [15] and non-Abelian vortices, the latter of which exhibit noncommutative reconnection dynamics [40][41][42] predicted to result in exotic quantum turbulence [43]. However, there have been no detailed studies of three-dimensional skyrmions in these phases.…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional skyrmions in spin-2 Bose–Einstein condensates

et al. 2018

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We introduce topologically stable three-dimensional skyrmions in the cyclic and biaxial nematic phases of a spin-2 Bose-Einstein condensate. These skyrmions exhibit exceptionally high mapping degrees resulting from the versatile symmetries of the corresponding order parameters. We show how these structures can be created in existing experimental setups and study their temporal evolution and lifetime by numerically solving the three-dimensional Gross-Pitaevskii equations for realistic parameter values. Although the biaxial nematic and cyclic phases are observed to be unstable against transition towards the ferromagnetic phase, their lifetimes are long enough for the skyrmions to be imprinted and detected experimentally.

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Core Structure and Non-Abelian Reconnection of Defects in a Biaxial Nematic Spin-2 Bose-Einstein Condensate

Cited by 33 publications

References 65 publications

Introduction to topological quantum computation with non-Abelian anyons

Introduction to topological quantum computation with non-Abelian anyons

Internal structure and stability of vortices in a dipolar spinor Bose-Einstein condensate

Three-dimensional skyrmions in spin-2 Bose–Einstein condensates

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