Scanning SQUID microscopy of vortex clusters in multiband superconductors

Nishio, Toshiyuki; Dao, Vu Hung; Chen, Qinghua; Chibotaru, Liviu F.; Kadowaki, K.; Moshchalkov, Victor

doi:10.1103/physrevb.81.020506

Cited by 81 publications

(106 citation statements)

References 26 publications

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“…Multiple effective coherence lengths lead to a semi-Meissner state whereby a combination of long-range attractive and short-range repulsive intervortex interactions give rise to clusters of vortices nucleating within a Meissner-like state [21]. This behavior was termed type-1.5 superconductivity when reported in MgB 2 [22][23][24]. Nonpairwise interactions may also lead to tendencies to form chainlike or irregular clusters [20] not unlike those observed in some surface probe experiments [15,16].…”

Section: Introductionmentioning

confidence: 99%

Muon-spin rotation measurements of the vortex state inSr2RuO4: Type-1.5 superconductivity, vortex clustering, and a crossover from a triangular to a square vortex lattice

et al. 2014

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Muon-spin rotation has been used to probe the vortex state in Sr 2 RuO 4 . At moderate fields and temperatures a lattice of triangular symmetry is observed, crossing over to a lattice of square symmetry with increasing field and temperature. At lower fields it is found that there are large regions of the sample that are completely free from vortices which grow in volume as the temperature falls. Importantly this is accompanied by increasing vortex density and increasing disorder within the vortex-cluster-containing regions. Both effects are expected to result from the strongly temperature-dependent long-range vortex attractive forces arising from the multiband chiral-order superconductivity.

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Section: Introductionmentioning

confidence: 99%

Muon-spin rotation measurements of the vortex state inSr2RuO4: Type-1.5 superconductivity, vortex clustering, and a crossover from a triangular to a square vortex lattice

et al. 2014

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“…However, practical atom chip schemes for interferometry with a wide dynamic range and versatile geometries are still very much sought after [23][24][25][26][27][28] . Such schemes may enable, for example, sensitive probing of classical or quantum properties of solid-state nanoscale devices and surface physics (for example, refs [29][30][31][32][33]. This is expected to enhance considerably the power of non-interferometric measurements with ultracold atoms on a chip, which have already contributed, for example, to the study of long-range order of current fluctuations in thin films 34 , the Casimir-Polder force [35][36][37][38] and Johnson noise from a surface 39 .…”

mentioning

confidence: 99%

Coherent Stern–Gerlach momentum splitting on an atom chip

2013

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In the Stern-Gerlach effect, a magnetic field gradient splits particles into spatially separated paths according to their spin projection. The idea of exploiting this effect for creating coherent momentum superpositions for matter-wave interferometry appeared shortly after its discovery, almost a century ago, but was judged to be far beyond practical reach. Here we demonstrate a viable version of this idea. Our scheme uses pulsed magnetic field gradients, generated by currents in an atom chip wire, and radio-frequency Rabi transitions between Zeeman sublevels. We transform an atomic Bose-Einstein condensate into a superposition of spatially separated propagating wavepackets and observe spatial interference fringes with a measurable phase repeatability. The method is versatile in its range of momentum transfer and the different available splitting geometries. These features make our method a good candidate for supporting a variety of future applications and fundamental studies.

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“…6(d). These simulations might explain why the disordered chains or stripes were frequently observed [10,11,15], while the ordered line state was seldom found in experiments.…”

Section: Effects Of Film Thickness and Disorders On Vortex Statesmentioning

confidence: 99%

“…Although large amount of experimental and theoretical efforts in this field has been made [10][11][12][13][14][15][16][17][18], the nature of the vortex clustering in multiband superconductors is still an intensely controversial issue now [17,[19][20][21][22]. In principle, the vortex cluster formation means that there might exist some type of attraction between vortices in addition to repulsion.…”

Section: Introductionmentioning

confidence: 99%

Simulation of the phase diagram of magnetic vortices in two-dimensional superconductors: evidence for vortex chain formation

Xu¹,

Fangohr²,

Gu³

et al. 2014

J. Phys.: Condens. Matter

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We study the superconducting vortex states induced by the interplay of long-range Pearl repulsion and short-range intervortex attraction using Langevin dynamics simulation. We show that at low temperature the vortices form an ordered Abrikosov lattice both in low and high fields. The vortices show distinctive modulated structures at intermediate fields depending on the effective intervortex attraction: ordered vortex chain and Kogame-like vortex structures for weak attraction; bubble, stripe and antibubble lattices for strong attraction. Moreover, in the regime of the chain state, the vortices display structural transitions from chain to labyrinthine (or disordered chain) and/or to disordered state depending on the strength of disorders.

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Scanning SQUID microscopy of vortex clusters in multiband superconductors

Cited by 81 publications

References 26 publications

Muon-spin rotation measurements of the vortex state inSr2RuO4: Type-1.5 superconductivity, vortex clustering, and a crossover from a triangular to a square vortex lattice

Muon-spin rotation measurements of the vortex state inSr2RuO4: Type-1.5 superconductivity, vortex clustering, and a crossover from a triangular to a square vortex lattice

Coherent Stern–Gerlach momentum splitting on an atom chip

Simulation of the phase diagram of magnetic vortices in two-dimensional superconductors: evidence for vortex chain formation

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