Duality symmetry and its breakdown in the vicinity of the superconductor–insulator transition

Ovadia, M.; Kalok, David; Sacépé, Benjamin; Shahar, D.

doi:10.1038/nphys2636

Cited by 46 publications

(64 citation statements)

References 30 publications

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“…For each device, R (B, T, E = 0) data were used to test the scaling prediction, by varying B at small increments at fixed T. In figure 5, the T-scaling of R for the film is shown. A good visual collapse of the data is obtained for zν=1.12, which is close to the previous findings 6,35 . For the wires, R flattens and become T independent on either side of B c [figure2(b)], as low-T is approached.…”

Section: Resultssupporting

confidence: 90%

“…In the superconducting side of the Btuned SIT, the power law is consistent with the collective pinning model of transport 22,34,36 and indicate the role played by interacting bosons (vortices) in transport. The existence of the power law behavior above B c , suggest that vortex transport might be important in the insulating state 34,35 . A quantum critical point is known to separate ground states with different symmetry.…”

Section: Resultsmentioning

confidence: 98%

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Finite-size effects in amorphous indium oxide

et al. 2016

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We study the low temperature magneto-transport properties of several highly disordered amorphous Indium oxide(a:InO) samples. Simultaneously fabricated devices comprising a 2-dimensional (2D) film and 10 µm long wires of different widths were measured to investigate the effect of size as we approach the 1D limit, which is around 4 times the correlation length, and happens to be around 100 nm for a:InO. The film and the wires showed magnetic field (B) induced superconductor to insulator transition (SIT). In the superconducting side, the resistance increased with decrease in wire width, whereas, an opposite trend is observed in the insulating side. We find that this effect can be explained in light of charge-vortex duality picture of the SIT. Resistance of the 2D film follows an activated behavior over the temperature (T ), whereas, the wires show a crossover from the high-T activated to a T -independent behavior. At high temperature regime the wires' resistance follow the film's until they deviate and became independent of T . We find that temperature at which this deviation occurs evolve with magnetic field and the width of the wire, which show the effect of finite size on the transport.

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Section: Resultssupporting

confidence: 90%

Section: Resultsmentioning

confidence: 98%

Finite-size effects in amorphous indium oxide

et al. 2016

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“…In superconducting films close to the critical point, the low-bias resistance isotherms follow the finite size scaling model 4,5,16,17 , which gives strong indication that the SIT in films is also a quantum phase transition (QPT). In addition, it has been shown that in amorphous MoGe 5 and NbN 17 films, nonlinear differential resistance measured as a function of magnetic field at several finite bias voltages also scales both on the insulating and superconducting sides of the SIT.…”

Section: Introductionmentioning

confidence: 92%

Zero-bias anomaly in homogeneously disordered MoGe nanowires undergoing a superconductor-insulator transition

Kim

Rogachev

2016

Phys. Rev. B

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“…Previous studies have examined evidence for duality (18,19) from resistivity measurements, but have not examined the full conductivity tensor across the transition. In this paper we provide insights concerning the nature of the H-SIT in highly disordered films, using new measurements of the full resistivity tensor across the quantum transition.…”

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confidence: 99%

Self-duality and a Hall-insulator phase near the superconductor-to-insulator transition in indium-oxide films

Breznay

Steiner

Kivelson

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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We combine measurements of the longitudinal (ρ xx ) and Hall (ρ xy ) resistivities of disordered 2D amorphous indium-oxide films to study the magnetic-field tuned superconductor-to-insulator transition (H-SIT) in the T → 0 limit. At the critical field, H c , the full resistivity tensor is T independent with ρ xx (H c ) = h/ 4e 2 and ρ xy (H c ) = 0 within experimental uncertainty in all films (i.e., these appear to be "universal" values); this is strongly suggestive that there is a particlevortex self-duality at H = H c . The transition separates the (presumably) superconducting state at H < H c from a "Hall-insulator" phase in which ρ xx → ∞ as T → 0 whereas ρ xy approaches a nonzero value smaller than its "classical value" H/ nec; i.e., 0 < ρ xy < H/ nec. A still higher characteristic magnetic field, H c * > H c , at which the Hall resistance is T independent and roughly equal to its classical value, ρ xy ≈ H/ nec, marks an additional crossover to a high-field regime (probably to a Fermi insulator) in which ρ xy > H/ nec and possibly diverges as T → 0. We also highlight a profound analogy between the H-SIT and quantum-Hall liquid-to-insulator transitions (QHIT).superconductor-insulator transition | quantum phase transition | self-duality | Hall insulator Q uantum phase transitions (QPTs) occur at zero temperature (T = 0) as a quantum control parameter is varied. Where the transition is continuous, quantum critical phenomena are expected to give rise to universal physics that can be analyzed using a straightforward scaling theory. The magnetic-field tuned transition between superconducting and insulating ground states in 2D conductors is a particularly attractive exemplar of a QPT because the magnetic field can be continuously tuned, allowing a detailed scaling analysis of the QPTs and explorations of the ground-state phases proximate to criticality (1-9). However, the exact nature of the insulating and superconducting states above and below the magnetic-field tuned superconductor-to-insulator transition (H-SIT) and a satisfactory description of the transition between them are still lacking.The conventional picture of T → 0 phases of a 2D electron fluid in the presence of disorder is based on the assumption that the only stable phases are superconducting or insulating (or, in a magnetic field, quantum Hall liquid phases). In contrast, studies of films near the H-SIT have suggested the existence of several unexpected new ground-state phases in films that superconduct at zero field. In weakly disordered films (with normal state resistivity small compared with the quantum of resistance, ρ N h=e 2 ), the superconducting state gives way to an "anomalous metallic phase" with a resistivity that extrapolates to a nonzero value, 0 < ρðT → 0, HÞ ρ N

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Duality symmetry and its breakdown in the vicinity of the superconductor–insulator transition

Cited by 46 publications

References 30 publications

Finite-size effects in amorphous indium oxide

Finite-size effects in amorphous indium oxide

Zero-bias anomaly in homogeneously disordered MoGe nanowires undergoing a superconductor-insulator transition

Self-duality and a Hall-insulator phase near the superconductor-to-insulator transition in indium-oxide films

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