APS March Meeting 2015
Volume 60, Number 1
Monday–Friday, March 2–6, 2015;
San Antonio, Texas
Session J52: Buckley Prize / Apker Award Session
2:30 PM–5:30 PM,
Tuesday, March 3, 2015
Room: Grand Ballroom C2
Abstract ID: BAPS.2015.MAR.J52.2
Abstract: J52.00002 : Buckley Prize Talk: Bosons on the Boundaries: The magnetic field driven superconductor-insulator quantum phase transition
3:06 PM–3:42 PM
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Abstract
Author:
Arthur Hebard
(University of Florida)
Experiments probing the competition between superconductivity and disorder
in two-dimensional (2D) thin-film systems have provided fascinating glimpses
into the physics of superconductor-insulator (S-I) quantum phase transitions
(QPTs). This talk will address the use of externally applied magnetic fields
to tune through the S-I transition of amorphous composite indium oxide
($\alpha $-InOx) thin films prepared at different stages of disorder.
Air-stable $\alpha $-InOx films are particularly advantageous for these
studies: the disorder parameter as measured by the sheet resistance can be
reproducibly controlled during deposition and the films are uniformly
homogeneous out to macroscopic length scales. Temperature-dependent
resistance and current-voltage measurements confirm the power-law decay of
the order-parameter correlation function appropriate to a
Kosterlitz-Thouless description of phase transitions in 2D systems.
Accordingly, the superconducting phase transition temperature Tc is related
to the unbinding of vortex-antivortex pairs either by temperature and/or
disorder. The application of magnetic fields unveils fundamentally different
physics in which, rather than a vortex unbinding transition, a field-tuned
QPT emerges with the signature of a disorder-dependent critical field Bc
that identifies the delocalization and Bose condensation of field-induced
vortices. The concomitant pronounced divergence in resistance, which becomes
increasing sharp as the temperature is lowered, marks the boundary between a
superconductor harboring both Bose condensed Cooper pairs and localized
vortices and an insulator harboring both Bose condensed vortices and
localized Cooper pairs. The data for this putative QPT are well described by
finite temperature scaling theory with critical exponent values accurately
determined. At higher fields there is a second critical field where the
transverse resistance appears to diverge, signaling the unbinding of pairs
with the superconducting energy gap simultaneously going to zero and
localized single electrons dominating to form a Fermi glass
insulator.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2015.MAR.J52.2