Interaction effects in non-Hermitian models of vortex physics

A. I. Larkin; C. Mudry; D. Finotello; D. K. K. Lee; D. R. Nelson; D. R. Nelson; D. R. Nelson; D. R. Nelson; D. R. Nelson; D. S. Fisher; D. S. Fisher; David R. Nelson; G. Blatter; J. A. Hertz; J. D. Reppy; K. B. Efetov; K. G. Singh; K. Huang; Kihong Kim; L. Civale; M. E. Fisher; M. H. W. Chan; M. Ma; M. P. A. Fisher; M. P. A. Fisher; M. P. A. Fisher; N. Hatano; N. Hatano; N. Hatano; N. M. Hugenholtz; N. M. Shnerb; N. N. Bogoliubov; N. V. Popov; P. B. Weichman; P. W. Brouwer; R. A. Lehrer; R. C. Budhani; R. T. Scalettar; S. Zhang; T. Giamarchi; T. Giamarchi; T. Giamarchi; T. Giamarchi; T. Hwa; U. C. Täuber; W. E. Pickett; W. Krauth

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Interaction effects in non-Hermitian models of vortex physics

Abstract

Vortex lines in superconductors in an external magnetic field slightly tilted from randomly-distributed parallel columnar defects can be modeled by a system of interacting bosons in a non-Hermitian vector potential and a random scalar potential. We develop a theory of the strongly-disordered non-Hermitian boson Hubbard model using the Hartree-Bogoliubov approximation and apply it to calculate the complex energy spectra, the vortex tilt angle and the tilt modulus of (1+1)-dimensional directed flux line systems. We construct the phase diagram associated with the flux-liquid to Bose-glass transition and find that, close to the phase boundary, the tilted flux liquid phase is characterized by a band of localized excitations, with two mobility edges in its low-energy spectrum.Comment: 19 pages, 19 figures, To appear in Phys. Rev.

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Last time updated on 05/06/2019