Self Duality and a possible Hall-insulator phase near the superconductor-to-insulator transition in two-dimensional indium-oxide films

Abstract

We combine measurements of the longitudinal (xx) and Hall (xy) resistivities of disordered two dimensional 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, Hc, the full resistivity tensor is T independent with xx(Hc) = h/4e2 and xy(Hc)=0 within experimental uncertainty in all films (i.e. these appear to be "universal" values), this is strongly suggestive that there is a particle-vortex self-duality at H=Hc. The transition separates the (presumably) superconducting state at H<Hc from a "Hall-insulator" phase in which xx ∞ as T 0 while xy approaches a non-zero value smaller than its "classical value" H/nec, i.e. 0<xy<H/nec. A still higher characteristic magnetic field, Hc*> Hc, at which the Hall resistance is T independent and roughly equal to its classical value, xy≈ H/nec, marks an additional crossover to a highfield regime (probably to a Fermi-insulator) in which 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).