Dephasing time and magnetoresistance of two-dimensional electron gas in spatially modulated magnetic fields

Abstract

The effect of a spatially modulated magnetic field on the weak localization phenomenon in two-dimensional electron gas (2DEG) is studied. Both the dephasing time τH and magnetoresistance are shown to reveal a nontrivial behavior as functions of the characteristics of magnetic field profiles. The magnetic field profiles with rather small spatial scales d and modulation amplitudes H0 such that H0d2 c/e are characterized by the dephasing rate τH-1 H02d2. The increase in the flux value H0d2 results in a crossover to a standard linear dependence τH-1 H0. Applying an external homogeneous magnetic field H one can vary the local dephasing time in the system and affect the resulting average transport characteristics. We have investigated the dependence of the average resistance vs the field H for some generic systems and predict a possibility to observe a positive magnetoresistance at not too large H values. The resulting dependence of the resistance vs H should reveal a peak at the field values H H0.