Impurity Quantum Monte Carlo Calculations of Persistent Currents

Abstract

<p>Recent interest in the fundamental physics of the Kondo effect has been driven by the observation of Kondo physics in mesoscopic systems such as quantum dots [1, 2] and carbon nanotubes [3], which can act analogously to magnetic impurities in a bulk metal. Highly tunable mesoscopic systems such as these present the possibility of observing the controversial Kondo length scale εK associated with the cloud of conduction electrons that screen the spin of the impurity [4]. This plays a similar role in scaling theories as the Kondo temperature Tk.</p> <p>One proposal [5] for detecting this length scale is to measure the finite-size dependence of persistent currents in an isolated conducting ring coupled to a quantum dot. The screening cloud should be 'trapped' in the closed system, and will not form if the size of the ring L is much smaller than εK. In particular, the current in the Kondo regime should be a universal scaling function j = L^-1 f(Φ, L/εK, T/Tk) (here Φ is the applied flux) [6, 7]. Considerable disagreement has arisen in the theoretical estimates of these persistent currents as different analytical treatments yield contradictory predictions [6, 8, 9, 10].</p> <p>This thesis presents a new Quantum Monte Carlo (QMC) technique for measuring persistent currents in such systems, based on the Hirsch-Fye Impurity QMC algorithm [11] which is ideally suited to treating systems with a single impurity such as the quantum dot. The algorithm provides exact numerical results at finite temperatures. The complexity of the algorithm does not scale directly with the size of the system, making it particularly attractive for investigating a wide range of system sizes.</p>