Fluctuations in quantum dot charging energy
Abstract
We show that quasi-periodic fluctuations in the charging energy EC of small, chaotic quantum dots result from strongly scarred states which are the remnant of periodic orbits in the classical confining potential. We perform self-consistent, density functional and spin density functional calculations for the dots used in the recent experimental studies of Sivan et al. [PRL 77, 1123 (1996)]. We directly compute the direct Coulomb matrix elements Wpq, screened by the gates, between self-consistent states. We show that diagonal elements (denoted Up) are uniformly larger than off diagonal elements, resulting in spin polarization of the dot. We show that strongly scarred states, which are quasi-one dimensional, have particularly large values of Up which causes them to remain, partially occupied, at the Fermi surface as gate voltage Vg is swept and more homogeneous, ``chaotic'' states pass through. We show that ultimate double-filling of these scars results in large upward fluctuations of EC. In addition, we show that Vg dependence of capacitances and level energies substantially enhances fluctuations in the gate voltage spacing dVg of Coulomb oscillations, as compared to and distinct from fluctuations in the ``inverse compressibility'' (i.e. EC). Moreover, these dependences modify the distribution of dVg fluctuations so that purely upward fluctuations of EC produce symmetric fluctuations in dVg. Consequently, gate voltage fluctuations (normalized by the appropriate capacitance ratio) are substantially greater than the single particle level spacing, Delta, but, as we show by direct calculation, their temperature T scaling is consistent with Delta/T and not EC/T, in complete agreement with experiment.
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