Impurity effects in few-electron quantum dots: Incipient Wigner molecule regime
Abstract
Numerically exact path-integral Monte Carlo data are presented for N≤ 10 strongly interacting electrons confined in a 2D parabolic quantum dot, including a defect to break rotational symmetry. Low densities are studied, where an incipient Wigner molecule forms. A single impurity is found to cause drastic effects: (1) The standard shell-filling sequence with magic numbers N=4,6,9, corresponding to peaks in the addition energy (N), is destroyed, with a new peak at N=8, (2) spin gaps decrease, (3) for N=8, sub-Hund's rule spin S=0 is induced, and (4) spatial ordering of the electrons becomes rather sensitive to spin. We also comment on the recently observed bunching phenomenon.
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