Abstract
We study the effect of Coulomb interaction on the few-electron dynamics in coupled semiconductor quantum dots by exact diagonalization of the few-body Hamiltonian. The oscillation of carriers is strongly affected by the number of confined electrons and by the strength of the interdot correlations. Single-frequency oscillations are found for either uncorrelated or highly correlated states, while multifrequency oscillations take place in the intermediate regime. Moreover, Coulomb interaction renders few-particle oscillations sensitive to perturbations in spatial directions other than that of the tunneling, contrary to the single-particle case. The inclusion of acoustic phonon scattering does not modify the carrier dynamics substantially at short times, but it can damp oscillation modes selectively at long times.
Highlights
Low-dimensional heterostructures enable direct probing of the time evolution of carriers
We study the effect of Coulomb interaction on the few-electron dynamics in coupled semiconductor quantum dots by exact diagonalization of the few-body Hamiltonian
Coupled quantum dotsCQDs, where the number of confined carriers can be controlled experimentally, are a most interesting case as they possess a discrete energy spectrum which stems from the quantum confinement in all three spatial directions, constituting the physical realization of the particle-in-the-box problem
Summary
Low-dimensional heterostructures enable direct probing of the time evolution of carriers. Either single-frequency or multifrequency charge oscillations occur, depending on the strength of the correlations between molecular levels of the CQD.
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