The Energy Level Structure of Low-dimensional Multi-electron Quantum Dots

Sako, Takeshi; Paldus, Josef; Diercksen, Geerd H. F.

doi:10.1016/s0065-3276(09)00709-6

Cited by 17 publications

(29 citation statements)

References 41 publications

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“…Therefore, the large mixing of these two configurations in the strong confinement regime indicates an improper description of the states of quantum dots that is based on an independent electron model with Hartree-Fock orbitals. In order to properly describe the states in the v p = 2 manifold, appropriate assignments of the normal modes of electrons are required [33,34,61]; these are introduced in the next section.…”

Section: A Energy Spectrummentioning

confidence: 99%

Origin of Hund’s multiplicity rule in quasi-two-dimensional two-electron quantum dots

2010

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The origin of Hund's multiplicity rules has been studied for a system of two electrons confined by a quasitwo-dimensional harmonic-oscillator potential by relying on a full configuration interaction wave function and Cartesian anisotropic Gaussian basis sets. In terms of appropriate normal-mode coordinates the wave function factors into a product of the center-of -mass and the internal components. The 1 u singlet state and the 3 u triplet state represent the energetically lowest pair of states to which Hund's multiplicity rule applies. They are shown to involve excitations into different degrees of freedom, namely, into the center-of-mass angular mode and the internal angular mode for the singlet and triplet states, respectively. The presence of an angular nodal line in the internal space allows then the triplet state to avoid the singularity in the electron-electron interaction potential, leading to the energy lowering of the triplet state relative to its counterpart singlet state.

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Section: A Energy Spectrummentioning

confidence: 99%

Origin of Hund’s multiplicity rule in quasi-two-dimensional two-electron quantum dots

2010

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“…This difference in the shape of the internal wave functions of these two systems can be understood by considering the spatial extent of the relevant one-electron orbitals: In the case of the He-like atomic systems there is a large difference in the size of the (1s) and (2p) orbitals, since they belong to different principal shells of n = 1 and n = 2. On the other hand, in the case of quantum dots, the (0σ g ) and (1π u ) orbitals also reside in different shells of v p = 0 and 1 where the polyad quantum number v p accounts for the shell structure of the two-dimensional harmonic oscillator [40,45,32,46], yet their spatial extent is of the same order of magnitude since the classical turning points of the harmonic oscillator along the x axis, for example, are |x c | = 1 and √ 3 for v = 0 and 1, respectively.…”

Section: Internal Wave Functionsmentioning

confidence: 99%

Origin of the first Hund rule and the structure of Fermi holes in two-dimensional He-like atoms and two-electron quantum dots

Sako

Paldus

Ichimura

et al. 2012

J. Phys. B: At. Mol. Opt. Phys.

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The lowest singlet-triplet pair of states of the two-electron twodimensional quantum dots and the corresponding pair of states of the two-dimensional helium-like systems have been studied by the full configuration interaction method focusing on the origin of the first Hund rule. The one-and two-electron components of the singlet-triplet energy gap show distinct trends for the systems studied in the regime of small nuclear charge Z n or of small confinement strength ω. The (0σ g)(1π u) singlet state in quantum dots is characterized by a larger electron repulsion than its counterpart triplet state for all values of ω while this relationship gets inverted for the corresponding (1s)(2p) singlet-triplet pair of He-like systems for small values of Z n , such as Z n = 2 or 3. The internal part of the full configuration interaction wave functions has been extracted and visualised in the three-dimensional internal space (r 1 ,r 2 ,φ −) to rationalize the observed trends. The singlet probability density of Helike systems located originally near the Fermi holes is shown to migrate into regions where either r 1 or r 2 are large while the corresponding singlet probability of quantum dots stays close to the Fermi holes. Their differences and their observed trends are rationalized on the basis of the structure of the genuine and conjugate Fermi holes.

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“…The three-electron quantum dots in different potentials including the harmonic, Coulomb and Gaussian terms were studied in Refs. [13][14][15][16][17][18][19][20][21][22] using different methodologies. In the present work, we consider parabolic and Coulomb terms but present a relatively different mathematical way to treat the problem.…”

Section: Introductionmentioning

confidence: 99%

A Unitary Transformation and Spectrum of a Three-Electron Quantum Dot

2011

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We consider the Hamiltonian of a three-electron quantum dot composed of parabolic confinement plus the Coulomb terms. Instead of using the Jacobi coordinates, we apply a unitary transformation to this system. To avoid the complexity, the Taylor expansion of the effective potential is introduced into the problem and thereby a solution is found for the eigenvalues of the corresponding three-body Schrödinger equation in terms of the Wigner parameter.

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The Energy Level Structure of Low-dimensional Multi-electron Quantum Dots

Cited by 17 publications

References 41 publications

Origin of Hund’s multiplicity rule in quasi-two-dimensional two-electron quantum dots

Origin of Hund’s multiplicity rule in quasi-two-dimensional two-electron quantum dots

Origin of the first Hund rule and the structure of Fermi holes in two-dimensional He-like atoms and two-electron quantum dots

A Unitary Transformation and Spectrum of a Three-Electron Quantum Dot

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