Spectra and correlated wave functions of two electrons confined in a quasi-one-dimensional nanostructure

Abstract: The energy spectra and wave functions of two electrons confined by a quasi-one-dimensional Gaussian potential have been calculated for different strength of confinement ω z and anharmonicity by using the quantum chemical full configuration interaction method employing a Cartesian anisotropic Gaussian basis set. The energy spectra for a nearly harmonic Gaussian potential have been studied and analyzed in three regimes of ωz, namely, large (ωz = 5.0) medium (ωz = 1.0), and small (ωz = 0.1). For large and medium … Show more

“…The convergence characteristic for the case of two electrons was given already in Ref. [20] and for the case of three electrons in Ref. [21].…”

“…This indicates that the anharmonicity is large. The extent of anharmonicity may be specified by the parameter α [20] which is defined for the quasione-dimensional quantum dots by…”

“…(2) and (3) have been chosen as one half of the strength of the confinement, ω xy and ω z , respectively, while the exponents for the Gaussian potentials have been determined in the same way as described in a previous study [19]. Since the strength of the confinement for the harmonic-oscillator potential is much larger than that for the Gaussian potential, only functions without nodes along the direction of the harmonic-oscillator potential have been selected and used in the basis sets [18][19][20]. The size of the basis set required for calculating a reliable energy spectrum has been determined by following the convergence of the energies while stepwise increasing its size.…”

“…Energy levels belonging to different polyad quantum numbers and having different spin multiplicities are converging to nearly degenerate levels as the strength of confinement becomes smaller. This convergence is caused by increasingly stronger potential walls of the electron-electron interaction potentials that modify significantly the nodal pattern of the wave function of lower spin states while affecting little the wave function of the highest spin states [20,21].…”

“…The polyad quantum number and its extension can be used to characterize the energy spectra of quasi-one-dimensional quantum dots of two and three electrons for the whole range of the strength of confinement [20,21]. Energy levels belonging to different polyad quantum numbers and having different spin multiplicities are converging to nearly degenerate levels as the strength of confinement becomes smaller.…”

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

“…The convergence characteristic for the case of two electrons was given already in Ref. [20] and for the case of three electrons in Ref. [21].…”

“…This indicates that the anharmonicity is large. The extent of anharmonicity may be specified by the parameter α [20] which is defined for the quasione-dimensional quantum dots by…”

“…(2) and (3) have been chosen as one half of the strength of the confinement, ω xy and ω z , respectively, while the exponents for the Gaussian potentials have been determined in the same way as described in a previous study [19]. Since the strength of the confinement for the harmonic-oscillator potential is much larger than that for the Gaussian potential, only functions without nodes along the direction of the harmonic-oscillator potential have been selected and used in the basis sets [18][19][20]. The size of the basis set required for calculating a reliable energy spectrum has been determined by following the convergence of the energies while stepwise increasing its size.…”

“…Energy levels belonging to different polyad quantum numbers and having different spin multiplicities are converging to nearly degenerate levels as the strength of confinement becomes smaller. This convergence is caused by increasingly stronger potential walls of the electron-electron interaction potentials that modify significantly the nodal pattern of the wave function of lower spin states while affecting little the wave function of the highest spin states [20,21].…”

“…The polyad quantum number and its extension can be used to characterize the energy spectra of quasi-one-dimensional quantum dots of two and three electrons for the whole range of the strength of confinement [20,21]. Energy levels belonging to different polyad quantum numbers and having different spin multiplicities are converging to nearly degenerate levels as the strength of confinement becomes smaller.…”

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

Field induced transient current in one-dimensional nanostructure

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