Hund’s rule in open-shell states of two-electron systems: From free through confined and screened atoms, to quantum dots

Katriel, Jacob; Montgomery, H. E.; Sarsa, A.; Buendı́a, E.

doi:10.17586/2220-8054-2019-10-1-31-41

Cited by 3 publications

(1 citation statement)

References 19 publications

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“…Recent progress was reviewed by E. Ley-Koo [22] in the field of confined atoms and molecules. Jacob Katriel et.al [23] revised singly-excited and singlet-triplet pairs of states of two-electron spherically symmetric systems that are degenerate in the absence of inter-electronic repulsion. Also, they studied the two-electron quantum dot confined by either a harmonic potential or by an infinite spherical well.…”

Section: Introductionmentioning

confidence: 99%

Applications of the Variational Quantum Monte Carlo Method to the Two-Electron Atoms

Doma¹,

El-Nohy²,

Salem³

2019

IJHEP

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The variational quantum Monte Carlo method was applied to investigate the ground states of the helium atom and helium like ions with atomic number from 1 to 10 and the first four excited states of the helium atom. Furthermore, the investigation of the ground state of helium, Li + , and Be 2+ in a confined impenetrable spherical box. Moreover, the calculation of the ground state of the helium atom in a strong magnetic field using four simple trial wave functions. The trial wave functions consist of usual orbital hydrogen wave functions multiplied by correlation function. Using four different correlation wave functions, we describe the interaction of the two electrons with each other and having a small number of variational parameters.

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Section: Introductionmentioning

confidence: 99%

Applications of the Variational Quantum Monte Carlo Method to the Two-Electron Atoms

Doma¹,

El-Nohy²,

Salem³

2019

IJHEP

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Building machine learning assisted phase diagrams: Three chemically relevant examples

et al. 2022

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In this work, we present a systematic procedure to build phase diagrams for chemically relevant properties by the use of a semi-supervised machine learning technique called uncertainty sampling. Concretely, we focus on ground state spin multiplicity and chemical bonding properties. As a first step, we have obtained single-eutectic-point-containing solid–liquid systems that have been suitable for contrasting the validity of this approach. Once this was settled, on the one hand, we built magnetic phase diagrams for several Hooke atoms containing a few electrons (4 and 6) trapped in spheroidal harmonic potentials. Changing the parameters of the confinement potential, such as curvature and anisotropy, and interelectronic interaction strength, we have been able to obtain and rationalize magnetic phase transitions flipping the ground state spin multiplicity from singlet (nonmagnetic) to triplet (magnetic) states. On the other hand, Bader’s analysis is performed upon helium dimers confined by spherical harmonic potentials. Covalency is studied using descriptors as the sign for Δ ρ( r C) and H( r C), and the dependency on the degrees of freedom of the system is studied, i.e., potential curvature ω2 and interatomic distance R. As a result, we have observed that there may exist a covalent bond between He atoms for short enough distances and strong enough confinement. This machine learning procedure could, in principle, be applied to the study of other chemically relevant properties involving phase diagrams, saving a lot of computational resources.

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He atom in a quantum dot: Structural, entanglement, and information-theoretical measures

2022

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Hund’s rule in open-shell states of two-electron systems: From free through confined and screened atoms, to quantum dots

Cited by 3 publications

References 19 publications

Applications of the Variational Quantum Monte Carlo Method to the Two-Electron Atoms

Applications of the Variational Quantum Monte Carlo Method to the Two-Electron Atoms

Building machine learning assisted phase diagrams: Three chemically relevant examples

He atom in a quantum dot: Structural, entanglement, and information-theoretical measures

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