The diffusion Monte Carlo method with symmetry-based state selection is used to calculate the quantum energy states of H2+ confined into potential barriers of atomic dimensions (a model for these ions in solids). Special solutions are employed, permitting one to obtain satisfactory results with rather simple native code. As a test case, 2πu and 2Πg states of H2+ ions under spherical confinement are considered. The results are interpreted using the correlation of H2+ states to atomic orbitals of H atoms lying on the confining surface and perturbation calculations. The method is straightforwardly applied to cavities of any shape and different hydrogen plasma species (at least one-electron ones, including H) for future studies with real crystal symmetries.
Quantum states of confined hydrogen plasma species: Monte Carlo calculations
MICCA LONGO, GAIA;LONGO, Savino;
2015-01-01
Abstract
The diffusion Monte Carlo method with symmetry-based state selection is used to calculate the quantum energy states of H2+ confined into potential barriers of atomic dimensions (a model for these ions in solids). Special solutions are employed, permitting one to obtain satisfactory results with rather simple native code. As a test case, 2πu and 2Πg states of H2+ ions under spherical confinement are considered. The results are interpreted using the correlation of H2+ states to atomic orbitals of H atoms lying on the confining surface and perturbation calculations. The method is straightforwardly applied to cavities of any shape and different hydrogen plasma species (at least one-electron ones, including H) for future studies with real crystal symmetries.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
