Testing standard basis sets for direct ionizations: H+ + H at ELab =0.1–100keV

Testing standard basis sets for direct ionizations: H+ + H at ELab =0.1–100keV

With the simplest‐level electron nuclear dynamics (SLEND) method, we test standard Slater‐type‐orbital/contracted‐Gaussian‐functions (STO/CGFs) basis sets for the simulation of direct ionizations (DIs), charge transfers (CTs), and target excitations (TEs) in H+ + H at ELab = 0.1–100 keV. SLEND is a...

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Veröffentlicht in:Journal of computational chemistry 2024-04, Vol.45 (10), p.671-682
Hauptverfasser: Kim, Hyunsik, Morales, Jorge A
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Charge transfer
Electrons
Simulation
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description With the simplest‐level electron nuclear dynamics (SLEND) method, we test standard Slater‐type‐orbital/contracted‐Gaussian‐functions (STO/CGFs) basis sets for the simulation of direct ionizations (DIs), charge transfers (CTs), and target excitations (TEs) in H+ + H at ELab = 0.1–100 keV. SLEND is a time‐dependent, variational, on‐the‐fly, and nonadiabatic method that treats nuclei and electrons with classical dynamics and a Thouless single‐determinantal state, respectively. While previous tests for CTs and TEs exist, this is the first SLEND/STO/CGFs test for challenging DIs. Spin‐orbitals with negative/positive energies are treated as bound/unbound states for bound‐to‐bound (CT and TE) and bound‐to‐unbound (DI) transitions. SLEND/STO/CGFs simulations correctly reproduce all the features of DIs, CTs and TEs over all the considered impact parameters and energies. SLEND/STO/CGFs simulations correctly predict CT integrals cross‐sections (ICSs) over all the considered energies and predict satisfactory DI and TE ICSs within some energy ranges. Strategies to improve SLEND/STO/CGFs for DI predictions are discussed.
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SLEND is a time‐dependent, variational, on‐the‐fly, and nonadiabatic method that treats nuclei and electrons with classical dynamics and a Thouless single‐determinantal state, respectively. While previous tests for CTs and TEs exist, this is the first SLEND/STO/CGFs test for challenging DIs. Spin‐orbitals with negative/positive energies are treated as bound/unbound states for bound‐to‐bound (CT and TE) and bound‐to‐unbound (DI) transitions. SLEND/STO/CGFs simulations correctly reproduce all the features of DIs, CTs and TEs over all the considered impact parameters and energies. SLEND/STO/CGFs simulations correctly predict CT integrals cross‐sections (ICSs) over all the considered energies and predict satisfactory DI and TE ICSs within some energy ranges. 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Electrons
Simulation
title Testing standard basis sets for direct ionizations: H+ + H at ELab =0.1–100keV
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