Your search keyword '"continuum orbitals"' showing total 6 results

1. Autocorrelation function for the chosen effective potential of the diatomic silver anion

Author

Jasik, Patryk, Franz, Jan, Kędziera, Dariusz, Kilich, Tymon, Kozicki, Jan, and Sienkiewicz, Józef

Subjects

rovibrational predissociation, spontaneous electron emission, lifetime, CCSD(T) method, potential energy curves, continuum orbitals, silver dimer, Ag2, quantum dynamics, nonadiabatic coupling

Abstract

The process of a two-channel decay of the diatomic silver anion (Ag2-), namely the spontaneous electron ejection giving Ag2 + e- and the dissociation leading to Ag- + Ag is theoretically studied. The ground state potential energy curves (PECs) of the neutral silver dimer and anionic silver diatomic molecule are calculated using the single reference coupled-cluster method with singles and doubles, and perturbative triples (CCSD(T)). The proper pseudopotential and optimized basis set are used in the presented approach. The interaction energies are corrected for the basis set superposition error (BSSE) by counterpoise (CP) correction. Based on the energies of rovibrational levels calculated using PECs, we are able to characterize the decay channels and compare our results with the experimental data. Having the ground state PEC of an anionic system, we calculate the quantum dynamics (QD) of the dissociation process, which allows us to calculate the widths and lifetimes of highly-lying rovibrational levels. The predissociation lifetimes for quasibond states with small widths of levels are treated with a time-independent approach. We also present the non-adiabatic coupling matrix element between chosen initial and final vibrational states of Ag2- and Ag2, which allow us to estimate the spontaneous electron emission lifetimes.

Published

2021

2. The rovibrational energy levels of the diatomic silver anion and neutral silver dimer

Author

Jasik, Patryk, Franz, Jan, Kędziera, Dariusz, Kilich, Tymon, Kozicki, Jan, and Sienkiewicz, Józef

Subjects

rovibrational predissociation, spontaneous electron emission, lifetime, CCSD(T) method, potential energy curves, continuum orbitals, silver dimer, Ag2, quantum dynamics, nonadiabatic coupling

Abstract

The process of a two-channel decay of the diatomic silver anion (Ag2-), namely the spontaneous electron ejection giving Ag2 + e- and the dissociation leading to Ag- + Ag is theoretically studied. The ground state potential energy curves (PECs) of the neutral silver dimer and anionic silver diatomic molecule are calculated using the single reference coupled-cluster method with singles and doubles, and perturbative triples (CCSD(T)). The proper pseudopotential and optimized basis set are used in the presented approach. The interaction energies are corrected for the basis set superposition error (BSSE) by counterpoise (CP) correction. Based on the energies of rovibrational levels calculated using PECs, we are able to characterize the decay channels and compare our results with the experimental data. Having the ground state PEC of an anionic system, we calculate the quantum dynamics (QD) of the dissociation process, which allows us to calculate the widths and lifetimes of highly-lying rovibrational levels. The predissociation lifetimes for quasibond states with small widths of levels are treated with a time-independent approach. We also present the non-adiabatic coupling matrix element between chosen initial and final vibrational states of Ag2- and Ag2, which allow us to estimate the spontaneous electron emission lifetimes.

Published

2021

3. Potential energy curves and spectroscopic parameters of the diatomic silver anion and neutral silver dimer

Author

Jasik, Patryk, Franz, Jan, Kędziera, Dariusz, Kilich, Tymon, Kozicki, Jan, and Sienkiewicz, Józef

Subjects

rovibrational predissociation, spontaneous electron emission, lifetime, CCSD(T) method, potential energy curves, continuum orbitals, silver dimer, Ag2, quantum dynamics, nonadiabatic coupling

Abstract

The process of a two-channel decay of the diatomic silver anion (Ag2-), namely the spontaneous electron ejection giving Ag2 + e- and the dissociation leading to Ag- + Ag is theoretically studied. The ground state potential energy curves (PECs) of the neutral silver dimer and anionic silver diatomic molecule are calculated using the single reference coupled-cluster method with singles and doubles, and perturbative triples (CCSD(T)). The proper pseudopotential and optimized basis set are used in the presented approach. The interaction energies are corrected for the basis set superposition error (BSSE) by counterpoise (CP) correction. Based on the energies of rovibrational levels calculated using PECs, we are able to characterize the decay channels and compare our results with the experimental data. Having the ground state PEC of an anionic system, we calculate the quantum dynamics (QD) of the dissociation process, which allows us to calculate the widths and lifetimes of highly-lying rovibrational levels. The predissociation lifetimes for quasibond states with small widths of levels are treated with a time-independent approach. We also present the non-adiabatic coupling matrix element between chosen initial and final vibrational states of Ag2- and Ag2, which allow us to estimate the spontaneous electron emission lifetimes.

Published

2021

4. The spontaneous electron emission and rotational predissociation lifetimes of the diatomic silver anion

Author

Jasik, Patryk, Franz, Jan, Kędziera, Dariusz, Kilich, Tymon, Kozicki, Jan, and Sienkiewicz, Józef

Subjects

rovibrational predissociation, spontaneous electron emission, lifetime, CCSD(T) method, potential energy curves, continuum orbitals, silver dimer, Ag2, quantum dynamics, nonadiabatic coupling

Abstract

The process of a two-channel decay of the diatomic silver anion (Ag2-), namely the spontaneous electron ejection giving Ag2 + e- and the dissociation leading to Ag- + Ag is theoretically studied. The ground state potential energy curves (PECs) of the neutral silver dimer and anionic silver diatomic molecule are calculated using the single reference coupled-cluster method with singles and doubles, and perturbative triples (CCSD(T)). The proper pseudopotential and optimized basis set are used in the presented approach. The interaction energies are corrected for the basis set superposition error (BSSE) by counterpoise (CP) correction. Based on the energies of rovibrational levels calculated using PECs, we are able to characterize the decay channels and compare our results with the experimental data. Having the ground state PEC of an anionic system, we calculate the quantum dynamics (QD) of the dissociation process, which allows us to calculate the widths and lifetimes of highly-lying rovibrational levels. The predissociation lifetimes for quasibond states with small widths of levels are treated with a time-independent approach. We also present the non-adiabatic coupling matrix element between chosen initial and final vibrational states of Ag2- and Ag2, which allow us to estimate the spontaneous electron emission lifetimes.

Published

2021

5. Non-adiabatic coupling elements between the diatomic silver anion and neutral silver dimer plus continuum electron

Author

Jasik, Patryk, Franz, Jan, Kędziera, Dariusz, Kilich, Tymon, Kozicki, Jan, and Sienkiewicz, Józef

Subjects

rovibrational predissociation, spontaneous electron emission, lifetime, CCSD(T) method, potential energy curves, continuum orbitals, silver dimer, Ag2, quantum dynamics, nonadiabatic coupling

Abstract

The process of a two-channel decay of the diatomic silver anion (Ag2-), namely the spontaneous electron ejection giving Ag2 + e- and the dissociation leading to Ag- + Ag is theoretically studied. The ground state potential energy curves (PECs) of the neutral silver dimer and anionic silver diatomic molecule are calculated using the single reference coupled-cluster method with singles and doubles, and perturbative triples (CCSD(T)). The proper pseudopotential and optimized basis set are used in the presented approach. The interaction energies are corrected for the basis set superposition error (BSSE) by counterpoise (CP) correction. Based on the energies of rovibrational levels calculated using PECs, we are able to characterize the decay channels and compare our results with the experimental data. Having the ground state PEC of an anionic system, we calculate the quantum dynamics (QD) of the dissociation process, which allows us to calculate the widths and lifetimes of highly-lying rovibrational levels. The predissociation lifetimes for quasibond states with small widths of levels are treated with a time-independent approach. We also present the non-adiabatic coupling matrix element between chosen initial and final vibrational states of Ag2- and Ag2, which allow us to estimate the spontaneous electron emission lifetimes.

Published

2021

6. Spectral properties of minimal‐basis‐set orbitals: Implications for molecular electronic continuum states.

Author

Langhoff, P. W. and Winstead, C. L.

Subjects

*POWER electronics, *PHOTOIONIZATION, *MOLECULAR orbitals, *QUANTUM chemistry

Abstract

Early studies of the electronically excited states of molecules by John A. Pople and coworkers employing ab initio single‐excitation configuration interaction (SECI) calculations helped to simulate related applications of these methods to the partial‐channel photoionization cross sections of polyatomic molecules. The Gaussian representations of molecular orbitals adopted by Pople and coworkers can describe SECI continuum states when sufficiently large basis sets are employed. Minimal‐basis virtual Fock orbitals stabilized in the continuous portions of such SECI spectra are generally associated with strong photoionization resonances. The spectral attributes of these resonance orbitals are illustrated here by revisiting previously reported experimental and theoretical studies of molecular formaldehyde (H2CO) in combination with recently calculated continuum orbital amplitudes. © 2005 Wiley Periodicals, Inc. Int J Quantum Chem, 2005 [ABSTRACT FROM AUTHOR]

Published

2005