Abstract: Photoionization dynamics of the RNA base uracil is studied in the framework of density functional theory. The photoionization calculations take advantage of a newly developed parallel version of a multicentric approach to the calculation of the electronic continuum spectrum which uses a set of B-spline radial basis functions and a Kohn-Sham density functional Hamiltonian. Both valence and core ionizations are considered. Scattering resonances in selected single-particle ionization channels are classified by the symmetry of the resonant state and the peak energy position in the photoelectron kinetic energy scale; the present results highlight once more the site specificity of core ionization processes. We further suggest that the resonant structures previously characterized in low-energy electron collision experiments are partly shifted below threshold by the photoionization processes. A critical evaluation of the theoretical results provides a guide for future experimental work on similar biosystems.
Density Functional Theory for the photoionization dynamics of Uracil / D., Toffoli; P., Decleva; Gianturco, Francesco Antonio; R. R., Lucchese. - In: THE JOURNAL OF CHEMICAL PHYSICS. - ISSN 0021-9606. - 127:23(2007), pp. 234317-1-234317-8. [10.1063/1.2813349]
Density Functional Theory for the photoionization dynamics of Uracil
GIANTURCO, Francesco Antonio;
2007
Abstract
Abstract: Photoionization dynamics of the RNA base uracil is studied in the framework of density functional theory. The photoionization calculations take advantage of a newly developed parallel version of a multicentric approach to the calculation of the electronic continuum spectrum which uses a set of B-spline radial basis functions and a Kohn-Sham density functional Hamiltonian. Both valence and core ionizations are considered. Scattering resonances in selected single-particle ionization channels are classified by the symmetry of the resonant state and the peak energy position in the photoelectron kinetic energy scale; the present results highlight once more the site specificity of core ionization processes. We further suggest that the resonant structures previously characterized in low-energy electron collision experiments are partly shifted below threshold by the photoionization processes. A critical evaluation of the theoretical results provides a guide for future experimental work on similar biosystems.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
