Version 2 2016-02-26, 17:07Version 2 2016-02-26, 17:07
Version 1 2016-02-25, 17:15Version 1 2016-02-25, 17:15
journal contribution
posted on 2016-02-15, 00:00authored byYuki Kanazawa, Masahiro Ehara, Thomas Sommerfeld
Low-lying π* resonance states
of DNA and RNA bases have been
investigated by the recently developed projected complex absorbing
potential (CAP)/symmetry-adapted cluster-configuration interaction
(SAC–CI) method using a smooth Voronoi potential as CAP. In
spite of the challenging CAP applications to higher resonance states
of molecules of this size, the present calculations reproduce resonance
positions observed by electron transmission spectra (ETS) provided
the anticipated deviations due to vibronic effects and limited basis
sets are taken into account. Moreover, for the standard nucleobases,
the calculated positions and widths qualitatively agree with those
obtained in previous electron scattering calculations. For guanine,
both keto and enol forms were examined, and the calculated values
of the keto form agree clearly better with the experimental findings.
In addition to these standard bases, three modified forms of cytosine,
which serve as epigenetic or biomarkers, were investigated: formylcytosine,
methylcytosine, and chlorocytosine. Last, a strong correlation between
the computed positions and the observed ETS values is demonstrated,
clearly suggesting that the present computational protocol should
be useful for predicting the π* resonances of congeners of DNA
and RNA bases.