The nucleobase cytosine and the cytosine dimer investigated by double resonance laser spectroscopy and ab initio calculations

Nir, Eyal; Hünig, Isabel; Kleinermanns, Karl; Vries, Mattanjah S. de

doi:10.1039/b310396j

Cited by 96 publications

(133 citation statements)

References 15 publications

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“…22,30 It also agrees quite well with the experimental adiabatic excitation energy of 3.95 eV estimated from the resonance-enhanced multiphoton ionization (REMPI) spectrum. 10,60 It has been proposed previously that the minimum energy path (MEP) approach is appropriate for the determination of the deactivaiton pathway since it provides information about the accessibility of the conical intersection. 29,[61][62][63] There is the possibility that it leads to the seam of CIs before reaching the ( 1 ππ*) min structure, thus providing the most relevant photochemical deactivation pathway.…”

Section: S 1 Minimum Energy Structurementioning

confidence: 99%

Photophysics of cytosine tautomers: new insights into the nonradiative decay mechanisms from MS-CASPT2 potential energy calculations and excited-state molecular dynamics simulations

Nakayama

Harabuchi

Yamazaki

et al. 2013

Phys. Chem. Chem. Phys.

111

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A comprehensive picture of the ultrafast nonradiative decay mechanisms of three cytosine tautomers (amino-keto, imino-keto, and amino-enol forms) is revealed by high-level ab initio potential energy calculations using the multistate (MS) CASPT2 method and also by on-the-fly excited-state molecular dynamics simulations employing the CASSCF method. To obtain a reliable potential energy profile along the deactivation pathways, the MS-CASPT2 method is employed even for the optimization of minimum energy structures in the excited state and conical intersection (CI) structures between the ground and excited states. In the imino (imino-keto) form, we locate a new CI structure involving the twisting of the imino group, and the decay pathway leading to this CI is found to be barrierless, suggesting a remarkably efficient deactivation of imino cytosine. In the keto (amino-keto) form, the MS-CASPT2 calculations exhibit an efficient decay path to the ethylene-like CI involving the twisting of C-C double bond in the six-membered ring, with a barrier of ~0.08 eV from the minimum of the 1 ππ* state. In the enol (amino-enol) form, three types of CIs are identified for the first time. Among them, the ethylene-like CI with a similar molecular structure to the keto form provides the most preferred deactivation pathway of enol cytosine. This pathway exhibits a higher barrier of ~0.22 eV and a higher energy of CI than those of keto cytosine. Nonadiabatic molecular dynamics simulations provide a time-dependent picture of the deactivation processes, including the excited-state lifetime of each tautomer. In particular, the decay time of the imino tautomer is predicted to be only ~100 fs. Our computational results are in remarkably good agreement with the experimental findings in recent femtosecond pump-probe photoionization spectroscopy [J. Am. Chem. Soc. 131, 16939 (2009); J. Phys. Chem. A 115, 8406 (2011)], supporting the coexistence of more than one tautomer in the photophysics of isolated cytosine and that each tautomer exhibits a different excited-state lifetime.1

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Section: S 1 Minimum Energy Structurementioning

confidence: 99%

Photophysics of cytosine tautomers: new insights into the nonradiative decay mechanisms from MS-CASPT2 potential energy calculations and excited-state molecular dynamics simulations

Nakayama

Harabuchi

Yamazaki

et al. 2013

Phys. Chem. Chem. Phys.

111

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“…While the energy difference between the enol and keto forms is very small, some of their other properties, such as their vertical excitation energies, are very different. Nir et al reported REMPI and hole burning spectra and concluded that the keto and enol tautomers have band origins that differ by a remarkable half electron volt at 314 nm and 278 nm, respectively (42,43). The REMPI spectra of U and T exhibit a very broad structure with an onset in the frequency range of the origin of the enol cytosine first reported by Brady et al (4).. No spectroscopic detail could be extracted from these broad spectra and tautomeric information was limited for a long time to bulk measurements.…”

Section: Purinesmentioning

confidence: 99%

Gas-Phase IR Spectroscopy of Nucleobases

Vries

2014

Topics in Current Chemistry

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Abstract.IR spectroscopy of nucleobases in the gas phase reflects simultaneous advances in both experimental and computational technique. Important properties, such as excited state dynamics, depend in subtle ways on structure variations, which can be followed by their infrared signatures. Isomer specific spectroscopy is a particularly powerful tool for studying the effects of nucleobase tautomeric form and base pair hydrogen bonding patterns.

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“…1 They produced cytosine dimers using laser desorption and presented strong evidence for only one isomer -(C1) 2 HB1 -being present in their molecular beam. 13 According to Kabelac and Hobza,54 this is the most populated isomer based on their molecular dynamics/quenching calculations (albeit of a 298K ensemble). The absence of other isomers could be explained 1 by a number of reasons stemming from the detection scheme in a REMPI experiment: (1) poor absorption in the first excited state; (2) ionization energy higher than accessible by two photons; (3) fragmentation of the cation; (4) lifetimes of the excited state being too short for second photon absorption.…”

Section: B Cytosine Dimers: Structures Binding Energies and Populationsmentioning

confidence: 99%

“…Previous ionization studies of cytosine consist of photoionization mass spectrometry (PIMS) measurements of AIEs, 6,7 photoelectron spectroscopy (PES) at the valence [8][9][10][11] and core level, 12 resonance enhanced multiphoton ionization (REMPI) experiments 13,14 and a number of electronic structure calculations. 9,[15][16][17][18] Trofimov et al 9 measured a valence-shell PES of cytosine.…”

Section: Introductionmentioning

confidence: 99%

Ionization of cytosine monomer and dimer studied by VUV photoionization and electronic structure calculations

Kostko

Bravaya

Krylov

et al. 2010

Phys. Chem. Chem. Phys.

124

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Photoionization of the cytosine dimer 2 SummaryWe report a combined theoretical and experimental study of ionization of cytosine monomers and dimers.Gas-phase molecules are generated by thermal vaporization of cytosine followed by expansion of the vapor in a continuous supersonic jet seeded in Ar. The resulting species are investigated by single photon ionization with tunable vacuum-ultraviolet (VUV) synchrotron radiation and mass analyzed using reflectron mass spectrometry. Energy onsets for the measured photoionization efficiency (PIE) spectra are 8.60±0.05 eV and 7.6±0.1 eV for the monomer and the dimer, respectively, and provide an estimate for the adiabatic ionization energies (AIE). The first AIE and the ten lowest vertical ionization energies (VIEs) for selected isomers of cytosine dimer computed using equation-of-motion coupled-cluster (EOM-IP-CCSD) method are reported. The comparison of the computed VIEs with the derivative of the PIE spectra, suggests that multiple isomers of the cytosine dimer are present in the molecular beam. The calculations reveal that the large red shift (0.7 eV) of the first IE of the lowest-energy cytosine dimer is due to strong inter-fragment electrostatic interactions, i.e., the hole localized on one of the fragments is stabilized by the dipole moment of the other. A sharp rise in the CH + signal at 9.20±0.05 eV is ascribed to the formation of protonated cytosine by dissociation of the ionized dimers. The dominant role of this channel is supported by the computed energy thresholds for the CH + appearance and the barrierless or nearly barrierless ionization-induced proton transfer observed for five isomers of the dimer.3

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The nucleobase cytosine and the cytosine dimer investigated by double resonance laser spectroscopy and ab initio calculations

Cited by 96 publications

References 15 publications

Photophysics of cytosine tautomers: new insights into the nonradiative decay mechanisms from MS-CASPT2 potential energy calculations and excited-state molecular dynamics simulations

Photophysics of cytosine tautomers: new insights into the nonradiative decay mechanisms from MS-CASPT2 potential energy calculations and excited-state molecular dynamics simulations

Gas-Phase IR Spectroscopy of Nucleobases

Ionization of cytosine monomer and dimer studied by VUV photoionization and electronic structure calculations

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