High-resolution photoelectron spectra of the pyrimidine-type nucleobases

Fulfer, Kristen D.; Hardy, D.; Aguilar, A.; Poliakoff, E. D.

doi:10.1063/1.4922310

Cited by 16 publications

(21 citation statements)

References 40 publications

(88 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…By averaging the values for each electronic cationic state within the different formulations of the CASPT2 method (see Table ) we predict the first four vertical ionisation potentials relative to the

^{2} π_{H O M O}^{+}

^{2} n_{O}^{+}

^{2} π_{H O M O - 1}^{+}

and

^{2} n_{N}^{+}

states (see Figure ) to be placed at 8.74, 9.44, 9.59 and 9.94 eV, respectively, while the first adiabatic ionisation potential is situated at 8.56 eV, which is in good agreement with the available experimental evidence and previous theoretical estimates . A standard deviation of ∼0.2 eV for the CASPT2 average is obtained for all states.…”

Section: Resultssupporting

confidence: 85%

Computing the Ultrafast and Radiationless Electronic Excited State Decay of Cytosine and 5‐methyl‐cytosine Cations: Uncovering the Role of Dynamic Electron Correlation

2019

View full text Add to dashboard Cite

Photoionisation in DNA, i. e. the process of photoinduced electron removal from the chromophoric species -the nucleobases -leading to their cationic form, has been scarcely studied despite being considered to be responsible for significant damaging instances in our genetic material. In this contribution we theoretically characterise the electronic ground and excited state decay pathways of cationic DNA nucleobase cytosine + and its epigenetic derivative 5-methyl-cytosine + , including the effects of dynamic electron correlation on energies and geometries of minima and conical intersections. We do this by comparing the results of XMS-CASPT2 calculations with CASSCF estimates and we find some significant differences between the results of these two methods. In particular, including dynamic electron correlation is found to significantly reduce the barrier to access the ðD 1 =D 0 Þ conical intersection. We find notable similarities in both cytosine and 5methyl-cytosine cations, and accessible conical intersections in the vicinity of the Franck-Condon region are found. This points towards an ultrafast depopulation of their electronic excited states. Moreover, the shape of the ground state potential energy surface strongly directs the decaying excited state population towards the cationic ground state minimum on ultrafast timescales, preventing photo-fragmentation and thus explaining their photostability. To better compare our calculations with the available experimental data we compute the UV (ground and excited state) and IR absorptions.[a] Dr.

show abstract

^{2} π_{H O M O}^{+}

^{2} n_{O}^{+}

^{2} π_{H O M O - 1}^{+}

and

^{2} n_{N}^{+}

Section: Resultssupporting

confidence: 85%

Computing the Ultrafast and Radiationless Electronic Excited State Decay of Cytosine and 5‐methyl‐cytosine Cations: Uncovering the Role of Dynamic Electron Correlation

2019

View full text Add to dashboard Cite

show abstract

“…We start by analysing and comparing the results obtained for the two well-defined experimental magnitudes often employed to benchmark the cationic manifold computationally, that is, the vertical and adiabatic ionisation potentials. Averaging values from Table 1 for each state in turn, the different formulations of the CASPT2 method predict the first three vertical ionisation potentials to be placed at 9.53, 10.00 and 10.59 eV, while the first adiabatic ionisation potential is placed at 9.35 eV, in agreement with the available experimental evidence [69][70][71][72] , as well as previous theoretical estimates. 6,15,74 As has been reported by Roca-Sanjuán et al, 15 the introduction of the IPEA shift appears to blue-shift the estimates obtained at the CASPT2 level, bringing them closer to the experimental values.…”

Section: Uracil + Energiessupporting

confidence: 83%

“…Averaged CASPT2 estimates of the first three vertical and first adiabatic ionisation potential are 9.22, 9.93, 10.51 and 9.05 eV, respectively, which are placed roughly within a tenth of an eV from the experimental evidence (see Table 2). [69][70][71][72] We observe a 0.2 (D 2 ) to 0.3 (D 0 ) eV red-shift on vertical and adiabatic ionisation potentials of 2 π + character related to 5methylation, i.e. moving from uracil + to thymine + .…”

Section: Thymine + Energiesmentioning

confidence: 79%

“…We reproduce the trend registered experimentally whereby 5methylation induces a stabilisation on the 2 π + cationic manifold. [69][70][71][72] Within the cationic manifold, CASSCF predicts 1 eV D 0 − D 1 and 0.08 eV D 1 − D 2 energy gaps at the FC region, in contrast with the XMS-CASPT2 estimates of 0.71 and 0.57 eV, respectively, leading to differences of ∼0.3 eV for the former and ∼0.5 eV for the latter. The red-shift on D 2 and the negligible effect on D 1 upon methylation leads to a near degeneracy between these states, which is however broken when including dynamic correlation.…”

Section: Thymine + Energiesmentioning

confidence: 79%

See 1 more Smart Citation

Ultrafast and radiationless electronic excited state decay of uracil and thymine cations: computing the effects of dynamic electron correlation

Segarra‐Martí

Tran

Bearpark

2019

Phys. Chem. Chem. Phys.

View full text Add to dashboard Cite

show abstract

“…The VIEs have been computed using both diagonal and non-diagonal approaches, whereas the gradients have been computed in all cases at the OVGF level since, as shown above for furane, the choice of the propagator method used in the simulation has a minor impact in the reproduction of the gradients, which can therefore be computed using cheaper methods. The reliability of the various propagator approaches has been checked comparing the theoretical results with the experimental photoelectron spectrum taken from ref 86. that is, up to our knowledge, the most accurate spectrum available in the literature, displaying an higher resolution with other spectra available in the literature 87,88.…”

Section: Applicationsmentioning

confidence: 99%

Assessment of Electron Propagator Methods for the Simulation of Vibrationally Resolved Valence and Core Photoionization Spectra

Baiardi

Paoloni

Barone

et al. 2017

J. Chem. Theory Comput.

View full text Add to dashboard Cite

The analysis of photoelectron spectra is usually facilitated by quantum mechanical simulations. Because of the recent improvement of experimental techniques, the resolution of experimental spectra is rapidly increasing, and the inclusion of vibrational effects is usually mandatory to obtain a reliable reproduction of the spectra. With the aim of defining a robust computational protocol, a general time-independent formulation to compute different kinds of vibrationally resolved electronic spectra has been generalized to also support photoelectron spectroscopy. The electronic structure data underlying the simulation are computed using different electron propagator approaches. In addition to the more standard approaches, a new and robust implementation of the second-order self-energy approximation of the electron propagator based on a transition operator reference (TOEP2) is presented. To validate our implementation, a series of molecules has been used as test cases. The result of the simulations shows that, for ultraviolet photoionization spectra, the more accurate nondiagonal approaches are needed to obtain a reliable reproduction of vertical ionization energies but that diagonal approaches are sufficient for energy gradients and pole strengths. For X-ray photoelectron spectroscopy, the TOEP2 approach, besides being more efficient, is also the most accurate in the reproduction of both vertical ionization energies and vibrationally resolved bandshapes.

show abstract

High-resolution photoelectron spectra of the pyrimidine-type nucleobases

Cited by 16 publications

References 40 publications

Computing the Ultrafast and Radiationless Electronic Excited State Decay of Cytosine and 5‐methyl‐cytosine Cations: Uncovering the Role of Dynamic Electron Correlation

Computing the Ultrafast and Radiationless Electronic Excited State Decay of Cytosine and 5‐methyl‐cytosine Cations: Uncovering the Role of Dynamic Electron Correlation

Ultrafast and radiationless electronic excited state decay of uracil and thymine cations: computing the effects of dynamic electron correlation

Assessment of Electron Propagator Methods for the Simulation of Vibrationally Resolved Valence and Core Photoionization Spectra

Contact Info

Product

Resources

About