Strong-field- versus weak-field-ionization pump-probe spectroscopy

Horton, Spencer; Liu, Yusong; Chakraborty, Pratip; Marquetand, Philipp; Rozgonyi, Tamás; Matsika, Spiridoula; Weinacht, Thomas

doi:10.1103/physreva.98.053416

Cited by 18 publications

(17 citation statements)

References 77 publications

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“…1 into three bands and plotted them as a function of C-I bond distance. The wave packet associated with the direct dissociation trajectories moves out to large C-I distances rapidly after internal conversion from the initially photoexcited states (13)(14)(15)(16)(17) to the dissociative states (9-12), while the wave packet associated with the indirect trajectories remains bound in states 13-17 for about 200 fs and then eventually internally converts, followed by dissociation. Panels (b1) and (b2) show the electronic state index as well as the potential energy as a function of delay time after the UV pump pulse.…”

Section: Discussionmentioning

confidence: 99%

“…Timedependent calculations have evolved to produce very detailed pictures of molecular dynamics, but they require many approximations and thus must be benchmarked against measurements in order to ensure accuracy and relevance. It is important that these simulations can be directly compared (without adjustable parameters) to time-resolved experimental data, as has been done, e.g., with quantum dynamics simulations [8][9][10][11][12], trajectory surface hopping calculations [13][14][15], ab initio multiple spawning (AIMS) [16][17][18][19][20][21], and many more approaches. While a given observable may apply certain constraints to a calculation, many ambiguities will remain.…”

Section: Introductionmentioning

confidence: 99%

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Spectroscopic and Structural Probing of Excited-State Molecular Dynamics with Time-Resolved Photoelectron Spectroscopy and Ultrafast Electron Diffraction

et al. 2020

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Pump-probe measurements aim to capture the motion of electrons and nuclei on their natural timescales (femtoseconds to attoseconds) as chemical and physical transformations take place, effectively making "molecular movies" with short light pulses. However, the quantum dynamics of interest are filtered by the coordinate-dependent matrix elements of the chosen experimental observable. Thus, it is only through a combination of experimental measurements and theoretical calculations that one can gain insight into the internal dynamics. Here, we report on a combination of structural (relativistic ultrafast electron diffraction, or UED) and spectroscopic (time-resolved photoelectron spectroscopy, or TRPES) measurements to follow the coupled electronic and nuclear dynamics involved in the internal conversion and photodissociation of the polyatomic molecule, diiodomethane (CH 2 I 2). While UED directly probes the 3D nuclear dynamics, TRPES only serves as an indirect probe of nuclear dynamics via Franck-Condon factors, but it is sensitive to electronic energies and configurations, via Koopmans' correlations and photoelectron angular distributions. These two measurements are interpreted with trajectory surface hopping calculations, which are capable of simulating the observables for both measurements from the same dynamics calculations. The measurements highlight the nonlocal dynamics captured by different groups of trajectories in the calculations. For the first time, both UED and TRPES are combined with theory capable of calculating the observables in both cases, yielding a direct view of the structural and nonadiabatic dynamics involved.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Spectroscopic and Structural Probing of Excited-State Molecular Dynamics with Time-Resolved Photoelectron Spectroscopy and Ultrafast Electron Diffraction

et al. 2020

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“…strong UV-C) required to remove electrons from the nucleobases (although this is reduced upon N1 substitution when moving to nucleosides and nucleotides, the nucleobase derivatives actually present in the DNA double helix chain). [6][7][8][9] This has for many years prevented in-depth studies, but recent developments in the generation of high-energy few-cycle UV-C pulses 10,11 and the advent of highenergy free electron laser sources 12 have opened up the possibility of studying time-resolved photoionisation processes in such small organic compounds and their use in pump-probe set-ups to monitor photo-reactions.…”

Section: Introductionmentioning

confidence: 99%

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.

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“…The ionisation of cytosine derivatives has been a topic of scarce study in the literature, with the only references found by us being relative to the specific UV/Vis absorption spectral fingerprints of cytosine +[22] as well as their IR features . Very little is also known about the cationic excited state decay relaxation, particularly comparing to other similar systems like the RNA nucleobase uracil . The only works available in the literature are characterisation of the Dyson norms of cytosine and the evolution of the cationic manifold along the relaxation of the bright and initially accessed singlet

π π^{*}

decay channel by Matsika and co‐workers, which cover different facets of potential ionisation mechanisms while not depicting the actual cation generation and its excited state decay relaxation channels.…”

Section: Introductionmentioning

confidence: 99%

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

2019

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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.

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Strong-field- versus weak-field-ionization pump-probe spectroscopy

Cited by 18 publications

References 77 publications

Spectroscopic and Structural Probing of Excited-State Molecular Dynamics with Time-Resolved Photoelectron Spectroscopy and Ultrafast Electron Diffraction

Spectroscopic and Structural Probing of Excited-State Molecular Dynamics with Time-Resolved Photoelectron Spectroscopy and Ultrafast Electron Diffraction

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

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