Ultrafast internal conversion in ethylene. I. The excited state lifetime

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An atomic orbital-based formulation of analytical gradients and nonadiabatic coupling vector elements for the state-averaged complete active space self-consistent field method on graphical processing units We present a new algorithm for ab initio quantum nonadiabatic molecular dynamics that combines the best features of ab initio Multiple Spawning (AIMS) and Multiconfigurational Ehrenfest (MCE) methods. In this new method, ab initio multiple cloning (AIMC), the individual trajectory basis functions (TBFs) follow Ehrenfest equations of motion (as in MCE). However, the basis set is expanded (as in AIMS) when these TBFs become sufficiently mixed, preventing prolonged evolution on an averaged potential energy surface. We refer to the expansion of the basis set as "cloning," in analogy to the "spawning" procedure in AIMS. This synthesis of AIMS and MCE allows us to leverage the benefits of mean-field evolution during periods of strong nonadiabatic coupling while simultaneously avoiding mean-field artifacts in Ehrenfest dynamics. We explore the use of time-displaced basis sets, "trains," as a means of expanding the basis set for little cost. We also introduce a new bra-ket averaged Taylor expansion (BAT) to approximate the necessary potential energy and nonadiabatic coupling matrix elements. The BAT approximation avoids the necessity of computing electronic structure information at intermediate points between TBFs, as is usually done in saddle-point approximations used in AIMS. The efficiency of AIMC is demonstrated on the nonradiative decay of the first excited state of ethylene. The AIMC method has been implemented within the AIMS-MOLPRO package, which was extended to include Ehrenfest basis functions.

Section: Computational Details and Resultsmentioning

confidence: 55%

Section: Computational Details and Resultsmentioning

confidence: 99%

Ab initio multiple cloning algorithm for quantum nonadiabatic molecular dynamics

Makhov

Glover

Martı́nez

et al. 2014

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245

“…In the case of single-photon ionization, the norms of Dyson orbitals have been shown to be a good approximation for relative ionization probabilities. [34][35][36][37] An excellent introduction into the description of photoionization using Dyson orbitals can be found in references 37-39, so here we only provide a brief overview.…”

Section: A Theorymentioning

confidence: 99%

Photoelectron spectra of 2-thiouracil, 4-thiouracil, and 2,4-dithiouracil

Ruckenbauer

Mai

Marquetand

et al. 2016

Ground-and excited-state UV photoelectron spectra of thiouracils (2-thiouracil, 4-thiouracil and 2,4-dithiouracil) have been simulated using multireference configuration interaction calculations and Dyson norms as measure for the photoionization intensity. Except for a constant shift, the calculated spectrum of 2-thiouracil agrees very well with experiment, while no experimental spectra are available for the two other compounds. For all three molecules, the photoelectron spectra show distinct bands due to ionization of the sulphur and oxygen lone pairs and the pyrimidine π system. The excited-state photoelectron spectra of 2-thiouracil show bands at much lower energies than in the ground state spectrum, allowing to monitor the excited-state population in time-resolved UV photoelectron spectroscopy (TRPES) experiments. However, the results also reveal that single-photon ionization probe schemes alone will not allow monitoring all photodynamic processes existing in 2-thiouracil. Especially, due to overlapping bands of singlet and triplet states the clear observation of intersystem crossing will be hampered.

“…A similar situation was encountered in the transient transparency of ethylene, [33] where the probe photon energy exceeded the adiabatic ionization potential by 4.9 eV. The question we must therefore address is how such a WP could be localized.…”

Section: Discussionmentioning

confidence: 65%

Coherent phase control of internal conversion in pyrazine

Seideman

Singha

et al. 2015

Shaped ultrafast laser pulses were used to study and control the ionization dynamics of electronically excited pyrazine in a pump and probe experiment. For pump pulses created without feedback from the product signal, the ion growth curve (the parent ion signal as a function of pump/probe delay) was described quantitatively by the classical rate equations for internal conversion of the S 2 and S 1 states. Very different, non-classical behavior was observed when a genetic algorithm (GA) was used to minimize the ion signal at some pre-determined target time, T. Two qualitatively different control mechanisms were identified for early (T< 1.5 ps) and late (T> 1.5 ps) target times. In the former case, the ion signal was largely suppressed for t < T , while for t T the ion signal produced by the GA-optimized pulse and a transform limited (TL) pulse coalesced. In contrast, for T > 1.5 ps the ion growth curve followed the classical rate equations for t < T , while for t T the quantum yield for the GA-optimized pulse was much smaller than for a TL pulse. We interpret the first type of behavior as an indication that the wave packet produced by the pump laser is localized in a region of the S 2 potential energy surface where the vertical ionization energy exceeds the probe photon energy, whereas the second type of behavior may be described by a reduced absorption cross section for S 0 → S 2 followed by incoherent decay of the excited molecules. * rjgordon@uic.edu 2