Sergei A. Trushin scite author profile

Ab initio multistate second-order perturbation theory (MS−CASPT2) calculations are used to map the reaction path for the ultrafast photochemical electrocyclic ring-opening of cyclohexa-1,3-diene (CHD). This path is characterized by evolution along a complex reaction coordinate extending over two barrierless excited state potential energy surfaces and ultimately leading to deactivation through a S1/S0 conical intersection. The observed excited-state dynamics involve three sequential phases with lifetimes (traveling times) of 10, 43, and 77 fs, respectively. In this work we associate each phase to the evolution of the CHD molecular structure along a different mode. In particular, we show that (a) the decay of CHD from its spectroscopic (1B2) state to a lower lying dark (2A1) excited state involves motion along a highly curved coordinate corresponding to a mixture of σ bond expansion and symmetry breaking skeletal bending, (b) the evolution on the 2A1 (S1) state and the final 2A1→1A1 (i.e., S1→S0) decay involve a large amplitude displacement along the same asymmetric bending mode which ultimately leads to a S1/S0 conical intersection, and (c) the application of a novel strategy for mapping the multidimensional S1/S0 intersection space indicates that the ultrashort 77 fs lifetime of the 2A1 excited state is due to the existence of an extensive set of S1/S0 conical intersection points spanning the low-lying part of the 2A1 energy surface. Points (a) and (b) are validated by discussing the results of previously reported and new femtosecond time-resolved spectroscopic data on CHD and on the two dialkyl derivatives α-terpinene and α-phellandrene. An interpretation in terms of driving forces is also given.

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Femtosecond Dynamics of Fe(CO)₅ Photodissociation at 267 nm Studied by Transient Ionization

Trushin

et al. 2000

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We found five consecutive processes with time constants 21, 15, 30, 47, and 3300 fs in Fe(CO)5 after excitation at 267 nm in the gas phase. The first four represent a continuous pathway of the molecule from the Franck−Condon region down to the lowest singlet state (S0) of Fe(CO)4 through a chain of Jahn−Teller-induced conical intersections. The motion before dissociation initially involves more than one of the equatorial ligands, but then eliminates only one CO. The product Fe(CO)4 is initially generated in its first excited singlet state S1, then it relaxes to S0 in 47 fs via a triply degenerate conical intersection at tetrahedral geometry. The pathway for this process involves pseudorotation of the ligands. The fifth step is assigned to thermal elimination of a second CO. Intersystem crossing to the triplet ground states of Fe(CO)4 and Fe(CO)3 takes more than 500 ps.

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Sergei A. Trushin

Controlled near-field enhanced electron acceleration from dielectric nanospheres with intense few-cycle laser fields

Reaction Path of a sub-200 fs Photochemical Electrocyclic Reaction

Femtosecond Dynamics of Fe(CO)₅ Photodissociation at 267 nm Studied by Transient Ionization

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Sergei A. Trushin

Controlled near-field enhanced electron acceleration from dielectric nanospheres with intense few-cycle laser fields

Reaction Path of a sub-200 fs Photochemical Electrocyclic Reaction

Femtosecond Dynamics of Fe(CO)5 Photodissociation at 267 nm Studied by Transient Ionization

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Product

Resources

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Femtosecond Dynamics of Fe(CO)₅ Photodissociation at 267 nm Studied by Transient Ionization