Dynamical Friction Effects on the Photoisomerization of a Model Protonated Schiff Base in Solution

Malhado, João Pedro; Spezia, Riccardo; Hynes, James T.

doi:10.1021/jp106096m

Cited by 46 publications

(79 citation statements)

References 116 publications

(272 reference statements)

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“…[17,[21][22][23] Different behavior was reported for protonated Schiff bases (PSBs), in which bond alternation is the predominant molecular coordinate that lifts the degeneracy at the 1 pp*/S 0 conical intersection. [24][25][26] The pyramidalization coordinate was found not to play any significant role in the singlet cis-trans isomerization mechanism of PSBs.…”

Section: Introductionmentioning

confidence: 90%

Molecular Mechanism of Diaminomaleonitrile to Diaminofumaronitrile Photoisomerization: An Intermediate Step in the Prebiotic Formation of Purine Nucleobases

Szabla

Góra

Šponer

et al. 2014

Chemistry A European J

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The photoinduced isomerization of diaminomaleonitrile (DAMN) to diaminofumaronitrile (DAFN) was suggested to play a key role in the prebiotically plausible formation of purine nucleobases and nucleotides. In this work we analyze two competitive photoisomerization mechanisms on the basis of state-of-the-art quantum-chemical calculations. Even though it was suggested that this process might occur on the triplet potential-energy surface, our results indicate that the singlet reaction channel should not be disregarded either. In fact, the peaked topography of the S1 /S0 conical intersection suggests that the deexcitation should most likely occur on a sub-picosecond timescale and the singlet photoisomerization mechanism might effectively compete even with a very efficient intersystem crossing. Such a scenario is further supported by the relatively small spin-orbit coupling of the S1 and T2 states in the Franck-Condon region, which does not indicate a very effective triplet bypass for this photoreaction. Therefore, we conclude that the triplet reaction channel in DAMN might not be as prominent as was previously thought.

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Section: Introductionmentioning

confidence: 90%

Molecular Mechanism of Diaminomaleonitrile to Diaminofumaronitrile Photoisomerization: An Intermediate Step in the Prebiotic Formation of Purine Nucleobases

Szabla

Góra

Šponer

et al. 2014

Chemistry A European J

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“…In principle, the intramolecular coordinates could be treated with Langevin dynamics as well if they are coupled to the solvent. 52 The quantitative accuracy of this approach may be limited by the approximations associated with a dielectric continuum representation of the solvent, linear response theory, and surface hopping. Nevertheless, this approach is expected to capture the qualitative aspects of photoinduced PCET processes.…”

Section: Mixed Quantum-classical Nonadiabatic Dynamics On Vibronicmentioning

confidence: 99%

Multidimensional treatment of stochastic solvent dynamics in photoinduced proton-coupled electron transfer processes: Sequential, concerted, and complex branching mechanisms

Soudackov

Hazra

Hammes‐Schiffer

2011

The Journal of Chemical Physics

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A theoretical approach for the multidimensional treatment of photoinduced proton-coupled electron transfer (PCET) processes in solution is presented. This methodology is based on the multistate continuum theory with an arbitrary number of diabatic electronic states representing the relevant charge distributions in a general PCET system. The active electrons and transferring proton(s) are treated quantum mechanically, and the electron-proton vibronic free energy surfaces are represented as functions of multiple scalar solvent coordinates corresponding to the single electron and proton transfer reactions involved in the PCET process. A dynamical formulation of the dielectric continuum theory is used to derive a set of coupled generalized Langevin equations of motion describing the time evolution of these collective solvent coordinates. The parameters in the Langevin equations depend on the solvent properties, such as the dielectric constants, relaxation time, and molecular moment of inertia, as well as the solute properties. The dynamics of selected intramolecular nuclear coordinates, such as the proton donor-acceptor distance or a torsional angle within the PCET complex, may also be included in this formulation. A surface hopping method in conjunction with the Langevin equations of motion is used to simulate the nonadiabatic dynamics on the multidimensional electron-proton vibronic free energy surfaces following photoexcitation. This theoretical treatment enables the description of both sequential and concerted mechanisms, as well as more complex processes involving a combination of these mechanisms. The application of this methodology to a series of model systems corresponding to collinear and orthogonal PCET illustrates fundamental aspects of these different mechanisms and elucidates the significance of proton vibrational relaxation and nonequilibrium solvent dynamics.

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“…The closest solvation dynamicsreaction rate connection is for low barrier electron 2,5,35,36 and proton transfers 37 , with a partial connection for other reaction classes [38][39][40] . There is however another potential solvation dynamics connection which is relatively little explored, i.e.…”

Section: Introductionmentioning

confidence: 99%

Solvation Dynamics in Liquid Water. 1. Ultrafast Energy Fluxes

Rey

Hynes

2015

J. Phys. Chem. B

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Solvation dynamics in liquid water is addressed via nonequilibrium energy transfer pathways activated after a neutral atomic solute acquires a unit charge, either positive or negative. It is shown that the well-known nonequilibrium frequency shift relaxation function can be expressed in a novel fashion in terms of energy fluxes, providing a clearcut and quantitative account of the processes involved. Roughly half of the initial excess energy is transferred into hindered rotations of first hydration shell water molecules, i.e. librational motions, specifically those rotations around the lowest moment of inertia principal axis. After integration over all water solvent molecules, rotations account for roughly 80 % of the energy transferred, while translations have a secondary role; transfer to intramolecular water stretch and bend vibrations is negligible. This picture is similar to that for relaxation of a single vibrationally or rotationally excited water molecule in neat liquid water, although solvation relaxation is more non-local. In addition, we find a remarkable independence of the main relaxation channels on the newly created charges sign. Although the methodology is applied here to the simplest solute case, the approach is rather general, and it should be at least equally useful in more realistic and complex scenarios.

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Dynamical Friction Effects on the Photoisomerization of a Model Protonated Schiff Base in Solution

Cited by 46 publications

References 116 publications

Molecular Mechanism of Diaminomaleonitrile to Diaminofumaronitrile Photoisomerization: An Intermediate Step in the Prebiotic Formation of Purine Nucleobases

Molecular Mechanism of Diaminomaleonitrile to Diaminofumaronitrile Photoisomerization: An Intermediate Step in the Prebiotic Formation of Purine Nucleobases

Multidimensional treatment of stochastic solvent dynamics in photoinduced proton-coupled electron transfer processes: Sequential, concerted, and complex branching mechanisms

Solvation Dynamics in Liquid Water. 1. Ultrafast Energy Fluxes

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