Dynamic Solvent Effect on Ultrafast Charge Recombination Kinetics in Excited Donor–Acceptor Complexes

Mikhailova, T. V.; Михайлова, В. А.; Ivanov, Anatoly I.

doi:10.1021/acs.jpcb.6b09363

Cited by 13 publications

(17 citation statements)

References 70 publications

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“…Indeed, MCSPT model simulations of the ultrafast CR kinetics in excited DACs have shown that the kinetic regularities of the charge transfer reactions occurring in nonequilibrium and equilibrium regimes can be strongly different. 14 In the present article such a regularity has been found and used for the first time as a strong evidence of the nonequilibrium mechanism of ultrafast CR. This regularity is associated with the dependence of the CR rate constant on dynamic properties of solvent, namely, on the solvent relaxation time.…”

Section: ■ Introductionsupporting

confidence: 54%

Verification of Nonequilibrium Mechanism of Ultrafast Charge Recombination in Excited Donor–Acceptor Complexes

2017

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Control of charge transfer requires knowledge of its detailed mechanism. Due to the large number of known mechanisms, the identification of the mechanism in specific systems is a challenge so far. In this article we propose the idea of how to distinguish between thermal and nonequilibrium modes of charge recombination in excited donor-acceptor complexes. Simulations of the effect of solvent relaxation time scale on ultrafast charge recombination kinetics in photoexcited donor-acceptor complexes within the framework of the multichannel stochastic model have shown that a series of regularities inherent to the thermal and nonequilibrium charge transfer can strongly differ. Among them there are opposite regularities, for example, the dependence of the dynamic solvent effect on the free energy gap. In particular, theory predicts that in ultrafast charge recombination of excited donor-acceptor complexes the dynamic solvent effect is weak in the area of weak exergonicity and becomes stronger in the area of stronger exergonicity whereas for the thermal reactions an opposite trend is expected. Comparison of such trends with experimental data implemented in this article allowed establishing the regime in which the reaction proceeds. It is shown that observation of dynamic solvent effect in the region of strong exergonicity for ultrafast charge recombination is decisive evidence in favor of nonequilibrium mechanism.

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Section: ■ Introductionsupporting

confidence: 54%

Verification of Nonequilibrium Mechanism of Ultrafast Charge Recombination in Excited Donor–Acceptor Complexes

2017

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“…The data presented in Figure allow us to suggest several practical recommendations for achieving the maximum CS efficiency in dyads. The reorganization energy E rm of low-frequency modes, which are typically associated with solvent but can include large-amplitude intramolecular nuclear motions, should be small. The reorganization energy E rv of high-frequency intramolecular vibrations should also be small as can be achieved in molecules with rigid structure. The CS energy gap |Δ G CS2 | should be larger than the energy gap between LES2 and LES1. Since rapidly relaxing polar solvents generally accelerate CS in the Marcus normal region and weakly affect CR in the Marcus inverted region, , using rapidly relaxing solvents is preferred. …”

Section: Numerical Results and Discussionmentioning

confidence: 99%

“…Since rapidly relaxing polar solvents generally accelerate CS in the Marcus normal region and weakly affect CR in the Marcus inverted region, , using rapidly relaxing solvents is preferred.…”

Section: Numerical Results and Discussionmentioning

confidence: 99%

The Efficiency of Photoinduced Intramolecular Charge Separation from the Second Excited State: What Factors Can Control It?

2020

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The efficiency of photoinduced charge separation (CS) in electron donor−acceptor compounds is commonly limited due to fast deactivation processes, such as the excited-state internal conversion and ultrafast hot reverse electron transfer to the acceptor, charge recombination (CR). A traditional way to avoid undesired energy losses due to CR is to put the reverse electron transfer into the Marcus inverted region, thus effectively suppressing it. This method, however, is not generally applicable when considering CS from the second locally excited state because the driving force of CR to the first excited state is small, and thus charge recombination is ultrafast and efficient. In this paper, we study the kinetic features of CS/CR from the second locally excited state of the donor using a semiclassical stochastic model of electron transfer. Particular attention is paid to the CS efficiency as well as the influence of the polar environment and intramolecular high-frequency vibrational modes on the kinetics of the charge-separated state. The influence of a number of model parameters on the CS yield and the energy efficiency has been analyzed using the results of numerical simulations. Several simple practical recipes for creating molecular compounds with high CS yields have been suggested. Simulations have also revealed a strong and non-monotonous (double-humped) dependence of both the yield and energy efficiency of CS on the driving force.

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“…Ultrafast transfer of charge (electron, proton, hole) is essential in fundamental science and diverse technological applications. − Currently, there are emerging applications in the areas of electrocatalysis, solar energy conversion, and molecular electronics. − Since the ultrafast electron transfer (ET) typically proceeds on a time scale comparable with that of the relaxation of solvent and intramolecular vibrations − the nuclear nonequilibrium created by an excitation laser pulse or chemical transformation may be of paramount importance in such reactions. − The regularities governing the kinetics of electron transfer occurring from nonthermalized solvent − and nonequilibrium state of nuclear subsystem of the reactants − can drastically differ from that of the thermal reactions. As a result, interest is growing in the study of such processes. , …”

Section: Introductionmentioning

confidence: 99%

Effect of Reactant and Product State Decay on Ultrafast Charge-Transfer Kinetics: Violation of the Principle of Independence of Elementary Chemical Reactions

Михайлова

Ivanov

2017

J. Phys. Chem. C

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Fast decay of both the reactant and product states is shown to strongly increase the intrinsic electron transfer rate in donor−acceptor dyads. The decay is associated with redistribution/ relaxation of excited vibrational states that typically participate in the reaction. Although the role of the reorganization of high-frequency vibrational modes in electron-transfer dynamics is well understood and it is commonly accepted to strongly affect the ultrafast electron transfer dynamics, the influence of the relaxation of excited vibrational states on electron transfer is not accounted for in experimental data analysis. In photoinduced electron transfer, excited states of high-frequency vibrational modes are often produced by laser pump pulse so that the ultrafast charge separation, at least partly, occurs from excited vibrational states. The charge recombination accompanying the charge separation also essentially occurs from excited vibrational states of intermediates to form a final excited vibrational state. Since the decay of the reactant state and electron transfer are two elementary chemical reactions occurring in parallel, the influence of vibrational relaxation on the intrinsic electron-transfer rate constant is a clear manifestation of the violation of the fundamental principle of chemical kinetics postulating the independence of elementary chemical reactions. The mechanism of the violation is discussed in detail. The transition probability that better characterizes the efficiency of ultrafast nonequilibrium charge recombination than the rate constant is calculated. The dependencies of the electron-transfer rate constant and the transition probability on the product decay time are predicted to be identical while on the reactant decay time to be opposite.

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Dynamic Solvent Effect on Ultrafast Charge Recombination Kinetics in Excited Donor–Acceptor Complexes

Cited by 13 publications

References 70 publications

Verification of Nonequilibrium Mechanism of Ultrafast Charge Recombination in Excited Donor–Acceptor Complexes

Verification of Nonequilibrium Mechanism of Ultrafast Charge Recombination in Excited Donor–Acceptor Complexes

The Efficiency of Photoinduced Intramolecular Charge Separation from the Second Excited State: What Factors Can Control It?

Effect of Reactant and Product State Decay on Ultrafast Charge-Transfer Kinetics: Violation of the Principle of Independence of Elementary Chemical Reactions

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