单电子转移反应

本文对重要有机反应之一的单电子转移过程作了综述。单电子转移反应与极性反应的根本区别在于,前者每次只发生一个电子的转移,而后者通常每次发生一对电子的转移。影响这二种历程的主要因素是反应物的立体因素,电子结构及氧化还原能力。单电子转移按其反应方式又被细分(?)inner-sphere ET (?) outer-sphere ET 二种历程。一些典型的单电子转移反应已被分类介绍。     

Competition of concatenated and thermally activated medium reorganization in photoinduced electron transfer reactions

Two mechanisms of photoinduced electron-transfer reactions, the classical mechanism of the preliminary thermally activated reorganization of a medium and reactants (at relatively weak electronic interaction between reactant molecules) and the mechanism of intermediate formation of exciplexes by concatenated medium reorganization correlated with charge displacement (at relatively strong electronic interaction between the reactants) are compared.     

Reversibility of electrode reactions involving organic compounds

A general empirical approach allowing one to describe the kinetics and evaluate the mechanism of the electrode electron transfer reactions is offered. The approach is based on the electrode potentials, the vertical ionization potentials (oxidation), and the affinity to electron (reduction). An equation linking kinetic and thermodynamic parameters is derived. Electrode reactions involving organic compounds are discussed in polarographic terms. The conclusion is drawn that most electron transfer reactions involving organic compounds are reversible, and that the irreversibility of the net electrode reaction is due to the irreversibility of subsequent chemical and electrochemical stages. An experimental observation of the slow electron transfer is possible in the cases of a substantial reorganization of molecules in the presence of fast subsequent chemical and electrochemical reactions.     

Pendant unit effect on electron tunneling in U-shaped molecules

The electron transfer reactions of three U-shaped donor-bridge-acceptor molecules with different pendant groups have been studied in different solvents as a function of temperature. Analysis of the electron transfer kinetics in nonpolar and weakly polar solvents provides experimental reaction Gibbs energies that are used to parameterize a molecular solvation model. This solvation model is then used to predict energetic parameters in the electron transfer rate constant expression and allow the electronic coupling between the electron donor and electron acceptor groups to be determined from the rate data. The U-shaped molecules differ by alkylation of the aromatic pendant group, which lies in the ‘line-of-sight’ between the donor and acceptor groups. The findings show that the electronic coupling through the pendant group is similar for these molecules.     

Luminescence quenching by DNA-bound viologens: effect of reactant identity on efficiency and dynamics of electron transfer in DNA

Photoinduced electron transfer from two intercalating photoactive donors, Ru(phen)2dppz2+ and ethidium, to intercalating viologen acceptors of the N,N'-dialkyl-6-(2'-pyridiniumyl)phenanthridinium family has been investigated through steady-state and time-resolved luminescence quenching measurements. Efficient quenching of the emission from these donors bound to DNA is observed at low concentrations of acceptor (1-10 eq.), and in time-resolved emission experiments it is determined that electron transfer occurs on the nanosecond time scale. Furthermore, transient absorption measurements confirm that the quenching is the result of a charge-transfer process; upon photoreaction of intercalated Ru(phen)2dppz2+ with a viologen acceptor, an intermediate with spectral properties resembling the expected charge-separated pair is observed. The quenching yields and kinetics obtained with this quencher are in marked contrast to those observed with these same donors paired with Rh(phi)2bpy3+ as an acceptor. The differing efficiencies of electron transfer for these donor/acceptor pairs bound to DNA as compared to others previously described are discussed qualitatively in terms of the structural and electronic properties of the different reactants.     

Fifty years of studies of double layer effects in electrode kinetics��a personal view

Developments in the treatment of double layer effects in electrode kinetics are outlined. These include discreteness-of-charge effects in the presence of specific adsorption, solvent effects in electron transfer reactions, and effects related to the distribution of charge in polyatomic reactants. The importance of studies at single crystal electrodes is emphasized, and the development of a single crystal ultramicroelectrode described. Finally, a method of improving the estimate of the diffuse layer potential drop on the basis of Monte Carlo simulations is presented.     

Dynamic effect of ionic atmosphere on the kinetics of the elementary act of charge transfer reactions

A general method is developed enabling to take into account in a unified manner the dynamical behaviour of all the degrees of freedom of the system, including the movement of the reactants as a whole and the dynamics of the ionic atmosphere. The method relates the transition probability to the density matrices of the whole reacting system. The Franck—Condon approximation is not used. As an example, the homogeneous and electrochemical electron transfer reactions are considered. The dynamic effect of the ionic atmosphere on the charge transfer kinetics is shown to consist in that the configuration of the ionic atmosphere in the transition state is different from this in the equilibrium initial and final states and corresponds to intermediate charges of the reacting particles. The effect of image forces in the case of electrochemical reactions is taken into account.     

Effect of Cetylpyridinium chloride on the electron transfer reactions of acetophenones with Ce(IV)

The kinetics of electron transfer reactions between acetophenones with Ce(IV) have been studied in aqueous acetic acid medium in the presence of cationic micelle Cetylpyridinium chloride (CPyCl) at different temperatures. Kinetic data reveal first-order dependence with respect to each of Ce(IV) and acetophenones. The cationic micelle, Cetylpyridinium chloride enhances the oxidation reactions. The catalysis fits to a model developed by Menger and Portnoy as well as Berezin's phase separation model. The binding and partition constants and the transfer free energy from water to micelle have been estimated and discussed, suggesting that the solubilization of both the reactants in the micellar phase, facilitates the oxidation. © 1993 John Wiley & Sons, Inc.     

A general theoretical model for electron transfer reactions in complex systems

In this paper we present a general theoretical-computational model for treating electron transfer reactions in complex atomic-molecular systems. The underlying idea of the approach, based on unbiased first-principles calculations at the atomistic level, utilizes the definition and the construction of the Diabatic Perturbed states of the involved reactive partners (i.e. the quantum centres in our perturbation approach) as provided by the interaction with their environment, including their mutual interaction. In this way we reconstruct the true Adiabatic states of the reactive partners characterizing the electron transfer process as the fluctuation of the electronic density due to the fluctuating perturbation. Results obtained by using a combination of Molecular Dynamics simulation and the Perturbed Matrix Method on a prototypical intramolecular electron transfer (from 2-(9,9'-dimethyl)fluorene to the 2-naphthalene group separated by a steroidal 5-α-androstane skeleton) well illustrate the accuracy of the method in reproducing both the thermodynamics and the kinetics of the process.     

Structure�Creactivity relationships in inorganic electrochemistry

Relationships between structure and electron transfer reactivity underlie many important electrochemical applications and provide fundamental insight to chemical and biological processes. The vast array of experimental techniques developed during the latter half of the twentieth century helped greatly to foster progress in this area, and the advent of powerful computational techniques such as density functional theory promises even more far-reaching developments. It is evident that molecular composition, geometric and electronic structure, and changes in these features influence the thermodynamics and kinetics of transition metal electron transfer reactions in predictable and understandable ways. Several examples drawn from the author??s research program to illustrate this premise include the influence of sulfur versus oxygen donation on molybdenum-centered electron transfer, reactions in which a change in metal atom spin state accompanies electron transfer, and concomitant multi-electron transfer and metal?Cmetal bond cleavage in binuclear, ligand-bridged complexes.     

Ru−FeNi Alloy Heterojunctions on Lignin-derived Carbon as Bifunctional Electrocatalysts for Efficient Overall Water Splitting

Rational design of efficient, stable, and inexpensive bifunctional electrocatalysts for oxygen evolution reactions (OER) and hydrogen evolution reactions (HER) is a key challenge to realize green hydrogen production via electrolytic water splitting. Herein, Ru nanoparticles and FeNi alloy heterojunction catalyst (Ru−FeNi@NLC) encapsulated via lignin-derived carbon was prepared by self-assembly precipitation and in situ pyrolysis. The designed catalyst displays excellent performance at 10 mA cm⁻² with low overpotentials of 36 mV for HER and 198 mV for OER, and only needs 1.48 V for overall water splitting. Results and DFT calculations show the unique N-doped lignin-derived carbon layer and Ru−FeNi heterojunction contribute to optimized electronic structure for enhancing electron transfer, balanced free energy of reactants and intermediates in the sorption/desorption process, and significantly reduced reaction energy barrier for the HER and OER rate-determining steps, thus improved reaction kinetics. This work provides a new in situ pyrolysis doping strategy based on renewable biomass for the construction of highly active, stable and cost-effective catalysts.     

A new external EI/CI source-ion trap system devoted to the study of ion-molecule reactions

A new instrumental arrangement dedicated to the study of ion-molecule reactions and consists of by an electron impact/chemical ionization source mounted 420 mm away from an ion trap is described. It has been designed and developed to exclude diffusion into the ion trap of the neutral reactants from the EI/CI source and so to avoid undesired side-reactions. Its instrumental parameterization is described and some preliminary results are illustrated that show promise for the successful application of the system to the study of ion-molecule reactions.     

Quantum effect of intramolecular high-frequency vibrational modes on diffusion-controlled electron transfer rate: from the weak to the strong electronic coupling regions

The Sumi-Marcus theory is extended by introducing two approaches to investigate electron transfer reactions from weak-to-strong electronic coupling regime. One of these approaches is the quantum R-matrix theory, useful for dealing with the intramolecular vibrational motions in the whole electronic coupling domain. The other is the split operator approach that is employed to solve the reaction-diffusion equation. The approaches are then applied to electron transfer in the Marcus inverted regime to investigate the nuclear tunneling effect on the long time rate and the survival probabilities. The numerical results illustrate that the adiabatic suppression obtained from the R-matrix approach is much smaller than that from the Landau-Zener theory whereas it cannot be predicted by the perturbation theory. The jointed effects of the electronic coupling and solvent relaxation time on the rates are also explored.     

Electron transfer in condensed media with mobile defects

A study has been made of electron transfer in a condensed polar medium containing two types of dynamically changing intrinsic parameters — static polarization and mobile defects, interacting locally with electronic states of the reactants. An expression has been obtained for the rate constant of a homogeneous, nonadiabatic, charge transfer reaction with allowance for large-scale and local fluctuations of the intrinsic parameters of the medium. It is shown that, along with fluctuations of the static polarization, Brownian motion of defects close to the reactants may lead to a significant variance of the electronic levels of the donor and acceptor.Translated from Teoreticheskaya i Éksperimental'naya Khimiya, Vol. 26, No. 4, pp. 406–413, July–August, 1990.     

Computational study on vapor phase coupling reaction between diiso(thio)cyanates with diamines,diols, and dithiols

Coupling between iso(thio)cyanates and amines, alcohols, and thiols to yield (thio)urea/urethane in the gas phase is important for the vacuum deposition processes of functional organic thin films such as molecular layer deposition or chemical vapor deposition. In this study, the kinetics and thermodynamics of 12 reactions between bifunctional reactants containing ? NCO/? NCS and ? NH₂/? OH/? SH moieties were calculated using double‐hybrid density functional theory to find systematic structure–reactivity relationships. The activation energy for the proton‐transfer step was correlated with the basicity of the nucleophile/Brønsted acid reactants, while the exothermicity of the coupling reaction depends on whether the other functionality is ? NCO or ? NCS. Analysis of the transition states revealed that the location of the transition state is affected by the basicity of the reactants. Vibrational and electronic spectra of the product were obtained to help future experimental investigations.     

Coherence in electron transfer pathways

Central to the view of electron-transfer reactions is the idea that nuclear motion generates a transition state geometry at which the electron/hole amplitude propagates coherently from the electron donor to the electron acceptor. In the weakly coupled or nonadiabatic regime, the electron amplitude tunnels through an electronic barrier between the donor and acceptor. The structure of the barrier is determined by the covalent and noncovalent interactions of the bridge. Because the tunneling barrier depends on the nuclear coordinates of the reactants (and on the surrounding medium), the tunneling barrier is highly anisotropic, and it is useful to identify particular routes, or pathways, along which the transmission amplitude propagates. Moreover, when more than one such pathway exists, and the paths give rise to comparable transmission amplitude magnitudes, one may expect to observe quantum interferences among pathways if the propagation remains coherent. Given that the effective tunneling barrier height and width are affected by the nuclear positions, the modulation of the nuclear coordinates will lead to a modulation of the tunneling barrier and hence of the electron flow. For long distance electron transfer in biological and biomimetic systems, nuclear fluctuations, arising from flexible protein moieties and mobile water bridges, can become quite significant. We discuss experimental and theoretical results that explore the quantum interferences among coupling pathways in electron-transfer kinetics; we emphasize recent data and theories associated with the signatures of chirality and inelastic processes, which are manifested in the tunneling pathway coherence (or absence of coherence).     

Two-Photon Photochemical Reactions of Aromatic Compounds in the Gas Phase

Studies on the gas-phase two-photon photochemistry of aromatic compounds performed in the past 25 years were summarized. Photophysical and photochemical unimolecular and bimolecular reactions occurring in the gas phase on the exposure of molecular systems (aliphatic aldehydes, ketones, and alcohols; aromatic hydrocarbons and their halogen derivatives; and heteroaromatic compounds with a conjugated -electron system) to pulsed laser UV radiation were considered. Data on the kinetics and mechanisms of primary two-photon photoexcitation, photodissociation, and photoionization of aromatic molecules were systematized, and the nature of electronically excited states responsible for these processes was determined. Data on the reactivity of transient species and on the kinetics of elementary steps of laser UV photolysis (bimolecular charge transfer and heavy particle transfer reactions and termolecular association and cluster ion formation reactions) were presented. General prerequisites to the stability of aromatic compounds under non-steady-state conditions of UV photolysis were found in accordance with the electronic structure of reactants and with the donor–acceptor properties of mixture components.     

Electrochemical examples of multiple-electron transfer

Various electroactive reactants that undergo multipleelectron transfer reactions at electrodes are divided into two broad classes. The first class exhibits a series of single electron steps at different electrode potentials. The second class exhibits multiple-electron transfer in a single voltammetric step. Examples from each class are offered and the reasons for their electrochemical behavior are described.