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Electron transfer, long range and orbital

Electron transfer, in thermal and photochemical activation of electron donor-acceptor complexes in organic and organometallic reactions, 29, 185 Electron transfer, long range and orbital interactions, 38, 1... [Pg.355]

Electron transfer, long range and orbital interactions, 38, 1... [Pg.358]

Fig. 1.25 Orbital comparison of long- and short-range quenching of an excited state (D ) and a ground state acceptor (A) by a Forster energy transfer (long-range), b Dexter energy transfer (short-range) and c photoinduced electron transfer (short range)... Fig. 1.25 Orbital comparison of long- and short-range quenching of an excited state (D ) and a ground state acceptor (A) by a Forster energy transfer (long-range), b Dexter energy transfer (short-range) and c photoinduced electron transfer (short range)...
Orbital interactions and long-range electron transfer, 38, 1 Organic materials for second-order non-linear optics, 32, 121 Organic reactivity, electron-transfer paradigm for, 35, 193 Organic reactivity, structure determination of, 35, 67 Orotidine monophosphate decarboxylase, the mechanism of, 38, 183... [Pg.359]

Electron transfer processes induce variations in the occupancy and/or the nature of orbitals which are essentially localized at the redox centers. However, these centers are embedded in a complex dielectric medium whose geometry and polarization depend on the redox state of the system. In addition, a finite delocalization of the centers orbitals through the medium is essential to-promote long-range electron transfers. The electron transfer process must therefore be viewed as a transition between two states of the whole system. The expression of the probability per unit time of this transition may be calculated by the general formahsm of Quantum Mechanics. [Pg.6]

Distance The affects of electron donor-acceptor distance on reaction rate arises because electron transfer, like any reaction, requires the wavefunctions of the reactants to mix (i.e. orbital overlap must occur). Unlike atom transfer, the relatively weak overlap which can occur at long distances (> 10 A) may still be sufficient to allow reaction at significant rates. On the basis of work with both proteins and models, it is now generally accepted that donor-acceptor electronic coupling, and thus electron transfer rates, decrease exponentially with distance kji Ve, exp . FCF where v i is the frequency of the mode which promotes reaction (previously estimated between 10 -10 s )FCF is a Franck Condon Factor explained below, and p is empirically estimated to range from 0.8-1.2 with a value of p 0.9 A most common for proteins. [Pg.160]

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Electron orbitals

Electron range

Electron transfer long range

Electron, orbiting

Long range

Long-range transfer

Orbital electrons

Orbitals electrons and

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