✦ LIBER ✦

On the transition from electronically nonadiabatic to solvent-controlled electron transfer

✍ Scribed by Dmitrii E. Makarov; Maria Topaler

Publisher: Elsevier Science
Year: 1995
Tongue: English
Weight: 505 KB
Volume: 245
Category: Article
ISSN: 0009-2614
DOI: 10.1016/0009-2614(95)01035-8

No coin nor oath required. For personal study only.

✦ Synopsis

Path integral techniques are used to study a simple model of barrierless electron transfer where the energy gap between two electronic states is subject to Gaussian random noise induced by solvent fluctuations. The kinetics of electron transfer are related to the statistics of zero-crossings of the noise. We argue that these statistics are different in the cases of Markovian and non-Markovian Gaussian-correlated noise, leading to qualitatively different types of transition from electronically nonadiabatic to solvent-controlled electron transfer. We also demonstrate that for the typical situation where solvent relaxation consists of a fast inertial Gaussian-correlated and a slow exponentially relaxing component, the rate of electron transfer is primarily controlled by the fast component.

📜 SIMILAR VOLUMES

On the transition from electronically no

On the transition from electronically nonadiabatic to solvent-controlled electron transfer (Chem. Phys. Letters 245 (1995) 343)

✍ D.E. Makarov; M. Topaler 📂 Article 📅 1996 🏛 Elsevier Science 🌐 English ⚖ 23 KB

Electron Transfer from Solvent to a Trip

Electron Transfer from Solvent to a Triplet Excited Acceptor Molecule

✍ Prof. Dr. Günther Briegleb; Dr. Helmut Schuster 📂 Article 📅 1970 🏛 John Wiley and Sons 🌐 English ⚖ 198 KB 👁 2 views

ChemInform Abstract: Electron Localizati

ChemInform Abstract: Electron Localization and the Transition from Adiabatic to Nonadiabatic Charge Transport in Organic Conductors

✍ Sven Stafstroem 📂 Article 📅 2010 🏛 John Wiley and Sons ⚖ 15 KB 👁 2 views

A special solvent effect of acetonitrile

A special solvent effect of acetonitrile on the electron transfer from triethylamine to triplet anthraquinone

✍ K. Hamanoue; T. Nakayama; K. Sugiura; H. Teranishi; M. Washio; S. Tagawa; Y. Tab 📂 Article 📅 1985 🏛 Elsevier Science 🌐 English ⚖ 43 KB

Electronic structure of the lithium molecular anion, fir, Chem. Phys. Letters 118 (1985) 67. Due to typographical errors the following corrections should be made: Eq. (4) should read in part: V(R+=)r-=-.\_\_\_ 2R4 In table 3, D, of the present work for X 2Zz should read 6714.0. \*\*\* A. Stromberg,

A special solvent effect of acetonitrile

A special solvent effect of acetonitrile on the electron transfer from triethylamine to triplet anthraquinone

✍ Kumao Hamanoue; Toshihiro Nakayama; Kazuaki Sugiura; Hiroshi Teranishi; Masakazu 📂 Article 📅 1985 🏛 Elsevier Science 🌐 English ⚖ 328 KB

The photoreduction of antluaquinone (AQ) by triethylamine in acetonittile was found IO ongmsle rrom LWO Independent prm: The free radical anion of AQ and the exiplex lxlween triethylamme and AQ were produced via Ihe second and tic lowest triplet stales 01 AQ. respectively.

Solvent motion controls the rate of intr

Solvent motion controls the rate of intramolecular electron transfer in solution

✍ Edward M. Kosower; Dan Huppert 📂 Article 📅 1983 🏛 Elsevier Science 🌐 English ⚖ 263 KB