Magnetic field effect as a probe of distance-dependent electron transfer in systems undergoing free diffusion

KRISSINEL, E. B.

doi:10.1080/002689799164919

Cited by 8 publications

(20 citation statements)

References 27 publications

(43 reference statements)

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“…In such RIPs having a long D-A distance, the exchange interaction may be so small that ISC from the singlet to the triplet states is reduced by H, as shown in solution [27,28] and at crystal surfaces [29]. Since the population of the singlet RIPs relative to that of the triplet RIPs becomes higher in the presence of H, exciplex fluorescence reduced by F is recovered to some extent in the presence of H; E-F-I-Q of the exciplex fluorescence becomes less in the presence of H. As already mentioned, it is also considered that fluorescent exciplex in type (I) is formed not only from RIP produced by PIET but also from a contact pair of the LE state, i.e., (D*…A) in Figure 1, since E-F-I-Q of the LE fluorescence, which leads to E-F-I-E of the number of RIPs produced by PIET, does not induce an enhancement of the exciplex fluorescence [61].…”

Section: Discussionmentioning

confidence: 99%

Magnetic field effects on electro-photoluminescence of photoinduced electron transfer systems in a polymer film

Awasthi

Ohta

2011

Journal of Photochemistry and Photobiology A: Chemistry

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Magnetic field effects on photoluminescence (PL) in the presence of external electric fields have been examined for a variety of electron donor and acceptor pairs, either linked with methylene chain or randomly distributed in polymethyl methacrylate (PMMA) films, which show intermolecular photoinduced electron transfer (PIET). Application of electric fields changes the energy separation among different electronic states, because the electric dipole moment at the state under consideration is usually different from the others. The energy levels within the same spin multiplicity are also shifted or splitted by application of magnetic field. Then, simultaneous application of electric field and magnetic field induces interesting effects on PL which cannot be observed when only electric field or magnetic field is applied to molecules. In this article, experimental results of the magnetic field effect of the electric field effect both on LE fluorescence and on exciplex fluorescence resulting from PIET are presented, and the mechanism of the synergy effects of the electric and magnetic fields on PL are discussed. The hyperfine interaction of the various radical-ion pairs produced by PIET has been also determined on the basis of the synergy effects on PL, and the results are compared with the calculated values.

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Section: Discussionmentioning

confidence: 99%

Magnetic field effects on electro-photoluminescence of photoinduced electron transfer systems in a polymer film

Awasthi

Ohta

2011

Journal of Photochemistry and Photobiology A: Chemistry

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“…This is appropriate for some systems in zero or relatively small external magnetic fields. Otherwise the basis of the problem should be essentially extended and a more complex theory of coherent spin transitions must be incorporated in IET, as was done for different goals in refs and .…”

Section: Discussionmentioning

confidence: 99%

“…as a summer school student, allowing him to successfully work on this paper. The numerical simulations were performed with the help of a computer program, QYield, developed by E. B. Krissinel, which was previously used for studying the spin-affected reaction of forward and backward transfer in ref .…”

Section: Acknowledgmentsmentioning

confidence: 99%

Reversible Photoionization in Liquid Solutions

2001

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The Stern-Volmer constant of fluorescence quenching by reversible intermolecular charge transfer is obtained by means of integral encounter theory. The latter provides the first non-Markovian description of the phenomenon which accounts for the reversibility of excited-state ionization. The forward and backward electron transfers (bimolecular and geminate) are specified by the position-dependent rates of ionization and recombination. Assuming that the conventional free energy gap law is inherent to all of them, a reasonable explanation is given for the famous Rehm and Weller free energy dependence of the Stern-Volmer constant. It requires the production of ions in excited states when forward electron transfer is highly exergonic and implies that the charge recombination occurs not only to the ground but also to the excited triplet state. It is assumed that spin conversion in the radical ion pairs is faster than the geminate recombination.

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“…1−4 The mechanisms of MFEs including the hyperfine coupling mechanism, the Δg mechanism, the level-crossing mechanism, the triplet mechanism, the spin relaxation mechanism, and low-field effects have been well established by reliable experimental measurements and through the development of theory of spin dynamics, which are also associated with the generation of chemically induced magnetic polarizations. 1,4 It has been suggested and demonstrated that RP dynamics in the absence and presence of magnetic fields are rich in information not only regarding the mechanisms of MFEs 5−7 but also regarding spatial RP motions in various media such as uniform solutions, 8,9 micelles, 10−13 proteins, 14 and ionic liquids. 15,16 Transient absorption spectroscopy, in which the absorption of transient radicals can be observed with high time resolution, is surely the first choice for the direct observation of RP dynamics under magnetic fields.…”

Section: ■ Introductionmentioning

confidence: 99%

Time-Resolved Detection of Magnetic Field Effects on Radical Pairs in Micelles: Two-Step Two-Laser Fluorescence Spectroscopy of Transient Radicals

2015

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A two-step two-laser fluorescence spectroscopy method was employed to enable time-resolved detection of magnetic field effects (MFEs) on radical pairs (RPs). In the photoinduced hydrogen abstraction reaction of benzophenone (BP) in sodium dodecyl sulfate (SDS) micellar solution, fluorescence from the BP ketyl radical (BPH•) was observed under various magnetic fields; BPH• forms RPs with hydrogen-abstracted SDS radicals (•SDS) in the micelles. Kinetic parameters of the RP dynamics such as the spin relaxation rate, the generation rate, and the escape rate were determined from the simple analysis. The MFEs on BPH• observed from the fluorescence measurements were explained by the spin relaxation mechanism proposed by Hayashi and Nagakura. In this study, we demonstrate that two-step two-laser fluorescence spectroscopy in combination with a magnetic field provides valuable information about photochemical reactions in which RPs play important roles. ■ INTRODUCTIONRadicals and radical pairs (RPs) are common short-lived intermediates in various photochemical reactions. A magnetic field can alter the reactivity of a RP, thereby affecting the yields of photochemical products. A unique aspect of such magnetic field effects (MFEs) on RPs is that the magnetic field can change the rate of RP reactions that proceed via the activated states of the reactions, although the magnetic energy of the RP is much smaller than the thermal energy. For this reason, MFEs on photochemical reactions involving RPs have attracted considerable attentions since the mid 1970s and have been studied by various quantitative measurements such as product analysis, steady-state and transient absorption spectroscopy, and fluorescence spectroscopy. 1−4 The mechanisms of MFEs including the hyperfine coupling mechanism, the Δg mechanism, the level-crossing mechanism, the triplet mechanism, the spin relaxation mechanism, and low-field effects have been well established by reliable experimental measurements and through the development of theory of spin dynamics, which are also associated with the generation of chemically induced magnetic polarizations. 1,4 It has been suggested and demonstrated that RP dynamics in the absence and presence of magnetic fields are rich in information not only regarding the mechanisms of MFEs 5−7 but also regarding spatial RP motions in various media such as uniform solutions, 8,9 micelles, 10−13 proteins, 14 and ionic liquids. 15,16 Transient absorption spectroscopy, in which the absorption of transient radicals can be observed with high time resolution, is surely the first choice for the direct observation of RP dynamics under magnetic fields. In transient absorption measurements, however, the absorption of the photoexcited states, which are precursors of the radicals, is often overlapped with the absorption of the radicals. In such situations, it is difficult to distinguish the RP dynamics from the excited-state ones. To measure complete RP dynamics, it is necessary to choose an adequate photochemical reaction in which the absor...

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Magnetic field effect as a probe of distance-dependent electron transfer in systems undergoing free diffusion

Cited by 8 publications

References 27 publications

Magnetic field effects on electro-photoluminescence of photoinduced electron transfer systems in a polymer film

Magnetic field effects on electro-photoluminescence of photoinduced electron transfer systems in a polymer film

Reversible Photoionization in Liquid Solutions

Time-Resolved Detection of Magnetic Field Effects on Radical Pairs in Micelles: Two-Step Two-Laser Fluorescence Spectroscopy of Transient Radicals

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