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Reaction CIDNP

Because the CIDNP effect is caused by the interplay of spin dynamics, diffusional dynamics, and chemical reactivity, information about each of these fields can be obtained from CIDNP experiments. CIDNP spectroscopy has proven extremely useful for studies of the former two aspects in systems with restricted diffusion (biradicals, and, to a lesser degree, micellar systems see Sections IV.C and IV.D). Concerning the rates and mechanisms of chemical reactions, CIDNP spectroscopy possesses several unique features, which make it a very powerful method. [Pg.101]

Another technique for the study of reactions that is highly specific for radical processes is known as CIDNP, an abbreviation for chemically induced dynamic nuclear polarization." The instrumentation required for such studies is a normal NMR spectrometer. CIDNP is observed as a strong perturbation of the intensity of NMR signals in products formed in certain types of free radical reactions. CIDNP is observed when the normal population of nuclear spin states dictated by the Boltzmann distribution is disturbed by the presence of an unpaired electron. The intense magnetic moment associated with an electron causes a polarization of nuclear spin states, which is manifested by enhanced absorption or emission, or both, in the NMR spectrum of the diamagnetic product of a free radical reaction. The technique is less general than EPR spectroscopy because not all free radicals can be expected to exhibit the phenomenon. [Pg.632]

The analysis of CIDNP effects allows information to be obtained on the structure and reactivity of active short-lived (from nanoseconds to microseconds) paramagnetic species (free radicals and radical ions, triplet excited molecules), and on molecular dynamics in the radical pair. The analysis makes it possible to distinguish between the bulk and in-cage stages of complex chemical reactions. CIDNP data also provide information on the multiplicities of reacting states, which is of utmost importance for understanding photochemical processes. [Pg.312]

The existence of the biradicals and the multipHcity of the surfaces on which these are formed have not been demonstrated directly however, experimental results (stereochemistry of the reaction, CIDNP [chemically induced dynamic nuclear polarization], radical trapping experiments, and quantum yield measurements) support their existence. Recently, the mechanism of 1,3-migration and oxa-di-Jt-methane reactions in terms of potential energy surface and decay funnels has been described this also supports the aforementioned mechanistic impHcations. The detailed mechanism, however, depends, in a very subtle way, on the structure of the chromophoric system and the presence of the functional groups. [Pg.1596]

CIDNP involves the observation of diamagnetic products fonned from chemical reactions which have radical intemiediates. We first define the geminate radical pair (RP) as the two molecules which are bom in a radical reaction with a well defined phase relation (singlet or triplet) between their spins. Because the spin physics of the radical pair are a fiindamental part of any description of the origins of CIDNP, it is instmctive to begin with a discussion of the radical-pair spin Hamiltonian. The Hamiltonian can be used in conjunction with an appropriate basis set to obtain the energetics and populations of the RP spin states. A suitable Hamiltonian for a radical pair consisting of radicals 1 and 2 is shown in equation (B1.16.1) below [12]. [Pg.1593]

Figure Bl.16.4. Part A is the vector representations of the. S state, an intennediate state, and the Jq state of a radical pair. Part B is the radical reaction scheme for CIDNP. Figure Bl.16.4. Part A is the vector representations of the. S state, an intennediate state, and the Jq state of a radical pair. Part B is the radical reaction scheme for CIDNP.
A general reaction scheme for CIDNP is shown in llgnre B1.16.4B. where the radical dynamics in each region... [Pg.1595]

The radical cation of 1 (T ) is produced by a photo-induced electron transfer reaction with an excited electron acceptor, chloranil. The major product observed in the CIDNP spectrum is the regenerated electron donor, 1. The parameters for Kaptein s net effect rule in this case are that the RP is from a triplet precursor (p. is +), the recombination product is that which is under consideration (e is +) and Ag is negative. This leaves the sign of the hyperfine coupling constant as the only unknown in the expression for the polarization phase. Roth et aJ [10] used the phase and intensity of each signal to detemiine the relative signs and magnitudes of the... [Pg.1601]

As for CIDNP, the polarization pattern is multiplet (E/A or A/E) for each radical if Ag is smaller than the hyperfme coupling constants. In the case where Ag is large compared with the hyperfmes, net polarization (one radical A and the other E or vice versa) is observed. A set of mles similar to those for CIDNP have been developed for both multiplet and net RPM in CIDEP (equation (B1.16.8) and equation (B1.16.9)) [36]. In both expressions, p is postitive for triplet precursors and negative for singlet precursors. J is always negative for neutral RPs, but there is evidence for positive J values in radical ion reactions [37]. In equation (B 1.16.8),... [Pg.1607]

Maeda K, Terazima M, Azumi T and Tanimoto Y 1991 CIDNP and CIDEP studies on intramolecular hydrogen abstraction reaction of polymethylene-linked xanthone and xanthene. Determination of the... [Pg.1620]

One aspect of both EPR and CIDNP studies that should be kept in mind is that either is capable of detecting very small amounts of radical intermediates. This sensitivity makes both techniques quite useful, but it can also present a pitfall. The most prominent features of either EPR or CIDNP spectra may actually be due to radicals that account for only minor amounts of the total reaction process. An example of this was found in a study of the decomposition of trichloroacetyl peroxide in alkenes. [Pg.671]

Observation of CIDNP effects in the resonances of either reactant or product species in the NMR spectrum of the reaction mixture. [Pg.195]

The kinetics of the decomposition of the 4-chlorobenzenediazonium ion under strict exclusion of oxygen (< 5 ppb 02, Schwarz and Zollinger, 1981) are compatible with the CIDNP results, subject to the reservation mentioned already, namely that CIDNP as a probe does not necessarily give results for all pathways, whereas kinetic measurements are normally related to the sum of all competitive mechanisms. The first reaction observable with conventional kinetic methods is the formation of the (E )-diazoate (t1/2 ca. 200 min), but it is also first-order with respect to the diazonium ion concentration. [Pg.204]

In another investigation (Loewenschuss et al., 1976) dediazoniation was studied in TFE and in acetonitrile in the presence of pyridine. There is UV and NMR evidence for the formation of a diazopyridinium cation in addition, -CIDNP absorption and emission signals were observed. Systems containing diazonium salts and pyridine are important in industrial chemistry, as pyridine is used as a proton acceptor in the diazo coupling reaction (see Sec. 12.8) in a considerable number of syntheses of azo dyes. At the same time pyridine has an unfavorable effect on the yield because of the competing homolytic dediazoniation. [Pg.206]

In triethylamine instead of benzene the reaction products are completely different, and are indicative of a homolytic process involving an initial electron transfer from triethylamine followed by a hydrogen atom transfer. Scheme 10-68 gives the major products, namely 1,3,5-tri-tert-butylbenzene (10.36, 20%), the oxime 10.39 (18%), formed from the nitroso compound 10.38, and the acetanilide 10.37 (40%). ESR and CIDNP data are consistent with Scheme 10-68. In their paper the authors discuss further products which were found in smaller yields. [Pg.256]

Chlorosulfo-de-diazoniation 241 CIDNP, see Dediazoniations Cinnamic acid derivatives, reaction with ArNj 243 Cinnolines 140 f. [Pg.447]

CIDNP 874, 879, 1070 Claisen-type condensation 259 a-Cleavage, photochemical 875-877 Conjugate addition reactions 778, 783-785, 788... [Pg.1198]

The first reports of the observation of transient emission and enhanced absorption signals in the H-n.m.r. spectra of solutions in which radical reactions were taking place appeared in 1967. The importance of the phenomenon, named Chemically Induced Dynamic Nuclear Spin Polarization (CIDNP), in radical chemistry was quickly recognized. Since that time, an explosive growth in the number of publications on the subject has occurred and CIDNP has been detected in H, C, N, and P as well as H-n.m.r. spectra. Nevertheless, the number of groups engaged in research in this area is comparatively small. This may be a consequence of the apparent complexity of the subject. It is the purpose of this review to describe in a quahtative way the origin of CIDNP and to survey the published applications of the phenomenon in... [Pg.53]

Potential applications of CIDNP thus span the whole breadth of chemistry from organic reactions to the physical chemistry of the liquid state. A progress report seems timely. Other, rather more limited reviews have appeared (Gloss, 1971b Fischer, 1971 a Buchachenko and Zhidomirov, 1971 Iwamura, 1971 Ward, 1972 Lawler, 1972). [Pg.54]

See other pages where Reaction CIDNP is mentioned: [Pg.23]    [Pg.322]    [Pg.450]    [Pg.508]    [Pg.1562]    [Pg.23]    [Pg.322]    [Pg.450]    [Pg.508]    [Pg.1562]    [Pg.1590]    [Pg.1591]    [Pg.1597]    [Pg.1604]    [Pg.1607]    [Pg.670]    [Pg.189]    [Pg.202]    [Pg.204]    [Pg.278]    [Pg.367]    [Pg.367]    [Pg.370]    [Pg.389]    [Pg.708]    [Pg.879]    [Pg.908]    [Pg.1070]    [Pg.1076]    [Pg.1097]    [Pg.1102]    [Pg.56]    [Pg.56]    [Pg.57]   
See also in sourсe #XX -- [ Pg.318 ]



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