Benzophenone radical ion

Sodium benzophenone ketyl Benzophenone, radical ion (1 —), sodium (8) Methanone, diphenyl-, radical ion (1-), sodium (9) (3463-17-0)... 

Lithium aluminum hydride Aluminate (1-), tetrahydro-, lithium (8) Aluminate (1-), tetrahydro-, lithium, (T-4)- (9) (16853-85-3) Sodium benzophenone ketyl Benzophenone, radical ion (1-), sodium (8), Methanone, diphenyl-, radical ion (1-), sodium (9), (3463-17-0)... 

In the ensuing discussion, the energy dependence of the rate constants for proton transfer within a variety of substituted benzophenone-lV, /V-dimethylaniline contact radical ion pairs is examined only the data for the nitrile solvents are discussed. This functional relationship is examined within the context of theories for non-adiabatic proton transfer. Finally, these results are viewed from the perspective of other proton-transfer studies that examine the energy dependence of the rate constants. 

The enthalpy changes associated with proton transfer in the various 4, -substituted benzophenone contact radical ion pairs as a function of solvent have been estimated by employing a variety of thermochemical data [20]. The effect of substituents upon the stability of the radical IP were derived from the study of Arnold and co-workers [55] of the reduction potentials for a variety of 4,4 -substituted benzophenones. The effect of substituents upon the stability of the ketyl radical were estimated from the kinetic data obtained by Creary for the thermal rearrangement of 2-aryl-3,3-dimethylmethylenecyclopropanes, where the mechanism for the isomerization assumes a biradical intermediate [56]. The solvent dependence for the energetics of proton transfer were based upon the studies of Gould et al. [38]. The details of the analysis can be found in the original literature [20] and only the results are herein given in Table 2.2. 

ESR and CIDNP studies intended to detect the radical intermediates failed [63], Conjugate addition of a vinylcuprate reagent to an enone takes place with retention of the vinyl geometry indicating that no vinyl radical intermediate is involved [64, 65], Kinetic isotope effects and substituent effects in cuprate addition to benzophenone indicate that C-C bond formation is rate-determining, which is not consistent with the involvement of a radical ion pair intermediate [66]. 

In summary, although the BH model predicts an inverted region for the kinetics of proton in the nonadiabatic regime, the BH model is only in qualitative accord with the data derived from the proton transfer within the benzophenone-N, A -dimethylaniline contact radical ion pairs. The failure of the model lies in its ID nature as it does not take into account the degrees of freedom for the vibrations associated with the proton-transfer mode. By incorporating these vibrations into the BH model, the LH model provides an excellent account of the parameters serving to control the kinetics of nonadiabatic proton transfer. A more rigorous test for the LH model will come when the kinetic deuterium isotope effects for benzophenone-A, A -dimethylaniline contact radical ions are examined as well as the temperature dependence of these processes are measured. 

Luminescence is seldom observed from free radicals and radical ions because of the low energy of the lowest excited states of open-shell species, the benzophenone ketyl radical being however a noteworthy exception. There are few reports of actual photochemical reactions of free radicals, but the situation is different with biradicals such as carbenes. These have two unpaired electrons and can exist in singlet or triplet states and they take part in addition and insertion reactions (Figure 4.90). 

A significant enhancement of reactivity of the carbonyl compound by complexation with Mg2+ has also been applied to a novel type of carbon-carbon bond formation via photoinduced electron transfer from unsymmet-rically substituted acetal (5) with benzophenone (6) (Scheme 26) [211]. This photochemical reaction takes place in the absence of Mg2+ in MeCN. However, the yield of the desired carbon-carbon coupling product 7 is only 15% together with radical dimers 8 (28%) and 9 (2%). Addition of Mg(C104)2 to this system results in a much higher yield of 7 (e.g., 78%) at the expense of radical dimer formation [211]. Thus, the initial photoinduced electron transfer may be catalyzed by Mg2+ to produce a radical ion pair (6 "-Mg2+5 +), where 6 is stabilized by the complexation with Mg2+, as shown in Scheme 26 [211]. The efficient C-C bond formation occurs in the radical ion pair, followed by cyclization before and after desilylation to produce various types of products (Scheme 26). 

As with arene-amine radical ion pairs, the ion pairs formed between ketones and amines can also suffer a-deprotona-tion. When triplet benzophenone is intercepted by amino acids, the aminium cation radical can be detected at acidic pH, but only the radical formed by aminium deprotonation is detectable in base (178). In the interaction of thioxanthone with trialky lamines, the triplet quenching rate constant correlates with amine oxidation potential, implicating rate determining radical ion pair formation which can also be observed spectroscopically. That the efficiency of electron exchange controls the overall reaction efficiency is consistent with the absence of an appreciable isotope effect when t-butylamine is used as an electron donor (179). 

Chemical evidence for the existence of electrons in irradiated cyclohexane was obtained from pulse radiolysis studies of solutions containing aromatic solutes27. Because of the lifetime of the pulse these experiments only allowed the determination of ions still surviving after 10 6 sec. With benzophenone and anthracene as scavengers transient absorption peaks at 700 nm and 730 nm respectively, were obtained. These were consistent with the known spectra of the benzophenone and anthracene radical ions and are most simply accounted for by assuming direct electron capture by these solutes. Positively charged ion radicals may also be produced since these are likely to have similar spectra. Ion yields can be calculated since the absorption coefficients are known, but these yields necessarily represent the sum of the positive and negative ion yields. Some results are shown in Fig. 3. 

Fig. 3. Radical ion yields in irradiated liquid cyclohexane ( - ), benzophenone (O-O),...

The dynamics of proton transfer within a variety of substituted benzophenone-iV-methylacridan contact radical ion pairs [e.g. (53)] in benzene have been examined.156 Correlation of the rate constants for proton transfer with the thermodynamic driving force has revealed both normal and inverted regions for proton transfer in benzene. 

The second example concerns a photo-induced e.t. with this same chemical system, to which an amine (e.g. DABCO) is added as an electron donor. The fast decay to the relaxed triplet excited state of benzophenone remains unchanged, but this is now followed by two further reactions the forward e.t. step which forms the radical ions, and the back e.t. of these ions to restore the initial system. 

There is evidence [19] that the initial absorption at ca. 720 nm within 25 ps belongs to a kind of SSIP of benzophenone radical anion and dimethylaniline radical cation. This peak shifts during 200 — 800 ps to 690 nm. The blue shift corresponds to the formation of the thermodynamically more stable contact ion pair, identified according to work by Hogen-Esch and Smid [20]. Finally the ketyl radical is observed at 545 nm after ca. 2000 ps. 

The analysis of similar processes with benzophenone (1) and benzil (7) requires a higher time resolution of the experimental setup. Using ns-laser flash photolysis, we observed the formation of radical ion intermediates, depending on solvent polarity, added salts and competing H-abstraction [36]. Summarizing all these experiments, one can draw the following conclusions (cf. Figs. 3—5, see also Ref. [33]) ... 

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