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Photoproduction

As always, the photooxidation of water to 2 has received much less attention than the much easier photoreduction of water to H2 However, some notable achievements have appeared and genuine progress has been made. The mechanisms for oxidation of water by metalloporphyrins and cobalt(III) ammines have been studied, with particular attention being given to kinetic parameters. Several new 02 evolving catalysts have been [Pg.530]

4 -dicarboxylic acid)ruthenium(II) which permits detailed [Pg.530]

Much fundamental work, concerned mostly with the mechanism and kinetics of photoinduced electron transfer in polar medium, has been reported that helps in the design of new solar energy storage systems. General treatments of electron transfer [Pg.531]

With flexible bridges, conformational parameters become. 126-129 [Pg.532]

This year has seen increased employment for polymer bound reactants. Both sensitiser, usually tris(2,2 -bipyridyl)ruthenium(II), and electron relay, usually a viologen derivative, have been attached to a polymer backbone. [Pg.533]


Fig. 5. Chemistry of cyclized mbbei—bis-a2ide negative acting resist, (a) Preparation of cyclized mbber resin from polyisoprene (b) photochemistry of aromatic bis-a2ide sensiti2ers. The primary photoproduct is a highly reactive nitrene which may combine with molecular oxygen to form oxygenated products, or may react with the resin matrix by addition or insertion to form polymer—polymer linkages. Fig. 5. Chemistry of cyclized mbbei—bis-a2ide negative acting resist, (a) Preparation of cyclized mbber resin from polyisoprene (b) photochemistry of aromatic bis-a2ide sensiti2ers. The primary photoproduct is a highly reactive nitrene which may combine with molecular oxygen to form oxygenated products, or may react with the resin matrix by addition or insertion to form polymer—polymer linkages.
The solubHity properties of the PAG itself can play an important role in the overaH resist performance as weU (50). SolubHity differences between the neutral onium salt and the acidic photoproducts can be quite high and wHl affect the resist contrast. In fact onium salts can serve as dissolution inhibitors in novolac polymers, analogous to diazonaphthoquinones, even in the absence of any acid-sensitive chemical function (51). [Pg.124]

Irradiation of ethyleneimine (341,342) with light of short wavelength ia the gas phase has been carried out direcdy and with sensitization (343—349). Photolysis products found were hydrogen, nitrogen, ethylene, ammonium, saturated hydrocarbons (methane, ethane, propane, / -butane), and the dimer of the ethyleneimino radical. The nature and the amount of the reaction products is highly dependent on the conditions used. For example, the photoproducts identified ia a fast flow photoreactor iacluded hydrocyanic acid and acetonitrile (345), ia addition to those found ia a steady state system. The reaction of hydrogen radicals with ethyleneimine results ia the formation of hydrocyanic acid ia addition to methane (350). Important processes ia the photolysis of ethyleneimine are nitrene extmsion and homolysis of the N—H bond, as suggested and simulated by ab initio SCF calculations (351). The occurrence of ethyleneimine as an iatermediate ia the photolytic formation of hydrocyanic acid from acetylene and ammonia ia the atmosphere of the planet Jupiter has been postulated (352), but is disputed (353). [Pg.11]

Fig. 22. Photochemical hole burning (PHB) (1,173) where CO is frequency CO, frequency of the laser and CO p, frequency of the photoproduct. Fig. 22. Photochemical hole burning (PHB) (1,173) where CO is frequency CO, frequency of the laser and CO p, frequency of the photoproduct.
The effects of uv radiation on V/-nitroso compounds depend on the pH and the medium. Under neutral conditions and ia the absence of radical scavengers, these compounds often appear chemically stable, although the E—Z equiUbrium, with respect to rotation around the N—N bond, can be affected (70). This apparent stabiUty is due to rapid recombination of aminyl radicals and nitric oxide [10102-43-9] formed duting photolysis. In the presence of radical scavengers nitrosamines decay rapidly (71). At lower pH, a variety of photoproducts are formed, including compounds attributed to photoelimination, photoreduction, and photo-oxidation (69). Low concentrations of most nitrosamines, even at neutral pH, can be eliminated by prolonged kradiation at 366 nm. This technique is used ki the identification of /V-nitrosamines that are present ki low concentrations ki complex mixtures (72). [Pg.108]

Catalysis (qv) refers to a process by which a substance (the catalyst) accelerates an otherwise thermodynamically favored but kiaeticahy slow reaction and the catalyst is fully regenerated at the end of each catalytic cycle (1). When photons are also impHcated in the process, photocatalysis is defined without the implication of some special or specific mechanism as the acceleration of the prate of a photoreaction by the presence of a catalyst. The catalyst may accelerate the photoreaction by interaction with a substrate either in its ground state or in its excited state and/or with the primary photoproduct, depending on the mechanism of the photoreaction (2). Therefore, the nondescriptive term photocatalysis is a general label to indicate that light and some substance, the catalyst or the initiator, are necessary entities to influence a reaction (3,4). The process must be shown to be truly catalytic by some acceptable and attainable parameter. Reaction 1, in which the titanium dioxide serves as a catalyst, may be taken as both a photocatalytic oxidation and a photocatalytic dehydrogenation (5). [Pg.398]

The concept and use of free radical attack on pyrimidines has been little developed. However, pyrimidine does react slowly with p-nitrobenzenediazonium chloride to yield some 2- and 4-p-nitrophenylpyrimidines (51JCS2323) in addition, 2,4-and 4,6-dimethyl-pyrimidine are converted by hydroxymethylene radicals (from ammonium peroxydisul-fate/methanol) into 6- and 2-hydroxymethyl derivatives, respectively (77H(6)525). Certain bipyrimidine photoproducts appear to be formed from two similar or dissimilar pyrimidinyl radicals (see Section 2.13.2.1.4). [Pg.73]

As mentioned above (Section 2.13.2.1.3), bipyrimidine photoproducts can arise, probably by reaction between two radicals. Thus, irradiation of an aqueous solution of 5-bromouracil (ill R=Br) in the absence of oxygen produces a variety of products including uracil, barbituric acid, 5-carboxyuracil (111 R = CO2H), several non-pyrimidine compounds and, as a stable end-product, the biuracil (114 R = H). A similar product (114 R = Me) is formed from 5-bromo-l,3-dimethyluracil (ilS). When two such related uracil derivatives are irradiated together, a mixed bipyrimidine product is formed, inter alia (B-76MI21302). [Pg.74]

Whereas the cycloaddition of arylazirines with simple alkenes produces A -pyrrolines, a rearranged isomer can be formed when the alkene and the azirine moieties are suitably arranged in the same molecule. This type of intramolecular photocycloaddition was first detected using 2-vinyl-substituted azirines (75JA4682). Irradiation of azirine (54) in benzene afforded a 2,3-disubstituted pyrrole (55), while thermolysis gave a 2,5-disubstituted pyrrole (56). Photolysis of azirine (57) proceeded similarly and gave 1,2-diphenylimidazole (58) as the exclusive photoproduct. This stands in marked contrast to the thermal reaction of (57) which afforded 1,3-diphenylpyrazole (59) as the only product. [Pg.56]

Nitrile ylides derived from the photolysis of 1-azirines have also been found to undergo a novel intramolecular 1,1-cycloaddition reaction (75JA3862). Irradiation of (65) gave a 1 1 mixture of azabicyclohexenes (67) and (68). On further irradiation (67) was quantitatively isomerized to (68). Photolysis of (65) in the presence of excess dimethyl acetylenedicar-boxylate resulted in the 1,3-dipolar trapping of the normal nitrile ylide. Under these conditions, the formation of azabicyclohexenes (67) and (68) was entirely suppressed. The photoreaction of the closely related methyl-substituted azirine (65b) gave azabicyclohexene (68b) as the primary photoproduct. The formation of the thermodynamically less favored endo isomer, i.e. (68b), corresponds to a complete inversion of stereochemistry about the TT-system in the cycloaddition process. [Pg.58]

In the case of cycloheptenone and larger rings, the main initial photoproducts are the -cycloalkenones produced by photoisomerization. In the case of the seven- and eight-membered rings, the double bonds are sufficiently strained that rapid reactions follow. In nonnucleophilic solvents dimerization occurs, whereas in nucleophilic solvents addition occurs. ... [Pg.762]

These compounds are not direct photoproducts, however. The compounds of structure 9 arise by solvolysis of benzvalene, the initial photoproduct. Products of type 10 are secondaiy photoproducts derived from 9. ... [Pg.779]

These various photoproducts are all valence isomers of the normal benzenoid structure. These alternative bonding patterns are reached from the excited state, but it is difficult to specify a precise mechanism. The presence of the t-butyl groups introduces a steric factor that works in favor of the photochemical valence isomerism. Whereas the t-butyl groups are coplanar with the ring in the aromatic system, the geometry of the bicyclic products results in reduced steric interactions between adjacent t-butyl groups. [Pg.780]

Suggest a reasonable pathway for the formation of each of the photoproducts formed on irradiation of the Diels-Alder adduct of 2,3-dimethylbutadiene and quinone ... [Pg.788]

The intervention of mesoionic intermediates is suggested by the facile transformation of steroidal dienones, and by a number of acid-catalyzed nonphotolytic reactions which either parallel the photoisomerizations or correlate photoproducts from reactions in protic and aprotic solvents. The isomerization (175) -> (176) -l- (177) has also beeen achieved in the dark by acetic and formic acid catalysis and clearly involves the conjugate acid of the proposed mesoionic intermediate (199) in the dark reaction. Further,... [Pg.332]

These results were justified by assuming that the first photoproduct of the reaction was cyclopropene-3-carbaldehyde. This compound can be obtained via... [Pg.43]

In the photochemical isomerization of isoxazoles, we have evidence for the presence of the azirine as the intermediate of this reaction. The azirine is stable and it is the actual first photoproduct of the reaction, as in the reaction of r-butylfuran derivatives. The fact that it is able to interconvert both photochemically and thermally into the oxazole could be an accident. In the case of 3,5-diphenylisoxazole, the cleavage of the O—N bond should be nearly concerted with N—C4 bond formation (8IBCJ1293) nevertheless, the formation of the biradical intermediate cannot be excluded. The results of calculations are in agreement with the formation of the azirine [9911(50)1115]. The excited singlet state can convert into a Dewar isomer or into the triplet state. The conversion into the triplet state is favored, allowing the formation of the biradical intermediate. The same results [99H(50)1115] were obtained using as substrate 3-phenyl-5-methylisoxazole (68ACR353) and... [Pg.59]

In agreement with the previously reported theoretical study, the results of semi-empirical calculations showed that the formation of the Dewar isomer is favored [99H(50)1115]. Probably, the observed formation of the azirine derives from a thermal isomerization of the first photoproduct, in line with that described in the case of furan and thiophene derivatives (Fig. 11). [Pg.64]

Indications fliat endogenous AHR hgand(s) may be derived from tryptophan have been reported repeatedly (87JBC15422 91MI5 98MI6 OOMIl 1). This implies fliat the tryptophan photoproduct 202 and molecules with a similar sbuctural framework are the most likely candidates as endogenous ligands for the AHR. [Pg.54]

Irradiation of 1-benzothiepins 1 in tetrahydrofuran with a high-pressure 450-W mercury lamp and a Pyrex filter at 0"C for four hours results in a reversal of the thiepin-synthesis method startingfrom 3,4-benzo-2-thiabicyclo[3.2.0]hept-3,6-dienes (see Section 2.1.3.3.), giving the photoproducts 2 along with some of the corresponding naphthalenes.1019... [Pg.104]

Prolonged irradiation of 1-benzothiepins 3 results in the formation of the secondary photoproducts 4 via a diradical photorearrangement.12,95... [Pg.104]

Morishima et al. [30, 50-54, 73-76] have made extensive investigations on photoinduced ET, using polycyclic aromatic chromophores covalently attached to polyelectrolytes. They were the first to show that the polyeletrolyte molecular surface provides an unusual microenvironment which greatly changes the rate of photoinduced ET and the fate of the charged photoproducts. [Pg.69]

Scheme 1 represents the kinetics of a photoinduced ET system including ground-state complexation. Within the DA complex an almost simultaneous back-reaction would occur (step 1). Therefore, the CT complexation causes the yield of the photoproducts to decrease. In this scheme, (Dsf. .. As" denotes a... [Pg.80]


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See also in sourсe #XX -- [ Pg.15 , Pg.21 ]

See also in sourсe #XX -- [ Pg.159 ]




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6-4 Pyrimidine-pyrimidone photoproduct

Benzene photoproducts

Catalysts photoproducts

Dissolved Organic Matter Photoproduct Formation Ecologically Significant

Electrostatic interactions, control photoproducts

Fries, photoproducts

Fries, photoproducts reaction

H2, photoproduction

Intermediate photoproducts

Iron, tris in photoproduction of oxygen from water

Labile photoproducts

Metallophthalocyanines in photoproduction of hydrogen from water

Metalloporphyrins in photoproduction of hydrogen from water

Molecular hydrogen, photoproduction

Organic photoproducts

Oxygen photoproduction from water

Phenolic photoproducts

Photolysis mechanism photoproducts

Photoproduct

Photoproduct

Photoproduct accumulation

Photoproduct distributions

Photoproduct motion

Photoproduction of H from Water

Photoproduction of Hydrogen from Hydrocarbons

Photoproduction successive

Photoproduction, hydrogen

Photoproducts

Photoproducts analysis

Photoproducts solutions, quantum yields

Photoproducts, DNA

Platinum in photoproduction of hydrogen from water

Platinum oxides in photoproduction of hydrogen from water

Primary photoproduct

Pyrimidine-pyrimidone photoproducts

Quantum yields, of photoproducts

Reaction photoproduct formation

Special Topic 6.4 Photoproduction of vitamin

Spore photoproduct

Thymine 6-4 photoproduct

Tris photoproduction

UV Photoproducts

UV photoproduct

Utilization photoproducts

Zinc porphyrinatoin photoproduction of hydrogen from water

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