Photochemical radical chain

The polymer-supported distannane 90 was used as a source of stannyl radicals in several radical cyclization reactions, such as the photochemical radical chain addition of f-butyl iodide to acetylenes yielding the Z/E mixture of alkenes or the photochemical cyclization of citronellyl bromide to give menthane in high yields164 (Scheme 44). 

Addition Chlorination. Chlorination of olefins such as ethylene, by the addition of chlorine, is a commercially important process and can be carried out either as a catalytic vapor- or Hquid-phase process (16). The reaction is influenced by light, the walls of the reactor vessel, and inhibitors such as oxygen, and proceeds by a radical-chain mechanism. Ionic addition mechanisms can be maximized and accelerated by the use of a Lewis acid such as ferric chloride, aluminum chloride, antimony pentachloride, or cupric chloride. A typical commercial process for the preparation of 1,2-dichloroethane is the chlorination of ethylene at 40—50°C in the presence of ferric chloride (17). The introduction of 5% air to the chlorine feed prevents unwanted substitution chlorination of the 1,2-dichloroethane to generate by-product l,l,2-trichloroethane. The addition of chlorine to tetrachloroethylene using photochemical conditions has been investigated (18). This chlorination, which is strongly inhibited by oxygen, probably proceeds by a radical-chain mechanism as shown in equations 9—13. 

Sulfoxidation is a photochemical reaction. The radical chain reaction is initiated by triplet sulfur dioxide (3 S02), excited by ultraviolet (UV) light of wavelength longer than 320 nm ... 

Cyclic ethers were also obtained by cyclization of alkoxyl radicals, generated in a radical chain reaction by reacting the thione 42 with (TMSfsSiH under photochemical conditions at 20 °C (Reaction 46). Regioselectivities of cyclization have been investigated and a progressive increase of the 6-endo-trig selectivity along the series R2 = H[Pg.140]

The monomers commonly used for the preparation of polymer monoliths are either hydrophobic, for example, styrene/divinylbenzene and alkyl methacrylates, or hydrophilic, for example, acrylamides. The polymerization is usually accomplished by radical chain mechanisms with thermal or photochemical initiation, as detailed in the reviews (Eeltink et al., 2004 Svec, 2004a and b). Internal structures of polymer monoliths are described to be corpuscular rather than spongy this means through-pores were found to be interstices of agglomerated globular skeletons as shown in Fig. 7.1 (Ivanov et al., 2003). Porosity is presumably predetermined by the preparation... 

Termination is by the recombination of H and Cl. There is complete corroboration of this mechanism from photochemical studies. This is undoubtedly a free-radical chain propagation mechanism. 

Various authors have studied the ageing of triterpenoid resins to understand and possibly slow their deterioration [3, 4, 12, 13, 17 36]. The main degradation pathway is autoxida-tion, an oxidative radical chain reaction [37, 38] after formation of radicals, oxygen from the air is inserted, leading to peroxides. The peroxides can be homolytically cleaved, resulting in new radicals that continue the chain reaction. The cleavage of peroxide bonds can be induced thermally or photochemically. 

Photochemically generated radicals in chain reactions are less familiar to synthetic chemists [8,21]. The above mentioned peroxides have been used in the presence of light to initiate radical chain reactions at room or lower temperatures. Azo compounds are also known to decompose photo-lytically to afford alkyl radicals. AIBN has rarely been used under such conditions. 

Alkyl amines add photochemically to olefins a condensation occurs between the a-carbon atom of the amine and the terminal carbon atom of 1-olefins by what is probably a free-radical, chain reaction.291 Internally illumination of solutions, containing piperidine and octene-1, with a mercury discharge tube led to the formation of 2-n-oetylpiperidine (CXLV). 

Unactivated aryl halides also undergo nucleophilic displacement via electron transfer in the initial step the so-called SRN1 mechanism. It is now clear that in the case of heteroaromatic compounds, nucleophilic substitution by the Srn process often competes with the addition-elimination pathway. The SRN reactions are radical chain processes, and are usually photochemically promoted. For example, ketone (895) is formed by the SRN1 pathway from 2-chloroquinoxaline (894) (82JOC1036). 

R. A. Marcus I have a question for Prof. Rice Do most industrial photochemical processes involve chain reactions If so, one suspects that they will be less susceptible to coherent control. Are there some industrial photochemical processes not involving free radical chains I gather that you hold the view, which seems reasonable, that the opportunities for coherent control are greater in devices such as electronic switches and generally in telecommunications ... 

In recent years visible photoinitiators for the formation of polymers via a radical chain reaction have also been developed. These absorb light which is blue, green, or red and also cause the polymerization of polyolacrylates, in some instances, such as encapsulated systems, with speed which is near photographic. Some of these photoinitiators provide the photochemical backbone of the nonsilver, near-photographic speed, imaging processes such as the Cycolor processes invented by the Mead Corporation. Cycolor initiators are cyanine dye, borate ion salts (4)—so-called ( +, —) ion pair... 

A free radical chain reaction proceeds through a succession of free radicals. In the photochemical chlorination of an alkane, the initiating step is the homolytic lission of chlorine molecules to produce chloroalkanc molecules and chlorine free radicals. These two reactions constitute the propagating step. However, the chlorine free radicals may also combine to form chlorine molecules or react with the alkane free radicals to form chloroalkane molecules. Both of these reactions constitute terminating steps of the chain reaction. Il should be noted, however, that the foregoing sequence cannot take place in the dark. Exposure to light allows the series of reactions then to proceed rather violently. 

We have mentioned how chlorine molecules dissociate to chlorine atoms on absorption of near-ultraviolet light and thereby cause radical-chain chlorination of saturated hydrocarbons (Section 4-4D). Photochemical chlorination is an example of a photochemical reaction that can have a high quantum yield— that is, many molecules of chlorination product can be generated per quantum of light absorbed. The quantum yield of a reaction is said to be unity when 1 mole of reactant is converted to product(s) per einstein1 of light absorbed. The symbol for quantum yield is usually 4>. 

Gorner H (1993) Acetone-sensitized photolysis of 5-iodouracil and 5-iodouridine in aqueous solution in the presence of alcohols free radical chain mechanism. J Photochem Photobiol A Chem 72 197-208... 

Singlet oxygen must attack the 2-position of a 3-hexylthienyl unit in order to abstract a p-hydrogen and form the hydroperoxide. Photochemical cleavage of the 0-0 bond yields the corresponding alkoxy radical and one hydroxyl radical. Chain scission then proceeds as a result of p-cleavage of the polymeric alkoxy radical. 

It has been shown that displacement of the iodo substituent in 4-iodo-l,l,2,2,9,9,10, 10-octafluoro[2.2]paracyclophane by arenethiolates or by stabilized enolates occurs by the radical chain. S rn 1 mechanism. The reaction occurs in DMF with photochemical stimulation.4... 

The mechanism of aminyl radical generation from PTOC carbamates follows closely the radical chain mechanism of alkyl radical generation from PTOC esters. The chain reaction sequence involves the series of steps shown in Scheme 8. Several methods for inducing N —O bond cleavage are possible. Photochemical decomposition of 29 via visible light irradiation is used to initiate the chain reaction sequence at ambient or subambient temperature reactions have been run as low as -78°C (91TL6493). 

Simple homolysis of the C-I bond by heating or by light is the most straightforward approach and was the first used for adding perfluoroalkyl iodides to olefins. One presumes that both the thermal and the photochemically induced addition reactions of perfluoroalkyl radicals proceed via free radical chain reactions as depicted in the Scheme below. However, the conditions of these reactions are rarely ideal for preparative purposes because high temperatures are required for the thermolytic process and long photolysis times are required for the photolytic method [60]. 

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