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Butadiene photochemically

A more demanding dynamical study aimed to rationalize the product distribution in photochemical cycloaddition, looking at butadiene-butadiene [82]. A large number of products are possible, with two routes on the excited Si state leading back to channels on the ground state. The results are promising, as the MMVB dynamics find the major products found experimentally. They also... [Pg.303]

A second synthesis of cobyric acid (14) involves photochemical ring closure of an A—D secocorrinoid. Thus, the Diels-Alder reaction between butadiene and /n j -3-methyl-4-oxopentenoic acid was used as starting point for all four ring A—D synthons (15—18). These were combined in the order B + C — BC + D — BCD + A — ABCD. The resultant cadmium complex (19) was photocyclized in buffered acetic acid to give the metal-free corrinoid (20). A number of steps were involved in converting this material to cobyric acid (14). [Pg.117]

Fig. 13.4. Orbital correlation of energy states involved in the photochemical butadiene-to-cyclobutene conversion. Fig. 13.4. Orbital correlation of energy states involved in the photochemical butadiene-to-cyclobutene conversion.
The cyclohexadiene-hexatriene system seems to be less complicated than the cyclobutene-butadiene system. Cyclohexadiene undergoes photochemical electrocyclic ring opening ... [Pg.775]

The photochemical behavior of butadienes has been closely studied. When these compounds are exposed to light, they move from the ground state to an excited state. This excited state eventually returns to one of the ground state conformations via a process that includes a radiationless decay (i.e., without emitting a photon) from the excited state potential energy surface back to the ground state potential energy surface. [Pg.232]

Bicyclic [6.4.0]dodecane systems have been prepared [17] by catalyzed and photochemical intermolecular cycloaddition of the cyclooct-2-en-l-ones 10 and 1,3-butadiene (1) and by catalyzed intramolecular cycloaddition of trienone 11 (Scheme 3.4). [Pg.102]

We may also look at this reaction from the opposite direction (ring closing). For this direction the rule is that those lobes of orbitals that overlap (in the HOMO) must be of the same sign. For thermal cyclization of butadienes, this requires conrotatory motion (Fig. 18.3). In the photochemical process the HOMO is the %3 orbital, so that disrotatory motion is required for lobes of the same sign to overlap. [Pg.1429]

Conlin148 also studied the pyrolysis of 1-methyl-1-silacyclobutane in the presence of excess butadiene at various temperatures where the decomposition followed first-order kinetics and where the silene isomerized to the isomeric silylene prior to reacting with the butadiene. The value for the preexponential factor A for the silene-to-silylene isomerization was found to be 9.6 0.2 s-1 and the Ewl for the isomerization was 30.4 kcal mol-1 with A// = 28.9 0.7 kcal mol-1 and AS = -18.5 0.9 cal mol-1 deg. More recently, the photochemical ring opening of l,l-dimethyl-2-phenylcyclobut-3-ene and its recyclization was studied. The Eact for cycli-zation was 9.4 kcal mol-1.113... [Pg.92]

The alternate approach of Dewar and Zimmerman can be illustrated by an examination of the 1,3,5-hexatriene system.<81,92> The disrotatory closure has no sign discontinuity (Hiickel system) and has 4n + 2 (where n = 1) ir electrons, so that the transition state for the thermal reaction is aromatic and the reaction is thermally allowed. For the conrotatory closure there is one sign discontinuity (Mobius system) and there are 4u + 2 (n = 1) ir electrons, so that the transition state for the thermal reaction is antiaromatic and forbidden but the transition state for the photochemical reaction is aromatic or allowed (see Chapter 8 and Table 9.8). If we reexamine the butadiene... [Pg.210]

In the thermal conrotatory process the molecule maintains a Ca axis of symmetry throughout the entire reaction, while the photochemical disrotatory process maintains a plane of symmetry as shown in Figure 9.13 for butadiene. [Pg.508]

Isoprene and piperylene undergo photochemical cross-addition to olefins to yield products similar to those observed for butadiene<27) ... [Pg.529]

The first photochemical reactions to be correlated with PMO theory were the dimerizations of anthracene, tetracene, pentacene, and acenaphthylene. 36> More detailed energy surfaces for the photodimerization reactions of butadiene have also been calculated. 30> In the category of simplified calculations lie studies of the regiospecificity of Diels-Alder reactions 37>, and reactivity in oxetane-forming reactions. 38,39) jn these... [Pg.147]

Electrocyclic closure of butadiene units encased within cycloheptane rings has been used to obtain bicyclo[3.2.0]heptene systems (Scheme 5)12. For example, irradiation of eucarvone 21 led to the formation of adduct 22 in 52% yield via a disrotatory ring closure123. This adduct was used as a key intermediate in the synthesis of the pheromone grandisol, 23, which proceeded in 20% overall yield from 22. In their synthesis of a-lumicolchicine. Chapman and coworkers utilized a photochemically initiated four-electron disrotatory photocyclization of colchicine to produce /Murnicolchicine 24a and its /-isomer 24b in a 2 1 ratio12b. These adducts were then converted, in a second photochemical step, to the anti head-to-head dimer a-lumicolchicine 25. [Pg.268]

Photochemical investigations When a solution of the complex Cp2Ti (o-C=QBu) 2 is irradiated, NMR spectroscopic monitoring shows that a titanacyclocumulene is first generated, and that this species then reacts with a further equivalent of titanocene to yield the dinuclear complex with p-q(l-3),q(2-4)-trans,trans-butadiene units between the two... [Pg.366]

The simplest example of an electrocyclic reaction involving 4n electron system is the thermal opening of cyclobutenes to 1,3 butadienes. The reaction can be done thermally or photochemically and under either conditions, it is stereospecific. [Pg.59]

In attempts to cany out cyclisation from butadiene 1,3 in the gaseous phase and under photochemical conditions R Srinivasan (J.Amer.Chem.Soc. 88, 3765 (1966) showed that irradiation yields a complex mixture of ethylene, acetylene, but-1 ene, hydrogen and polymers. The quantum yields of acetylene and ethylene formation increase with pressure. [Pg.60]

On the other hand in a photochemical transformation by a disrotatory process, one electron is promoted from jt to n orbital and so the o, n and it orbitals of cyclobutene would correlate with /. /2 and /3 orbitals of butadiene. Thus the first excited state of cyclobutene, since it correlates with the first excited state of butadiene, therefore, the process would be a photochemically symmetry allowed process. [Pg.63]

Similarly the first excited state of butadiene V1V2V3 is correlated with a high energy upper excited state G27tc of cyclobutene. Thus a photochemical conrotatory process in either direction would be a symmetry forbidden reaction. [Pg.64]

See other pages where Butadiene photochemically is mentioned: [Pg.371]    [Pg.343]    [Pg.477]    [Pg.371]    [Pg.343]    [Pg.477]    [Pg.369]    [Pg.197]    [Pg.191]    [Pg.272]    [Pg.749]    [Pg.751]    [Pg.771]    [Pg.67]    [Pg.38]    [Pg.69]    [Pg.1092]    [Pg.873]    [Pg.157]    [Pg.345]    [Pg.486]    [Pg.67]    [Pg.475]    [Pg.27]    [Pg.621]    [Pg.245]    [Pg.198]    [Pg.218]   
See also in sourсe #XX -- [ Pg.306 , Pg.320 ]



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