Pyrolysis Diels-Alder reaction

Diels-Alder reactions, 4, 842 flash vapour phase pyrolysis, 4, 846 reactions with 6-dimethylaminofuKenov, 4, 844 reactions with JV,n-diphenylnitrone, 4, 841 reactions with mesitonitrile oxide, 4, 841 structure, 4, 715, 725 synthesis, 4, 725, 767-769, 930 theoretical methods, 4, 3 tricarbonyl iron complexes, 4, 847 dipole moments, 4, 716 n-directing effect, 4, 44 2,5-disubstituted synthesis, 4, 116-117 from l,3-dithiolylium-4-olates, 6, 826 electrocyclization, 4, 748-750 electron bombardment, 4, 739 electronic deformation, 4, 722-723 electronic structure, 4, 715 electrophilic substitution, 4, 43, 44, 717-719, 751 directing effects, 4, 752-753 fluorescence spectra, 4, 735-736 fluorinated derivatives, 4, 679 H NMR, 4, 731 Friedel-Crafts acylation, 4, 777 with fused six-membered heterocyclic rings, 4, 973-1036 fused small rings structure, 4, 720-721 gas phase UV spectrum, 4, 734 H NMR, 4, 7, 728-731, 939 solvent effects, 4, 730 substituent constants, 4, 731 halo... 

Perfluorotetramethylthiadiphosphanorbornadiene and bis(trifluoromethyl) thiadiphosphole can be prepared by thermolysis of an adduct of methanol and hexakis(trifluoromethyl)-l,4-diphosphabarrelene with sulfur [113] (equation 23) Pyrolysis of the adduct of hexafluorinated Dewar benzene and phenyl azide results in ring expansion giving azepine, which photochemically yields an intramolecular 2-1-2 adduct, a good dienophile for the Diels-Alder reaction [114, //5] (equation 24) Thermolysis of fluonnated derivatives of 1,5-diazabicyclo-... 

Pyridones from 1,3,5 triketones, 46,60 Pyrolysis, diketene to ketene, 46, SO a-PYRONE, 46,101 in Diels Alder reactions, 46, 104 4-Pyrones, 2,6 disubstituted, from 1,3,5 pentanetnones by acid cycliza tion, 46, 61... 

Starting from 27, cyclo-Cig was prepared in the gas phase by laser flash heating and the neutral product, formed by stepwise elimination of three anthracene molecules in retro-Diels-Alder reactions, was detected by resonant two-photon-ionization time-of-flight mass spectrometry [23]. However, all attempts to prepare macroscopic quantities of the cyclocarbon by flash vacuum pyrolysis using solvent-assisted sublimation [50] only afforded anthracene and polymeric material. 

On the other hand, numerous examples are already known in which monomeric metaphosphoric esters are generated by thermolysis reactions. Most worthy of mention in this context is the gas phase pyrolysis of the cyclic phosphonate 150 which leads via a retro-Diels-Alder reaction to butadiene and monomeric methyl metaphosphate (151) 108,109, no). While most of the phosphorus appears as pyrophosphate and trimeric and polymeric metaphosphate, a low percentage (<5%) of products 152 and 153 is also found on condensation of the pyrolyzate in a cold trap containing diethylaniline or N,N,N, N,-tetraethyl-m-phenylene-diamine. The... 

The Diels-Alder adduct of sulpholene and cyclopentadiene is a useful starting material for substituted diene synthesis121. The diene moiety is unmasked by retro-Diels-Alder reaction and sulphur dioxide extrusion under flash vacuum pyrolysis conditions (equations 74 and 75)122,123. 

The term Diels-Alder reaction in a general sense refers to the reaction between a diene and a dienophile. Retro Diels-Alder reaction is a process that, under certain conditions, produces diene and olefin or a compound containing a C=C bond. The application of flash vacuum pyrolysis to effect the retro Diels-Alder reaction, as shown in Schemes 5-46 and 5-47, has become the standard procedure since the introduction of the method by Stork et al.74 in the 1970s. Therefore, alkenes that are difficult to access by conventional methods may be obtained via retro Diels-Alder reactions.75 In particular, this reaction allows the preparation of thermodynamically less stable compounds such as 4,5-dialkyl cyclopenta-2-en-one. In this case, the alkene functional group can be regarded as being protected by cyclopentadiene (as shown in 154 or 157), which, after subsequent reaction, can easily be removed through quick pyrolysis. 

Dienes can also be generated under the conditions of Diels-Alder reaction from precursors. An example of exceeding reactive diene is quinodimethane which has been synthesized from the pyrolysis of benzocyclobutene. 

Another method to prepare allenyl ketones uses flash vacuum pyrolysis of the heterocycles 121 (Scheme 7.19) [163], This elimination of carbon monoxide is at least formally a cheletropic reaction. Highly reactive allenes such as esters and nitriles of type 124 or unsubstituted butadienal can be generated if retro-Diels-Alder reaction of 123 or similar precursors, respectively, is performed by flash vacuum pyrolysis [164]. 

The analogous transformation of 125, also realized by flash vacuum pyrolysis, gave rise to allenic oximes 126 [165], which are not directly accessible by the classical route starting from allenyl ketones and hydroxylamine (see Section 7.3.2) [122], Because compounds 125 are prepared from allenyl ketones and furan by [4 + 2]-cycloaddition followed by treatment with hydroxylamine, the retro-Diels-Alder reaction 125 —> 126 is in principle the removal of a protecting group (see also Scheme 7.46). 

Particularly good yields of the cydoadduct 329 are obtained if R1 = R2 = H is valid for the allenyl ketone 328 [165]. The Diels-Alder products 329 can undergo many chemical transformations, for example to the oximes 330, which yield the modified allenes 331 after a subsequent flash vacuum pyrolysis. The oximes 331 generated by retro-Diels-Alder reaction are not available from ketones 328 and hydroxylamine hydrochloride directly [122] (see also Scheme 7.19). 

Since the Diels-Alder reaction is reversible, the 2,4-diethylidenecyclobutane-l,3-dione (6) reacted at room temperature with cyclopentadiene to give the bisadduct 7, which cycloreverted to 6 on flash-vacuum pyrolysis.78... 

In another series of related experiments Errede and coworkers prepared o-quinodimethane itself by the flash pyrolysis of o-methylbenzyltrimethylam-monium hydroxide 23 [72, 73], The conditions of this experiment were such that the o-quinodimethane was quenched soon after it was formed by cooling to - 78 °C. The product trapped out under these conditions was an approximately 25 75 mixture of 1,2,5,6-dibenzocyclooctadiene 20 and the spiro o-quinodimethane dimer 24 (Fig. 14). Dimer 24 can readily be seen to be the result of the Diels-Alder reaction of one o-quinodimethane bis-exo-methylene diene unit across one of the exo-methylene groups of another o-quinodimethane. The spirodimer... 

Oxabicyclo[3.2.0]hepta-l,4,6-triene (289), a planar Sn-electron analog of 4, has been prepared by flow pyrolysis of 288 (both cis and trans) in approximately 10% yield (>95% purity) 289 is an extremely sensitive compound, polymerizing instantaneously on exposure to oxygen. In solution, where it is stable for several days, it slowly dimerizes to give the known compound 291 the pentacyclic intermediate 290 is possibly involved. In Diels-Alder reactions, 289 behaves like an olefin with cyclopentadiene it reacts immediately to give 292. Hydrogenation occurs at the same site. ... 

Synthesis of benzo[c]furans and isoindoles (181) is also possible by the addition of benzyne to the respective monocycles (178), followed by reduction (179 — 180) and pyrolysis. In an alternative procedure, (179) is reacted with 3,6-bis(2-pyridyl)-l,2,4,5-tetrazine, which affords (181) under far less vigorous conditions via a retro Diels-Alder reaction of the intermediate (182). 4-Phenyl-1,2,4-triazoles pyrolyze to form isoindoles (Section 3.4.3.12.2). 

The dibenzarsenins (125) are prepared by the pyrolysis of a 10-benzyl-5,10-dihy-drodibenz[6,e]arsenin (equation 27). This reaction proceeds via a radical abstraction process. The parent (125 R = H) is unstable and could not be isolated, but the phenyl (125 R = Ph), tolyl (125 R = 4-MeCeH4) and p-methoxyphenyl (125 R = 4-MeOCeH4) derivatives were isolated. Like arsenin itself, (125) can act as a diene in the Diels-Alder reaction and maleic anhydride adducts were prepared for each of the above (77RTC265). 

Flash vacuum pyrolysis of the silacyclopentene (121) affords 1,1-dimethylsilole. Though it dimerizes below room temperature, it can be trapped as an adduct with maleic anhydride and can be regenerated by a retro Diels-Alder reaction of the dimer (Scheme 1951 (81JOM(209)C25). It is also formed from the peroxidation of l,l-dimethylsilacyclopent-3-ene, followed by reduction to the cyclopent-4-ene-3-ol and catalyzed vacuum flow dehydration (Scheme 196) (81JOM(216)32l). The germole can be prepared similarly <81JOM(2lo)C33>. 

When 3,4-dihydro-2//-pyran (555) is given pulses of a laser beam, it decomposes by a retro-Diels-Alder reaction into acrolein and ethylene (78JA6111). 4-Methyl-5,6-dihydro-2//-pyran (555a) when irradiated in methanol through which oxygen is passed gives a mixture of four cyclic products on treatment with sodium borohydride (79JCS(P1)1806). Pyrolysis of the dihydropyran (555) at 350 °C yields butadiene. 

As a result of their accessibility, dihydropyrans provide a useful source of 4//-pyrans. Indeed one of the earliest syntheses of the parent compound involved the pyrolysis of 2-acetoxy-3,4-dihydropyran (165) (62JA2452). The concomitant formation of acrolein, vinyl acetate and acetic acid indicates that a reverse Diels-Alder reaction competes with the pyrolysis. 

Diels-Alder reactions are, of course, reversible, and the pathway followed for the reverse reaction (2,3 arrows) can sometimes be as telling as the pathway for the forward reaction. The direction in which any pericyclic reaction takes place is determined by thermodynamics, with cycloadditions, like the Diels-Alder reaction, usually taking place to form a ring because two n-bonds on the left are replaced by two Diels-Alder reaction can be made to take place in reverse when the products do not react with each other rapidly, as in the pyrolysis of cyclohexene 2.3 at 600°. It helps if either the diene or the dienophile has some special stabilization not present in the starting material, as in the formation of the aromatic ring in anthracene 2.15 in the synthesis of diimide 2.16 from the adduct 2,14, and in... 

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