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Ring closure Cyclization

Bicyclooctanes, isomerization paths of, 20 282 Bicycio (2.2.2)-2- octene, 20 269, 270 Bifimctional catalysts, ring closure, cyclization, 29 311-316 C5 cyclization, 29 311... [Pg.54]

In this paper, we shall discuss, first by a polymerization of unsaturated side-groups (side-chains), second by the polymer-analogous condensation of suitable functional groups, third by ring-closures (cyclization) via electrocyclic reactions and, fourth by cyclization via electrophilic substitution reactions. [Pg.16]

Dong JH, Dong WK, Dae YC (2010) Facile ring-closure cyclization of atenes by nucleophilic C-alkylation reaction in ionic Uqitid. Tetrahedron Lett 51 54-56... [Pg.61]

Electi ocyclic reactions are examples of cases where ic-electiDn bonds transform to sigma ones [32,49,55]. A prototype is the cyclization of butadiene to cyclobutene (Fig. 8, lower panel). In this four electron system, phase inversion occurs if no new nodes are fomred along the reaction coordinate. Therefore, when the ring closure is disrotatory, the system is Hiickel type, and the reaction a phase-inverting one. If, however, the motion is conrotatory, a new node is formed along the reaction coordinate just as in the HCl + H system. The reaction is now Mdbius type, and phase preserving. This result, which is in line with the Woodward-Hoffmann rules and with Zimmerman s Mdbius-Huckel model [20], was obtained without consideration of nuclear symmetry. This conclusion was previously reached by Goddard [22,39]. [Pg.347]

SUBSTITUTED BUTADIENES. The consequences of p-type orbitals rotations, become apparent when substituents are added. Many structural isomers of butadiene can be foiined (Structures VIII-XI), and the electrocylic ring-closure reaction to form cyclobutene can be phase inverting or preserving if the motion is conrotatory or disrotatory, respectively. The four cyclobutene structures XII-XV of cyclobutene may be formed by cyclization. Table I shows the different possibilities for the cyclization of the four isomers VIII-XI. These structmes are shown in Figure 35. [Pg.369]

Synthesis of 2-thioxopenams (76) has also been realized usiag a [sulfur, C-5] ring closure (117). Cyclization of 4-(3)-chloroazetidinone [88816-44-8] (77, R = R = SCOCH ), C22H22ClN20gS2, usiag imidazole ia aqueous dioxane proceeded stereospecifically to give the 5-(R)-thioxopenam [83362-57-6]... [Pg.12]

Only one successful penem synthesis involving a [nitrogen, C-3] ring closure has been described (119). Cyclization of the ketomalonate (79) usiag hydrofluoric acid-pyridine afforded the penams (80) which were converted to the penem (81). Attempts to adapt the versatile diazoketoester-carbapenem cyclization for penem synthesis failed (120). [Pg.12]

This type of cyclization is important only for the formation of cinnolines. In all cases, the starting compounds have an ortho amino group, which upon diazotization undergoes ring closure with the other functionality, most frequently with a multiple bond. [Pg.43]

The converse situation in which ring closure is initiated by the attack of a carbon-based radical on the heteroatom has been employed only infrequently (Scheme 18c) (66JA4096). The example in Scheme 18d begins with an intramolecular carbene attack on sulfur followed by rearrangement (75BCJ1490). The formation of pyrrolidines by intramolecular attack of an amino radical on a carbon-carbon double bond is exemplified in Scheme 19. In the third example, where cyclization is catalyzed by a metal ion (Ti, Cu, Fe, Co " ), the stereospecificity of the reaction depends upon the choice of metal ion. [Pg.100]

Ring closures based upon electrophilic processes are uncommon. The cationic cyclization in Scheme 29a proceeds via transformation of the commencing oxime into a nitrilium ion (81CC568). Schemes 29b (82CB706) and 29c (82CB714) exemplify the application of intramolecular acylation. [Pg.105]

The acid promoted cyclization of AT-(2-chloroallyl)enaminones (Scheme 35a) provides the expected 3-methyltetrahydroindoles, whereas similar treatment of iV-(2-chloroallyl)anilines yields unexpectedly 2-, rather than 3-, methylindoles (Scheme 35b) (75JCS(Pl)U46). The course of the latter cyclization is not resolved although various intermediates, such as those shown, have been considered. The ring closure in the furan synthesis shown in Scheme 35c is catalyzed by mercury(II) ion (79JCs(Pl)316l). [Pg.109]

Ring contraction and intramolecular cyclization constitute a convenient route to ring-fused systems that would be difficult to synthesize in other ways. H- 1,2-Diazepines (538) undergo electrocyclic ring closure to the fused pyrazole system (539) (71CC1022). Azepines also undergo similar valence bond isomerizations. [Pg.161]

The important synthesis of pyrazoles and pyrazolines from aldazines and ketazines belongs to this subsection. Formic acid has often been used to carry out the cyclization (66AHQ6)347) and N-formyl-A -pyrazolines are obtained. The proposed mechanism (70BSF4119) involves the electrocyclic ring closure of the intermediate (587) to the pyrazoline (588 R = H) which subsequently partially isomerizes to the more stable trans isomer (589 R = H) (Section 4.04.2.2.2(vi)). Both isomers are formylated in the final step (R = CHO). [Pg.276]

The Frasca method for obtaining 1-arylindazoles also involves a C(3)—C(3a) ring closure (67CJC697). It consists in the cyclization of p-nitrophenylhydrazones of ketones and aldehydes with polyphosphoric acid. The Barone computer-assisted synthetic design program has found several new methods for preparing indazoles (79MI40409). The selected method involves the transformation of jV, jV -diphenylhydrazides (596) into 1-phenylindazoles (597) by means of trifluoromethanesulfonic anhydride. The yields vary from 2% (R = H) to 50% (R = Ph). [Pg.276]

The treatment of 2-hydroxyacetophenone with hydroxylamine-O-sulfonic acid in dilute aqueous base produced 3-methyl-1,2-benzisoxazole. The mechanism was reported to be a C(2)—C(3) ring closure via intermediate (560) (Scheme 171). Salicylaldehyde failed to cyclize with dilute base, but with 20% KOH and hydroxylamine-O-sulfonic acid the transformation to 1,2-benzisoxazole succeeded (76MI41600). Kemp and Woodward isolated an oxime sulfonate (561) from salicylaldehyde and hydroxylamine-O-sulfonic acid and the subsequent decomposition gave 1,2-benzisoxazole in 95% yield (65T3019). [Pg.117]

Intramolecular ring closure by valence isomerization to a carbon in the 3-position is not common, but known l,l-di-t-butyl-2-nitrosoethylene, stable at room temperature, cyclizes at 220 °C to the stable 4,4-di-f-butyl(4iT)oxazete (75AG(E)70). [Pg.33]

See other pages where Ring closure Cyclization is mentioned: [Pg.835]    [Pg.133]    [Pg.835]    [Pg.344]    [Pg.38]    [Pg.32]    [Pg.24]    [Pg.835]    [Pg.133]    [Pg.835]    [Pg.344]    [Pg.38]    [Pg.32]    [Pg.24]    [Pg.370]    [Pg.316]    [Pg.42]    [Pg.273]    [Pg.331]    [Pg.456]    [Pg.190]    [Pg.320]    [Pg.90]    [Pg.96]    [Pg.102]    [Pg.103]    [Pg.106]    [Pg.107]    [Pg.107]    [Pg.111]    [Pg.115]    [Pg.136]    [Pg.138]    [Pg.163]    [Pg.167]    [Pg.36]    [Pg.36]    [Pg.88]    [Pg.245]    [Pg.295]    [Pg.137]   


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