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Substituted cycloalkanes

CH2 cycloalkanes 7 C cycloalkane substituted 8 C trans-condensed cycles 9 C02... [Pg.472]

Just as with substituted cycloalkanes, substituted benzene rings are numbered in a way that gives the lowest possible numbers for the substituents. In the following structure, numbering the ring as shown gives the numbers 1, 2, and 4 for the substituent positions. Because ethyl is lower in the alphabet than methyl, it is written first in the name 2-ethyl-1,4-dimethylbenzene. [Pg.724]

Stereochemistry refers to chemistry in three dimensions Its foundations were laid by Jacobus van t Hoff and Joseph Achille Le Bel m 1874 Van t Hoff and Le Bel mde pendently proposed that the four bonds to carbon were directed toward the corners of a tetrahedron One consequence of a tetrahedral arrangement of bonds to carbon is that two compounds may be different because the arrangement of their atoms m space IS different Isomers that have the same constitution but differ m the spatial arrangement of their atoms are called stereoisomers We have already had considerable experience with certain types of stereoisomers—those involving cis and trans substitution patterns m alkenes and m cycloalkanes... [Pg.281]

One simple test for chirality of substituted cycloalkanes is to represent the ring in planar form. If the planar form is achiral because of a symmetry element, the compound will not... [Pg.86]

Substituted cycloalkanes are named by rules similar to those we saw in the previous chapter for open-chain alkanes (Section 3.4). For most compounds, there are only two steps. [Pg.108]

Count the number of carbon atoms in the ring and the number in the largest substituent chain, (f the number of carbon atoms in the ring is equal to or greater than the number in the substituent, the compound is named as an alkyl-substituted cycloalkane. If the number of carbon atoms in the largest substituent is greater than the number in the ring, the compound is named as a cycloalkyl-substituted alkane. For example ... [Pg.108]

For an alkyl- or halo-substituted cycloalkane, choose a point of attachment as carbon 1 and number the substituents on the ring so that the second substituent... [Pg.108]

Because of their cyclic structures, cycloalkanes have two faces as viewed edge-on, a "top" face and a "bottom" face. As a result, isomerism is possible in substituted cycloalkanes. For example, there are two different 1,2-dimethyl-cyclopropane isomers, one with the two methyl groups on the same face of the ring and one with the methyls on opposite faces (Figure 4.2). Both isomers are stable compounds, and neither can be converted into the other without breaking and reforming chemical bonds. Make molecular models to prove this to yourself. [Pg.111]

The 1,2-diinethylcyclopropanes are members of a subclass of stereoisomers called cis-trans isomers. The prefixes cis- (Latin "on the same side") and tmns-(Latin "across") are used to distinguish between them. Cis-trans isomerism is a common occurrence in substituted cycloalkanes. [Pg.112]

Substituted cyclohexanes are the most common cycloalkanes and occur widely in nature. A large number of compounds, including steroids and many pharmaceutical agents, have cyclohexane rings. The flavoring agent menthol, for instance, has three substituents on a six-membered ring. [Pg.117]

Conformational analysis (Section 4.8) A means of assessing the energy of a substituted cycloalkane by totaling the steric interactions present in the molecule. [Pg.1238]

Another interesting example is provided by the phenylethynylcarbene complex 173 and its reactions with five-, six-, and seven-membered cyclic enamines 174 to form bridgehead-substituted five-, six-, and seven-membered cycloalkane-annelated ethoxycyclopentadienes with high regioselectivity under mild reaction conditions (Scheme 38) [119,120]. In these transformations the phenylethynylcarbene complex 173 acts as a C3 building block in a formal [3+2] cycloaddition. Like in the Michael additions (reaction route F in Scheme 4), the cyclic electron-rich enamines 174 as nucleophiles attack the... [Pg.51]

Acetylene- and Diacetylene-Expanded Cycloalkanes and Rotanes. 201 1 -42 de Meijere A, Kozhushkov SI, Khlebnikov AF (2000) Bicyclopropylidene - A Unique Tetra-substituted Alkene and a Versatile Cj-Building Block. 207 89-147 de Meijere A, Kozhushkov SI, Hadjiaraoglou LP (2000) Alkyl 2-Chloro-2-cyclopropylidene-acetates - Remarkably Versatile Building Blocks for Organic Synthesis. 207 149-227 Dennig J (2003) Gene Transfer in Eukaryotic Cells Using Activated Dendrimers. 228 227-236 de Raadt A, Fechter MH (2001) Miscellaneous. 215 327-345 Desreux JF, see Jacques V (2002) 221 123-164... [Pg.260]

There is some increase in selectivity with functionally substituted carbenes, but it is still not high enough to prevent formation of mixtures. Phenylchlorocarbene gives a relative reactivity ratio of 2.1 1 0.09 in insertion reactions with i-propylbenzene, ethylbenzene, and toluene.212 For cycloalkanes, tertiary positions are about 15 times more reactive than secondary positions toward phenylchlorocarbene.213 Carbethoxycarbene inserts at tertiary C—H bonds about three times as fast as at primary C—H bonds in simple alkanes.214 Owing to low selectivity, intermolecular insertion reactions are seldom useful in syntheses. Intramolecular insertion reactions are of considerably more value. Intramolecular insertion reactions usually occur at the C—H bond that is closest to the carbene and good yields can frequently be achieved. Intramolecular insertion reactions can provide routes to highly strained structures that would be difficult to obtain in other ways. [Pg.936]

The most common synthetic utility of azoniaspiroalkanes is as precursors to nitrogen-containing cycloalkanes via nucleophilic substitution reactions (Equation 1). [Pg.1040]

In general, it is possible to predict the presence or absence of optical activity in any substituted cycloalkane merely by looking at flat structures, without considering the exact three-dimensional chair conformations. [Pg.214]

It is of course possible to name individual radialenes according to IUPAC rules [e.g. per(methylene)cycloalkanes 1-4]. However, the descriptiveness of the term radialene may some day pave its way into the official nomenclature. For substituted [ ]radialenes we have proposed1 a pragmatic numbering system, in which an inner ring is numbered first, followed by an outer ring . The numbering of substituents should follow IUPAC rules. Thus, the hydrocarbon 7 is 4,4-diethyl-5,5-dimethyl[3]radialene, the ester 8 should be called 7-methoxycarbonyl-5,5-dimethyl[4]radialene, the nitrile 9 which can exist in four diastereomeric forms is (6Z,7Z)-6-cyano-5,5,7-trimethyl[4]radialene and the difunctionalized [5]radialene 10 is (7 ,6Z)-7-bromo-6-formyl-6-methyl[5]radialene. [Pg.928]

Cyclopolymerization of Nonconjugated Dienes. Cyclopolymerization is an addition polymerization that leads to introduction of cyclic structures into the main chain of the polymer. Nonconjugated dienes are the most deeply studied monomers for cyclopolymerization and for cyclocopolymerizations with alkene monomers 66 In general, (substituted and unsubstituted) dienes with double bonds that are linked by less than two or more than four atoms cannot undergo efficient cyclization and result in crosslinked materials.12 In fact, efficient cyclopolymerization processes have been described, for instance, for a,oo-dienes like 1,5-hexadiene, 2-methyl-l,5-hexadiene, 1,6-heptadiene, and 1,7-octadiene,67 73 which lead to formation of homopolymers and copolymers containing methylene-1,3-cycloalkane units. [Pg.26]

Most of the above-mentioned dihydropyridazinones bear an alkyl substituent either at C-4 or at C-5. However, there are also patents on 4,5-cycloalkane annulated congeners (65, R = substituted Ph X = (CH2)M, n = 1-4) [111, 225, 246-248] and on 6-aryldihydropyridazinones bearing various other substituents at the /J-carbon atoms [206, 211, 229, 237, 249-252]. [Pg.18]

Similar considerations apply in case of substituted cycloalkanes, e.g., methyl cyclopropane... [Pg.246]

C complexes, 32 185-186 CFjHCFjH, 39 340 chemisorption complexes, 32 170-172 CjH, enthalpies, 37 141, 143 "C-labeling studies, 25 166-172 commercial, 6 197 complex molecules, 30 58-72 medium-sized rings, 30 68-72 polymethylcycloalkanes, 30 59-65 substituted aromatics, 30 65-68 cyclic-acyclic product ratio, 30 8-9 cycloalkanes, 30 68-69 function, hydrogen pressure, 30 12, 15-16 hydrocarbon reaction models, 32 202-205 hydrogenolysis and, 23 93, 103 interconversion, 30 81-82 isopentane, 30 17 label scrambling, 30 7, 12-13 mechanism, 30 5-16 bifunctional, 30 4 catalyst particle size and, 30 72-85 concerted, 30 20... [Pg.130]

Regioselective Substitution of Unactivated CH Bonds CH bonds in cycloalkanes (decaline, steroids) and alkanes bearing electron-deficient groups in remote posihons (1,2-dichlorocyclohexane, decanoic acid) can be regioselectively subshtuted at the anode by trifluoroacetate, acetate, or methoxide (Figs. 1, 2) [12-14]. [Pg.402]

Cycloalkenes such as cyclohexene, 1-methylcyclohexene, cyclopentene, and nor-bornene are hydrosilylated with triethylsilane in the presence of aluminum chloride catalyst in methylene chloride at 0 °C or below to afford the corresponding hydrosilylated (triethylsilyl)cycloalkanes in 65-82% yields [Eq. (23)]. The reaction of 1-methylcyclohexene with triethylsilane at —20 °C occurs regio- and stereoselectively to give c/i-l-triethylsilyl-2-methylcyclohexane via a tra x-hydrosilylation pathway. Cycloalkenes having an alkyl group at the double-bonded carbon are more reactive than non-substituted compounds in Lewis acid-catalyzed hydrosilylations. ... [Pg.58]

Recently, Corma et al. have patented a process of oxidizing cycloalkane with molecular oxygen to produce cycloalkanol and/or cycloalkanone in the presence of hydrotalcite-intercalated heteropoly anion [Co MnCo (H20)039] (M = W or Mo), which comprised one cobalt as a central atom and another as a substitute of a W=0 fragment in the Keggin structure [98]. At 130 °C and 0.5 MPa, 64 and 24% selectivity to cyclohexanone and cyclohexanol, respectively, was achieved at cyclohexane conversion about 5%. This catalytic system could be of practical importance provided a true heterogeneous nature of catalysis and good catalyst recyclability had been proved. Unfortunately, this information was lacking in [98]. [Pg.272]

Hydrogenation of fluorene Hydrogenation of fluorene provided, 34 wt % hexahydrofluorene, 6 wt % peihydrofluorene and 16 wt % cracked material as well as 44 wt % unreacted fluorene.The cracked material consisted largely of diphenyl with smaller proportions ortho methyl-substituted diphenyl. These products arise from cracking of the central five-membered ring. Compounds produced from hydrogenation of these compounds were also identified as well as small amounts of cycloalkanes. [Pg.243]


See other pages where Substituted cycloalkanes is mentioned: [Pg.177]    [Pg.97]    [Pg.319]    [Pg.78]    [Pg.76]    [Pg.54]    [Pg.55]    [Pg.232]    [Pg.200]    [Pg.197]    [Pg.216]    [Pg.137]    [Pg.341]    [Pg.170]    [Pg.239]    [Pg.253]    [Pg.35]    [Pg.10]    [Pg.602]    [Pg.82]    [Pg.254]    [Pg.280]    [Pg.227]   
See also in sourсe #XX -- [ Pg.142 ]

See also in sourсe #XX -- [ Pg.141 , Pg.142 , Pg.143 , Pg.143 , Pg.144 , Pg.145 , Pg.146 , Pg.146 ]




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Alkyl-substituted cycloalkanes

Cycloalkan

Cycloalkanes

Cycloalkanes substituted cyclohexanes

Substituted cycloalkanes, naming

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