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Molecular double bond

From the X-ray structural data [98] we calculate the distances (in A) of inter-molecular double bond centers in possible dimer pairs of 64, and 65. They come out as follows ... [Pg.135]

Pyykko P, Atsumi M (2009) Molecular double-bond covalent radii for elements Li-E112. ChemEurJ 15 186-197... [Pg.48]

Asphaltenes are obtained in the laboratory by precipitation in normal heptane. Refer to the separation flow diagram in Figure 1.2. They comprise an accumulation of condensed polynuclear aromatic layers linked by saturated chains. A folding of the construction shows the aromatic layers to be in piles, whose cohesion is attributed to -it electrons from double bonds of the benzene ring. These are shiny black solids whose molecular weight can vary from 1000 to 100,000. [Pg.13]

Hence we have two molecular orbitals, one along the line of centres, the other as two sausage-like clouds, called the n orbital or n bond (and the two electrons in it, the n electrons). The double bond is shorter than a single C—C bond because of the double overlap but the n electron cloud is easily attacked by other atoms, hence the reactivity of ethene compared with methane or ethane. [Pg.56]

These absorptions are ascribed to n-n transitions, that is, transitions of an electron from the highest occupied n molecular orbital (HOMO) to the lowest unoccupied n molecular orbital (LUMO). One can decide which orbitals are the HOMO and LUMO by filling electrons into the molecular energy level diagram from the bottom up, two electrons to each molecular orbital. The number of electrons is the number of sp carbon atoms contributing to the n system of a neuhal polyalkene, two for each double bond. In ethylene, there is only one occupied MO and one unoccupied MO. The occupied orbital in ethylene is p below the energy level represented by ot, and the unoccupied orbital is p above it. The separation between the only possibilities for the HOMO and LUMO is 2.00p. [Pg.197]

For 4,5-dialkylthiazoles, the molecular ion decomposes by two competitive pathways, either loss of HCN followed by elimination of the radical R in the position /3 to the double bond of the resulting substituted thiirene, or by p cleavage followed by elimination of HCN (119). [Pg.348]

Write structural formulas or build molecular models and give the lUPAC names for all the alkenes of molecular formula C6H12 that contain a trisub stituted double bond (Dont forget to include stereoisomers)... [Pg.198]

Wnte a structural formula or build a molecular model and give a correct lUPAC name for each alkene of molecular formula C7H14 that has a tetrasubstituted double bond... [Pg.224]

The stereoselectivity of this reaction depends on how the alkene approaches the catalyst surface As the molecular model m Figure 6 3 shows one of the methyl groups on the bridge carbon lies directly over the double bond and blocks that face from easy access to the catalyst The bottom face of the double bond is more exposed and both hydrogens are transferred from the catalyst surface to that face... [Pg.235]

Hydrocarbons that contain a carbon-carbon triple bond are called alkynes Non cyclic alkynes have the molecular formula C H2 -2 Acetylene (HC=CH) is the simplest alkyne We call compounds that have their triple bond at the end of a carbon chain (RC=CH) monosubstituted or terminal alkynes Disubstituted alkynes (RC=CR ) have internal triple bonds You will see m this chapter that a carbon-carbon triple bond is a functional group reacting with many of the same reagents that react with the double bonds of alkenes... [Pg.363]

Let us now examine the Diels-Alder cycloaddition from a molecular orbital perspective Chemical experience such as the observation that the substituents that increase the reac tivity of a dienophile tend to be those that attract electrons suggests that electrons flow from the diene to the dienophile during the reaction Thus the orbitals to be considered are the HOMO of the diene and the LUMO of the dienophile As shown m Figure 10 11 for the case of ethylene and 1 3 butadiene the symmetry properties of the HOMO of the diene and the LUMO of the dienophile permit bond formation between the ends of the diene system and the two carbons of the dienophile double bond because the necessary orbitals overlap m phase with each other Cycloaddition of a diene and an alkene is said to be a symmetry allowed reaction... [Pg.414]

A certain species of grasshopper secretes an allenic substance of molecular formula C13H20O3 that acts as an ant repellent The carbon skeleton and location of various substituents in this substance are indicated in the partial structure shown Complete the structure adding double bonds where appropriate... [Pg.419]

FIGURE 11 12 Molecular geometry of cyclooctatetraene The ring is not planar and the bond distances alternate between short double bonds and long single bonds... [Pg.450]

What about a substance wrth the molecular formula 71414 Thrs compound can not be an alkane but may be erther a cycloalkane or an alkene because both these classes of hydrocarbons correspond to the general molecular formula C H2 Any time a ring or a double bond is present in an organic molecule its molecular formula has two fewer hydrogen atoms than that of an alkane with the same number of carbons... [Pg.574]

A molecule of molecular formula C7H12 has four fewer hydrogens than the corre spondrng alkane It has an rndex of hydrogen defrcrency of 2 and can have two rrngs two double bonds one rrng and one double bond or one trrple bond... [Pg.574]

Section 13 23 A compound s molecular formula gives information about the number of double bonds and rings it contains and is a useful complement to spec troscopic methods of structure determination... [Pg.577]

Index of hydrogen deficiency (Section 13 23) A measure of the total double bonds and nngs a molecule contains It is determined by comparing the molecular formula C Hj. of the compound to that of an alkane that has the same number of carbons according to the equation... [Pg.1286]

Geometrical Isomerism. Rotation about a carbon-carbon double bond is restricted because of interaction between the p orbitals which make up the pi bond. Isomerism due to such restricted rotation about a bond is known as geometric isomerism. Parallel overlap of the p orbitals of each carbon atom of the double bond forms the molecular orbital of the pi bond. The relatively large barrier to rotation about the pi bond is estimated to be nearly 63 kcal mol (263 kJ mol-i). [Pg.43]

Hydrogenation of polybutadiene converts both cis and trans isomers to the same linear structure and vinyl groups to ethyl branches. A polybutadiene sample of molecular weight 168,000 was found by infrared spectroscopy to contain double bonds consisting of 47.2% cis, 44.9% trans, and 7.9% vinyl. After hydrogenation, what is the average number of backbone carbon atoms between ethyl side chains ... [Pg.67]

Table 6.7 gives a few other examples of torsional barrier heights. That for ethylene is high, typical of a double bond, but its value is uncertain. The barriers for methyl alcohol and ethane are three-fold, which can be confirmed using molecular models, and fhose of toluene and nifromefhane are six-fold. The decrease in barrier heighf on going fo a higher-fold barrier is fypical. Rofafion abouf fhe C—C bond in toluene and fhe C—N bond in nifromefhane is very nearly free. [Pg.192]

A common example of the Peieds distortion is the linear polyene, polyacetylene. A simple molecular orbital approach would predict S hybddization at each carbon and metallic behavior as a result of a half-filled delocalized TT-orbital along the chain. Uniform bond lengths would be expected (as in benzene) as a result of the delocalization. However, a Peieds distortion leads to alternating single and double bonds (Fig. 3) and the opening up of a band gap. As a result, undoped polyacetylene is a semiconductor. [Pg.237]

Castor oil (qv) contains a predominance of ricinoleic acid which has an unusual stmcture inasmuch as a double bond is present in the 9 position while a hydroxyl group occurs in the 12 position. The biochemical origin of ricinoleic acid [141-22-0] in the castor seed arises from enzymatic hydroxylation of oleoyl-CoA in the presence of molecular oxygen. The unusual stmcture of ricinoleic acid affects the solubiUty and physical properties of castor oil. [Pg.129]


See other pages where Molecular double bond is mentioned: [Pg.49]    [Pg.185]    [Pg.377]    [Pg.378]    [Pg.271]    [Pg.49]    [Pg.185]    [Pg.377]    [Pg.378]    [Pg.271]    [Pg.404]    [Pg.149]    [Pg.156]    [Pg.215]    [Pg.216]    [Pg.36]    [Pg.335]    [Pg.81]    [Pg.224]    [Pg.574]    [Pg.575]    [Pg.790]    [Pg.1287]    [Pg.210]    [Pg.814]    [Pg.265]    [Pg.436]    [Pg.116]    [Pg.508]    [Pg.126]   
See also in sourсe #XX -- [ Pg.378 ]




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