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Terminal hydrogen atom

Figure 16.4 Upper panel shows a benzenoid cluster model (C96H24) and nonbenzenoid models (C80H2o, C112H2a). Lower panel shows the unoccupied C 2p-DOS and C 2s-DOS of carbon atoms in the cluster models. Carbon atoms from the centered atoms to the edged atoms are numbered as 1C-7C, respectively. Hydrogen atoms terminating the edged-carbon atoms are numbered as 8H. The lower-energy DOS portions at the n peak positions of 1C and 7C are denoted by arrows. For a colour version of this figure please see the colour plate section near the end of the book. Figure 16.4 Upper panel shows a benzenoid cluster model (C96H24) and nonbenzenoid models (C80H2o, C112H2a). Lower panel shows the unoccupied C 2p-DOS and C 2s-DOS of carbon atoms in the cluster models. Carbon atoms from the centered atoms to the edged atoms are numbered as 1C-7C, respectively. Hydrogen atoms terminating the edged-carbon atoms are numbered as 8H. The lower-energy DOS portions at the n peak positions of 1C and 7C are denoted by arrows. For a colour version of this figure please see the colour plate section near the end of the book.
Although the bulk of the evidence in favour of termination by reaction (9) and (10) can be seen to be questionable, it does seem that these reactions can be of importance in certain special cases. For phenolic inhibitors, there seems little doubt that reaction (5) alone is important for amines, and particularly for those amines that do not possess a labile hydrogen atom, termination via complex formation may not be negligible. [Pg.208]

Step 1. We assume the carbon atoms to be joined, with hydrogen atoms terminal ... [Pg.65]

Saito et al have explored the properties of polyenes, C2 H2, with hydrogen atom termination at the both ends as a function of the chain... [Pg.191]

Thus, a transition from ethyl-ethyl termination to ethyl-hydrogen atom termination would exhibit a lining-out of the over-all decomposition rate at some maximum level. [Pg.55]

Bivalent radicals derived from unbranched alkenes, alkadienes, and alkynes by removing a hydrogen atom from each of the terminal carbon atoms are named by replacing the endings -ene, -diene, and -yne by -enylene, -dienylene, and -ynylene, respectively. Positions of double and triple bonds are indicated by numbers when necessary. The name vinylene instead of ethenylene is retained for —CH=CH—. [Pg.5]

An alternative chain-terminating decomposition of the tetroxide, known as the Russell mechanism (29), can occur when there is at least one hydrogen atom in an alpha position the products are a ketone, an alcohol and oxygen (eq. 15). This mechanism is troubling on theoretical grounds (1). Questions about its vaUdity remain (30), but it has received some recent support (31). [Pg.335]

In mbber production, the thiol acts as a chain transfer agent, in which it functions as a hydrogen atom donor to one mbber chain, effectively finishing chain growth for that polymer chain. The sulfur-based radical then either terminates with another radical species or initiates another chain. The thiol is used up in this process. The length of the mbber polymer chain is a function of the thiol concentration. The higher the concentration, the shorter the mbber chain and the softer the mbber. An array of thiols have subsequendy been utilized in the production of many different polymers. Some of these apphcations are as foUow ... [Pg.13]

Figure 18.16 One-dlmenslonal NMR spectra, (a) H-NMR spectrum of ethanol. The NMR signals (chemical shifts) for all the hydrogen atoms In this small molecule are clearly separated from each other. In this spectrum the signal from the CH3 protons Is split Into three peaks and that from the CH2 protons Into four peaks close to each other, due to the experimental conditions, (b) H-NMR spectrum of a small protein, the C-terminal domain of a cellulase, comprising 36 amino acid residues. The NMR signals from many individual hydrogen atoms overlap and peaks are obtained that comprise signals from many hydrogen atoms. (Courtesy of Per Kraulis, Uppsala, from data published in Kraulis et al.. Biochemistry 28 7241-7257, 1989.)... Figure 18.16 One-dlmenslonal NMR spectra, (a) H-NMR spectrum of ethanol. The NMR signals (chemical shifts) for all the hydrogen atoms In this small molecule are clearly separated from each other. In this spectrum the signal from the CH3 protons Is split Into three peaks and that from the CH2 protons Into four peaks close to each other, due to the experimental conditions, (b) H-NMR spectrum of a small protein, the C-terminal domain of a cellulase, comprising 36 amino acid residues. The NMR signals from many individual hydrogen atoms overlap and peaks are obtained that comprise signals from many hydrogen atoms. (Courtesy of Per Kraulis, Uppsala, from data published in Kraulis et al.. Biochemistry 28 7241-7257, 1989.)...
Figure 18.17 Two-dimensional NMR spectnim of the C-terminal domain of a cellulase. The peaks along the diagonal correspond to the spectrum shown in Figure 18.16b. The off-diagonal peaks in this NOE spectrum represent interactions between hydrogen atoms that are closer than 5 A to each other in space. From such a spectrum one can obtain information on both the secondary and tertiary structures of the protein. (Courtesy of Per Kraulis, Uppsala.)... Figure 18.17 Two-dimensional NMR spectnim of the C-terminal domain of a cellulase. The peaks along the diagonal correspond to the spectrum shown in Figure 18.16b. The off-diagonal peaks in this NOE spectrum represent interactions between hydrogen atoms that are closer than 5 A to each other in space. From such a spectrum one can obtain information on both the secondary and tertiary structures of the protein. (Courtesy of Per Kraulis, Uppsala.)...
Figure 18.20 The two-dimensional NMR spectrum shown in Figure 18.17 was used to derive a number of distance constraints for different hydrogen atoms along the polypeptide chain of the C-terminal domain of a cellulase. The diagram shows 10 superimposed structures that all satisfy the distance constraints equally well. These structures are all quite similar since a large number of constraints were experimentally obtained. (Courtesy of P. Kraulis, Uppsala, from data published in P. Kraulis et ah. Biochemistry 28 7241-7257, 1989, by copyright permission of the American Chemical Society.)... Figure 18.20 The two-dimensional NMR spectrum shown in Figure 18.17 was used to derive a number of distance constraints for different hydrogen atoms along the polypeptide chain of the C-terminal domain of a cellulase. The diagram shows 10 superimposed structures that all satisfy the distance constraints equally well. These structures are all quite similar since a large number of constraints were experimentally obtained. (Courtesy of P. Kraulis, Uppsala, from data published in P. Kraulis et ah. Biochemistry 28 7241-7257, 1989, by copyright permission of the American Chemical Society.)...
Other mild oxidising agents which abstract the terminal hydrogen atoms and thus facilitate disulphide formation may be used as vulcanising agents. They include benzoyl peroxide, p-nitrosobenzene and p-quinone dioxime. [Pg.553]

Thermal decomposition of LiR eliminates a /6-hydrogen atom to give an olefin and LiH, a process of industrial importance for long-chain terminal alkenes. Alkenes can also be produced by treatment of ethers, the organometallic reacting here as a very strong base (proton acceptor) ... [Pg.105]

Proposed structure of Bi4H , omitting Teiminal hydrogen atoms have been omilled terminal hydrogen atoms for clarity for clarity... [Pg.173]

Free radicals may also react with a hydrocarbon molecule from the feed by abstracting a hydrogen atom. In this case the attacking radical is terminated, and a new free radical is formed. Abstraction of a hydrogen atom can occur at any position along the chain. However, the rate of hydrogen abstraction is faster from a tertiary position than from a secondary, which is faster than from a primary position. [Pg.56]

The newly formed free radical may terminate by abstraction of a hydrogen atom, or it may continue cracking to give ethylene and a free radical. Aromatic compounds with side chains are usually dealkylated. The produced free radicals further crack to yield more olefins. [Pg.92]

The acidic hydrogen in terminal alkynes can readily be replaced by silver, in a diagnostic test. [(Me3P)Ag(C=CPh)] has a polymeric structure while [(Ph3P)Ag(C=CPh)]4 is made of [Ag(PPh3)2]+ and [Ag(C=CPh)2] fragments linked so that the silver atoms form a square [147]. [Pg.308]

Both terminal and internal acyclic alkenes can be metathesized, corresponding to Eq. (4), where R is an alkyl group or a hydrogen atom. [Pg.133]

Studies with simple radicals show that carbon-centered radicals react with phenols by abstracting a phenolic hydrogen (Scheme 5.14). The phenoxy radicals may then scavenge a further radical by C -C or C-O coupling or (in the case of hydroquinones) by loss of a hydrogen atom to give a quinone. The quinone may then react further (Section 5.4.4). Thus two or more propagating chains may be terminated for every mole of phenol.I9j... [Pg.270]

Benzene may react by addition as shown in Scheme 6.12 (this pathway is also open to other aromatic solvents). The cyclohexadienyl radical is a poor initiating species and may terminate a second chain by hydrogen atom transfer. According to this process, benzene is a retarder rather than a transfer agent. [Pg.295]

To avoid these stability problems, it is necessary to minimize the proportion of chains that terminate by radical-radical reaction. One way of achieving this is to conduct the polymerization in the presence of an appropriate chain transfer agent. For example, if polymerization is performed in the presence of a H-donor chain transfer agent, conditions can be chosen such that most chains terminate by hydrogen-atom transfer. Bagby et al.iA examined the thermal stability of PMMA formed with dodecanethiol. These polymer chains will then possess, more... [Pg.418]


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See also in sourсe #XX -- [ Pg.3 ]




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