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And electronic effects

Deviation includes, in fact, the summation of steric and electronic effects, and basicity is somewhat a useful predictor for properties of complex dyes (solvent sensitivity, isomeric forms of trinuclear dyes) and gives also semiquantitative data for color structure relation (atomic)... [Pg.71]

The quatemization of the nitrogen atom of the thiazole ring (the Menschutkin s reaction) by alkyl halide or methyl tosylate can be used to measure the reactivity of this atom and thus to evaluate steric and electronic effects of ring substituents. [Pg.386]

Steric and electronic effects influence the rate of nucleophilic addition to a proton ated carbonyl group m much the same way as they do for the case of a neutral one and protonated aldehydes react faster than protonated ketones... [Pg.717]

The BDE theory does not explain all observed experimental results. Addition reactions are not adequately handled at all, mosdy owing to steric and electronic effects in the transition state. Thus it is important to consider both the reactivities of the radical and the intended coreactant or environment in any attempt to predict the course of a radical reaction (18). AppHcation of frontier molecular orbital theory may be more appropriate to explain certain reactions (19). [Pg.221]

Hydrolysis reactions involving tetrahedral intermediates are subject to steric and electronic effects. Electron-withdrawing substituents faciUtate, but electron-donating and bulky substituents retard basic hydrolysis. Steric effects in acid-cataly2ed hydrolysis are similar to those in base-cataly2ed hydrolysis, but electronic effects are much less important in acid-cataly2ed reactions. Higher temperatures also accelerate the reaction. [Pg.388]

The steric and electronic effects of substituents on the electrophilic attack at the nitrogen atom have been discussed in the general chapter on reactivity (Section 4.02.1.3). All the conclusions are valid for pyrazoles and indazoles. The effect on equilibrium constants will be discussed in detail in the sections dealing with values (Sections 4.04.2.1.3(iv) and (v)) and the kinetic effects on the rates of quaternization in the corresponding section (4.04.2.1.3(vii)). [Pg.223]

A mechanism has been proposed to rationalize the results shown in Figure 23. The relative proportion of the A -pyrazolines obtained by the reduction of pyrazolium salts depends on steric and electronic effects. When all the substituents are alkyl groups, the hydride ion attacks the less hindered carbon atom for example when = Bu only C-5 is attacked. The smaller deuterohydride ion is less sensitive to steric effects and consequently the reaction is less selective (73BSF288). Phenyl substituents, both on the nitrogen atom and on the carbon atoms, direct the hydride attack selectively to one carbon atom and the isolated A -pyrazoline has the C—C double bond conjugated with the phenyl (328 R or R = Ph). Open-chain compounds are always formed during the reduction of pyrazolium salts, becoming predominant in the reduction of amino substituted pyrazoliums. [Pg.243]

The rate of dimerization of nitrile A-oxides is strongly influenced by the nature of R. When R = Cl, Br, CO2 alkyl or COR, the nitrile A-oxide cannot be isolated nor obtained in solution for any appreciable time. Table 11 gives the approximate time required for complete dimerization of some nitrile A-oxides (335) to furoxans (336) in benzene solution at 18 °C (70E1169). Evidently, steric and electronic effects dramatically increase the stability... [Pg.66]

Silyl ethers are among the most frequently used protective groups for the alcohol function. This stems largely from the fact that their reactivity (both formation and cleavage) can be modulated by a suitable choice of substituents on the silicon atom. Both steric and electronic effects are the basic controlling elements that regulate the ease of cleavage in multiply functionalized substrates. In plan-... [Pg.113]

Studies have established that the partition between transition states 3 and 4 depends on the nature of the diol unit bound to boron and on the steric and electronic effects of the a-sub-stituent X23. The data shown below demonstrate that the reactions of2-(l-methyl-2-propenyl)-4,4,5,5-tetramethyl-l,3,2-dioxaborolane proceed with a moderate preference for transition state 3 with the C2 methyl group in an axial position. Selectivity diminishes with 2-(l-methyl-2-propenyl)-l,3,2-dioxaborolane and reverses with dimethyl (l-methyl-2-propenyl)boronale, suggesting that steric interactions (gauche interactions in the case of the tetramethyl-1,3,2-diox-aborolane) between X and the diol unit on boron are capable of destabilizing transition state 4 relative to 3. [Pg.321]

The sterochemistry adopted between these complexes appears to be a balance between steric and electronic effects. [Pg.229]

One can use an LFER to facilitate the separation and quantitation of the effects of different variables on the reaction. Thus, steric and electronic effects can be explored by selecting a subseries in which only one of them varies. [Pg.224]

Cyclic systems have frequently been used in studies of chemical bonding and reactivity, reaction mechanisms and a variety of other problems of interest to chemists3. Their utility depends on the changes in the carbon-carbon and the carbon-heteroatom bonds as well as on steric and electronic effects that result from the introduction of heteroatoms into the system. Indeed, the carbon-heteroatom bond length in small rings shows an effective increase with increasing heteroatom electronegativity4, in line with a... [Pg.381]

In 1991, an important paper was published by Bock et a/.84 that described the steric and electronic effects on the formation of the dispiroketal dihexulose dianhydrides. The authors described the conformation of six dihexulose dianhydrides, as determined by X-ray crystallography or NMR spectroscopy. They concluded that these conformations are dictated by the anomeric and exo-anomeric effects. Thus, the dihexulose dianhydrides are disposed to adopt conformations that permit operation of these effects—even if this results in the dioxane ring having a boat conformation or all three substituents on one pyranose ring being axial. [Pg.225]

Cycloaddition reactions of (E)-l-acetoxybutadiene (18a) and (E)-l-methoxy-butadiene (18b) with the acrylic and crotonic dienophiles 19 were studied under high pressure conditions [9] (Table 5.1). Whereas the reactions of 18a with acrylic dienophiles regioselectively and stereoselectively afforded only ortho-enJo-adducts 20 in fair to good yields, those with crotonic dienophiles did not work. Similar results were obtained in the reactions with diene 18b. The loss of reactivity of the crotonic dienophiles has been ascribed to the combination of steric and electronic effects due to the methyl group at the )S-carbon of the olefinic double bond. [Pg.208]

Nickel and palladium react with a number of olefins other than ethylene, to afford a wide range of binary complexes. With styrene (11), Ni atoms react at 77 K to form tris(styrene)Ni(0), a red-brown solid that decomposes at -20 °C. The ability of nickel atoms to coordinate three olefins with a bulky phenyl substituent illustrates that the steric and electronic effects (54,141) responsible for the stability of a tris (planar) coordination are not sufficiently great to preclude formation of a tris complex rather than a bis (olefin) species as the highest-stoichiometry complex. In contrast to the nickel-atom reaction, chromium atoms react (11) with styrene, to form both polystyrene and an intractable material in which chromium is bonded to polystyrene. It would be interesting to ascertain whether such a polymeric material might have any catal3dic activity, in view of the current interest in polymer-sup-ported catalysts (51). [Pg.149]

The exact enthalpy of polymerization for a particular monomer will depend on the steric and electronic effects imposed by the substituents attached to the E=E double bond. For olefins, resonance stabihzation of the double bond and increased strain in the polymer due to substituent interactions are the most important factors governing AHp For example, propylene has a calculated AH of -94.0 kJ moT, whereas the polymerization of the bulkier 2-methylpropene is less exothermic (-78.2 kJ moT ) [63]. Due to resonance effects, the experimentally determined AH of styrene (-72.8 kJ mol ) is less exothermic than that for propylene, while that for bulkier a-methylstyrene is even less favorable (-33.5 kJ moT ) [63]. In general, bulky 1,2-disubstituted olefins (i.e., PhHC= CHPh) are either very difficult or impossible to polymerize. [Pg.114]

This approach did not seem to be as satisfactory for those sulfamates having heteroatom substituents (hetero-sulfamates). Spillane suggested that the various electronic effects of the hetero-atoms probably introduce an additional variable that is apparently absent, or constant, for the carbosulfamates. Because molecular connectivity correlates structure with molecular volume and electronic effects, Spillane included molecular connectivity, (computed for the entire molecule, RNHSOO to the four variables, x, y, z, and V, and applied the statistical technique of linear-discrimination analysis to 33 heterosulfamates (10 sweet, 23 not sweet). A correlation of >80% was obtained for the x, z, x subset 5 of the 33... [Pg.302]

When aromatics, even single-ring compoimds such as benzene, have one substituent already, the introduction of the next also gives rise to regioisomerism. In addition, the first one guides the introduction of the second by steric and electronic effects. [Pg.72]

These results show that the electrochemical measurements can, via ab initio simulations, be linked to phenomena at the atomic level, such as structural and electronic effects and, in this case, binding energies on the surfaces. [Pg.65]


See other pages where And electronic effects is mentioned: [Pg.137]    [Pg.305]    [Pg.313]    [Pg.101]    [Pg.247]    [Pg.4]    [Pg.129]    [Pg.37]    [Pg.78]    [Pg.216]    [Pg.311]    [Pg.83]    [Pg.603]    [Pg.634]    [Pg.81]    [Pg.220]    [Pg.205]    [Pg.40]    [Pg.300]    [Pg.823]    [Pg.49]    [Pg.67]    [Pg.108]    [Pg.81]    [Pg.276]   
See also in sourсe #XX -- [ Pg.1386 ]




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Anomeric Control by Electronic and Steric Effects

Combining steric and electronic effects

Conformational and Electronic Effects

ELECTRONIC AND ELECTRICAL EFFECTS OF SOLVENTS

Effect of Electron Withdrawing Substituents in OsO4 Reactions and Pinacol-Pinacolone Reaction

Effect of Nonbonding Electrons and Multiple Bonds on Bond Angles

Effective Electron and Hole Masses

Effective Electronic Coupling in Duplexes with Separated Donor and Acceptor Sites

Effective masses of electrons and holes

Effects of Electron Correlation and Matrices

Effects of Electron Correlations and Structure on Cluster Magnetism

Effects on Electronic Properties and Reactivity

Electron correlation effects and

Electron-directing and steric effects solvents

Electronic Bite Angle Effect and Activity

Electronic Effects and Carbohydrate Conformation

Electronic Effects in Metallocenes and Certain Related Systems

Electronic Shell Effects in Monomer and Dimer Separation Energies

Electronic effect on the destabilization of carbonyl and

Electronic effects of heteroaromatic and

Electrons photoelectric effect and

Nuclear and Electronic Spin Effects

Phosphines and phosphites electronic effects

Relativistic effects and electronic

Relativistic effects and electronic structur

Relativistic effects and electronic structure

Rock Salt Layers and Their Effect on Electronic Properties

Steric and electronic effects

Symmetrized squares, electronic states and the Jahn-Teller effect

Torsional and electronic effects

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