Kinetics methoxide

Charge diagrams suggest that the 2-amino-5-halothiazoles are less sensitive to nucleophilic attack on 5-position than their thiazole counterpart. Recent kinetic data on this reactivity however, show, that this expectation is not fulfilled (67) the ratio fc.. bron.c.-2-am.noih.azoie/ -biomoth.azoie O"" (reaction with sodium methoxide) emphasizes the very unusual amino activation to nucleophilic substitution. The reason of this activation could lie in the protomeric equilibrium, the reactive species being either under protomeric form 2 or 3 (General Introduction to Protomeric Thiazoles). The reactivity of halothiazoles should, however, be reinvestigated under the point of view of the mechanism (1690). 

The reaction of MeO /MeOH with 2-Cl-5(4)-X-thiazoles (122) follows a second-order kinetic law, first order with respect to each reactant (Scheme 62) (297, 301). A remark can be made about the reactivity of the dichloro derivatives it has been pointed out that for reactions with sodium methoxide, the sequence 5>2>4 was observed for monochlorothiazole compounds (302), For 2.5-dichlorothiazole, on the contrary, the experimental data show that the 2-methoxy dehalogenation is always favored. This fact has been related to the different activation due to a substituent effect, less important from position 2 to 5 than from... 

The following table gives exchange rates in methanolic sodium methoxide for a number of hydrocarbons and equilibrium acidities for some. Determine whether there is a correlation between kinetic and thermodynamic acidity in this series of compounds. If so, predict the thermodynamic acidity of the hydrocarbons for which no values are listed. 

Interestingly, true hydrides, such as NaH and KH, do not reduce carbonyl groups. Using energies of hydride and methoxide (at left), calculate AH xn for the reduction of formaldehyde by H. Is this reaction more or less favorable than those based on ZH4 Can the low reactivity of NaH and KH be attributed to thermodynamic factors, or must kinetic factors be responsible ... 

A similar kinetic effect was reported for the reaction of 4-chloro-pyridine 1-oxide with methoxide ion at 50°, and still larger effects were obtained with the 2- and 3-isomers at the same temperature. ... 

The kinetic effects of some substituents on the fused benzene ring (CHg, NOg, OCHg, Cl) havc been determined recently for the reaction between the methoxide ion and the series of compounds aj-R-2-chlorobenzothiazole. Some of these effects are compared in Table XVIII with those observed at the 6-position of 2-chloroquino-lines and quinoxalines which are of the conjugative class. The data for... 

Irregular kinetics were observed in methoxy-dechlorination of 1-chloro-2,4,5-tiinitronaphthalene. This observation was shown to arise from reaction of the 1-methoxy product with more methoxide ion to form the intermediate complex 389 comparable to that formed... 

Chloroquinoline (401) reacts well with potassium fluoride in dimethylsulfone while its monocyclic analog 2-chloropyridine does not. Greater reactivity of derivatives of the bicyclic azine is evident also from the kinetic data (Table X, p. 336). 2-Chloroquinoline is alkoxylated by brief heating with methanolic methoxide or ethano-lic potassium hydroxide and is converted in very high yield into the thioether by trituration with thiocresol (20°, few hrs). It also reacts with active methylene carbanions (45-100% yield). The less reactive 3-halogen can be replaced under vigorous conditions (160°, aqueous ammonia-copper sulfate), as used for 3-bromoquino-line or its iV-oxide. 4-Chloroquinoline (406) is substituted by alcoholic hydrazine hydrate (80°, < 8 hr, 20% yield) and by methanolic methoxide (140°, < 3 hr, > 90% yield). This apparent reversal of the relative reactivity does not appear to be reliable in the face of the kinetic data (Tables X and XI, pp. 336 and 338) and the other qualitative comparisons presented here. 

The diastereomeric ratio of the trimethylsilyl triflate catalyzed amidoalkylation of a number of silyl enol ethers at — 40 CC appears to be dependent on the substituents in the substrate87. At — 40 °C the diastereomeric ratio is shown to be kinetically controlled. On allowing the reaction mixture to warm to 20 "C slow epimerization, increasing the amount of the minor isomer, is observed. In the case of the naphthalene derivative, sodium methoxide catalyzed epimerization of the kinetic mixture [(antijsyn) 88 12] produces the thermodynamic mixture [(antijsyn) 9 91]. 

The reduction of tributyltin methoxide with optically active methyl-phenyl-1-naphthylsilane involves retention of configuration at the silicon atom and follows second-order kinetics (2 72). The reaction between tributyltin methoxide and ring-substituted dimethylphenylsilanes shows a Hammett p-value of -t-0.903, and that between dimethyl-phenylsilane and ring-substituted tributyltin phenoxides shows a p-value of -1.319 this is compatible with the reactions proceeding through a 4-centered (SNi-Si) transition state (272, 173). 

General Methods. Methanol used in kinetic runs was distilled from sodium methoxide or calcium hydride in a nitrogen atmosphere before use. Freshly distilled cyclohexanol was added to the methanol in the ratio 6.0 ml cyclohexanol/200 ml MeOH and was used as an internal standard for gas chromatographic (GC) analysis. Benzaldehyde was distilled under vacuum and stored under nitrogen at 5°. Other aldehydes (purchased from Aldrich) were also distilled before use. The corresponding alcohols (purchased from Aldrich) were distilled and used to prepare GC standards. All metal carbonyl cluster complexes were purchased from Strem Chemical Company and used as received. Tetrahydrofuran (THF) was distilled from sodium benzophenone under nitrogen before use. 

Zn2+-catalyzed cleavage of (Zn2+ HPNPP)2 in ethanol discussed above.85 For the slower reacting MNPP, the chemical cleavage step (represented by k3 and requiring a methoxide which is probably coordinated to one or both of the metal ions in 35 2Zn(II)) is relatively slow, so that both the pre-equilibrium steps are established and typical Michaelis-Menten behavior is observed with saturation at higher [35 2Zn(II)]. On the other hand, with the far more reactive HPNPP the chemical cyclization step, /c3, is proposed to be faster than the k 2 step in the concentration range of 35 2Zn(II) used here. In this event, the observed kinetics would be linear in [35 2Zn(II)] as is the case in Fig. 20, with kohs — /c, [35 2Zn(I )]k2/(k, + k2). 

A kinetic study of reactions between 4-substituted nitrosobenzene and methoxide ions (in methanol), to yield 4-substituted azoxybenzenes in the presence of oxygen, indicated... 

In the Michael addition reaction depicted in eq. [146] the diastereomeric sulfoxides 312 are formed under kinetic control conditions, therefore, the addition of sodium diethyl malonate is an irreversible process. On the contrary, addition of sodium methoxide to the sulfoxide 311 is a thermodynamically controlled process and leads to a mixture of diastereomeric ]3-methoxysulfoxides 313 in a 31 69 ratio (320). 

Nitrobenzoylamino)-2,2-dimethylpropanamide (143 R = Me) reacts in methanol-DMSO solution with sodium methoxide to yield 5,5-dimethyl-2-(4-nitrophenyl)imidazol-4(5//)-one (144 R = Me). The 4-methoxyphenyl derivative and the parent phenyl derivative react similarly, as do compounds in which variation of the 2-substitutent (R = Pr , Ph, 4-O2NC6H4) was made. The mechanism of the cyclization probably involves initial formation of the anion of the alkanamide (145), which adds to the carbonyl group of the benzamido moiety to yield the tetrahedral oxyanion (146) proton transfer and dehydration then yield the heterocycle (144). The kinetics of hydrolysis in water at 70 °C and pH 2-11 of A-glycidylmorpholine (147) have been reported. ... 

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