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Catalysis inhibition

Alfassi, Z. B., and Benson, S. W., A simple empirical method for the estimation of activation energies in radical molecule metathesis reactions, Int. J. Chem. Kinetics S, 879 (1973). Allara, D. L., and Edelson, D., A computational analysis of a chemical switch mechanism. Catalysis-inhibition effects in a copper surface-catalyzed oxidation, J. Phys. Chem. 81, 2443 (1977). [Pg.190]

Bifunctional phosphines also react forming chelating di-tertiary phosphines (Scheme 8). Serious catalysis inhibition by the product is not found. [Pg.30]

Bischoff, J. L. and Fyfe, W. S. Catalysis inhibition and the calcite-aragonite problem. I. The aragonite-calcite transformation. Amer. J. Sci. 266, 65 (1968)... [Pg.119]

Bischoff, J. L., and Fyfe, J. L. Catalysis, inhibition and the calcite-aragonite problem. [Pg.92]

Initial Studies Catalysis Inhibition Isolation or Detection of Intermediates ... [Pg.270]

Huang CS, Moore WR, Meister A (1988) On the active site thiol of y-glutamylcysteine synthetase relationship to catalysis, inhibition, and regulation. Proc Nad Acad Sci USA 85 2464-246830... [Pg.103]

Tables 7.6 and 7.7). Electronegative elements bound to the edge of graphene layers would attract electrons from the delocalized ir-electron system and thus reduce their capacity to transfer to adsorbed molecules. This might be an explanation of their catalysis-inhibiting effect. [Pg.259]

Investigation of facilitating and inhibiting influences (catalysis, inhibition). [Pg.401]

The theoretical description of electrocatalysis that takes into account electron and ion transfer and the transport process, the permeations of the substrates, and their combined involvement in the control over the overall kinetics has been elaborated by Albeiy and Hillman [312,313,373] and by Andrieux and Saveant [315], and a good summary can be found in [314]. Practically all of the possible cases have been considered, including Michaelis-Menten kinetics for enzyme catalysis. Inhibition, saturation, complex mediation, etc., have also been treated. The different situations have also been represented in diagrams. Based on the theoretical models, the respective forms of the Koutecky-Levich eqrration have been obtained, which make analyzing the resirlts of voltarrrmetry on stationary artd rotating disc electrodes a straightforward task. [Pg.253]

A group of cyclic peptides and peptide surfactants have been examined as potential catalysts for the hydrolysis of esters. Catalysis, inhibition and no activity was observed. ... [Pg.335]

Ligand-deficient catalysis, inhibition, and corresponding kinetic models were considered in Section 5.4.2. Generation of active sites in catalysis by organometaUic complexes involves a step outside the catalytic cycle, namely the loss of the figand from the catalyst. This step frees the coordinative site, allowing binding of the reactants. [Pg.549]

P. G. Ashmore, Catalysis and Inhibition of Chemical Reactions, Butterworths, London, 1963. [Pg.752]

A micelle-bound substrate will experience a reaction environment different from bulk water, leading to a kinetic medium effect. Hence, micelles are able to catalyse or inhibit organic reactions. Research on micellar catalysis has focused on the kinetics of the organic reactions involved. An overview of the multitude of transformations that have been studied in micellar media is beyond the scope of this chapter. Instead, the reader is referred to an extensive set of review articles and monographs" ... [Pg.129]

In this section the influence of micelles of cetyltrimethylammonium bromide (CTAB), sodium dodecylsulfate (SDS) and dodecyl heptaoxyethylene ether (C12E7) on the Diels-Alder reaction of 5.1a-g with 5.2 in the absence of Lewis-add catalysts is described (see Scheme 5.1). Note that the dienophiles can be divided into nonionic (5.1a-e), anionic (5.If) and cationic (5.1g) species. A comparison of the effect of nonionic (C12E7), anionic (SDS) and cationic (CTAB) micelles on the rates of their reaction with 5.2 will assess of the importance of electrostatic interactions in micellar catalysis or inhibition. [Pg.133]

In all surfactant solutions 5.2 can be expected to prefer the nonpolar micellar environment over the aqueous phase. Consequently, those surfactant/dienophile combinations where the dienophile resides primarily in the aqueous phase show inhibition. This is the case for 5.If and S.lg in C12E7 solution and for S.lg in CTAB solution. On the other hand, when diene, dienophile and copper ion simultaneously bind to the micelle, as is the case for Cu(DS)2 solutions with all three dienophiles, efficient micellar catalysis is observed. An intermediate situation exists for 5.1c in CTAB or C12E7 solutions and particularly for 5.If in CTAB solution. Now the dienophile binds to the micelle and is slid elded from the copper ions that apparently prefer the aqueous phase. Tliis results in an overall retardation, despite the possible locally increased concentration of 5.2 in the micelle. [Pg.142]

Elucidating Mechanisms for the Inhibition of Enzyme Catalysis An inhibitor interacts with an enzyme in a manner that decreases the enzyme s catalytic efficiency. Examples of inhibitors include some drugs and poisons. Irreversible inhibitors covalently bind to the enzyme s active site, producing a permanent loss in catalytic efficiency even when the inhibitor s concentration is decreased. Reversible inhibitors form noncovalent complexes with the enzyme, thereby causing a temporary de-... [Pg.638]

Metal Deactivators. The abiUty of metal ions to catalyse oxidation can be inhibited by metal deactivators (19). These additives chelate metal ions and increase the potential difference between the oxidised and reduced states of the metal ions. This decreases the abiUty of the metal to produce radicals from hydroperoxides by oxidation and reduction (eqs. 15 and 16). Complexation of the metal by the metal deactivator also blocks its abiUty to associate with a hydroperoxide, a requirement for catalysis (20). [Pg.228]

Many reactions catalyzed by the addition of simple metal ions involve chelation of the metal. The familiar autocatalysis of the oxidation of oxalate by permanganate results from the chelation of the oxalate and Mn (III) from the permanganate. Oxidation of ascorbic acid [50-81-7] C HgO, is catalyzed by copper (12). The stabilization of preparations containing ascorbic acid by the addition of a chelant appears to be negative catalysis of the oxidation but results from the sequestration of the copper. Many such inhibitions are the result of sequestration. Catalysis by chelation of metal ions with a reactant is usually accomphshed by polarization of the molecule, faciUtation of electron transfer by the metal, or orientation of reactants. [Pg.393]

A kinetic method for the determination of 2,4-dinitrophenol is proposed. The method is based on the inhibiting effect of 2,4-dinib ophenol on the Mn(II) catalysis of the oxidation of malachite green with potassium periodate. The reaction was followed spectrophotometrically at 615 nm. The optimal experimental conditions for the determination of 2,4-dinitrophenol were established under the optimal reaction conditions ... [Pg.136]

One advantage of the initial rate method is that it avoids any complications arising from product inhibition or catalysis or from subsequent reactions. Another advantage is that it is applicable to veiy slow reactions whose study by other methods might be impractical. [Pg.29]

For this specific task, ionic liquids containing allcylaluminiums proved unsuitable, due to their strong isomerization activity [102]. Since, mechanistically, only the linkage of two 1-butene molecules can give rise to the formation of linear octenes, isomerization activity in the solvent inhibits the formation of the desired product. Therefore, slightly acidic chloroaluminate melts that would enable selective nickel catalysis without the addition of alkylaluminiums were developed [104]. It was found that an acidic chloroaluminate ionic liquid buffered with small amounts of weak organic bases provided a solvent that allowed a selective, biphasic reaction with [(H-COD)Ni(hfacac)]. [Pg.247]

Poly(L-malate) decomposes spontaneously to L-ma-late by ester hydrolysis [2,4,5]. Hydrolytic degradation of the polymer sodium salt at pH 7.0 and 37°C results in a random cleavage of the polymer, the molecular mass decreasing by 50% after a period of 10 h [2]. The rate of hydrolysis is accelerated in acidic and alkaline solutions. This was first noted by changes in the activity of the polymer to inhibit DNA polymerase a of P. polycephalum [4]. The explanation of this phenomenon was that the degradation was slowest between pH 5-9 (Fig. 2) as would be expected if it were acid/base-catalyzed. In choosing a buffer, one should be aware of specific buffer catalysis. We found that the polymer was more stable in phosphate buffer than in Tris/HCl-buffer. [Pg.100]

Catalysis and Inhibition in Solutions of Synthetic Polymers and in Micellar Solutions H. Morawetz... [Pg.426]


See other pages where Catalysis inhibition is mentioned: [Pg.352]    [Pg.280]    [Pg.314]    [Pg.725]    [Pg.431]    [Pg.352]    [Pg.280]    [Pg.314]    [Pg.725]    [Pg.431]    [Pg.2706]    [Pg.2993]    [Pg.639]    [Pg.252]    [Pg.87]    [Pg.152]    [Pg.71]    [Pg.86]    [Pg.8]    [Pg.272]    [Pg.295]    [Pg.299]    [Pg.301]    [Pg.237]    [Pg.122]    [Pg.779]    [Pg.62]    [Pg.29]    [Pg.31]    [Pg.109]   
See also in sourсe #XX -- [ Pg.580 , Pg.580 ]




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