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Nickel ligand substitution reaction

Much of the focus of these studies has been on the relation between ligand substitution reaction mechanisms on octahedral nickel(II) and the dynamics of the planar-octahedral equilibria. For typical octa-... [Pg.32]

Neutral nickel bis(dithiolene) complexes undergo ligand substitution reactions with a variety of amines to form mixed-ligand dithiolene complexes (52, 60). Dance and Miller (60) pointed out that reduction of electron-poor bis(dithiolene) complexes ( i/2 > 0 V vs. SCE) by halides or pseudo-halides, unhindered amines, or common weakly Lewis basic solvents (such as acetonitrile)... [Pg.279]

Mixed-ligand complexes such as nickel dithiolene diimine can be prepared via ligand substitution reactions (Eq. 6) (52). [Pg.280]

A key feature of many olefin polymerization catalysts based on square-planar nickel compounds is the presence of ligands, which provide considerable steric hindrance to access the sites of coordinative unsaturation above and below the square plane." " The complex /r 7/ .r-NiGl2 l,3-bis(2,6diisopropylphenyl)imidazol-2-ylidene 2 15 was synthesized from NiGl2(PPh3)2 by a ligand-substitution reaction." ... [Pg.10]

It has been pointed out that the types of solvents which are used here, are not generally such as would enter into strong association with the substrate. The molecularity of the substitution reaction may then stand more chance of being an operational concept. Amongst the binary carbonyls, the only systems which have been extensively studied have been nickel tetracarbonyl and the hexacarbonyls of group VI. For the former, the observation of a first-order rate is at least consistent with a rate-determining dissociation of one carbonyl ligand followed by reaction of the intermediate with whichever nucleophile should be available. [Pg.28]

In a series of studies of the spectroscopy and photochemistry of nickel(O) -a-diimine complexes, the structural differences among the complexes NiL2 and Ni(CO)2L (L Q-diimine) have been examined by means of molecular orbital calculations and electronic absorption Raman resonance studies.2471, 472 Summing up earlier work, the noninnocence of a-diimine ligands with a flat — N=C—C=N— skeleton in low-valent Ni chemistry and the course of substitution reactions of Ni° complexes with 1,4-diaza-1,3-dienes or a,a -bipyridine have been reviewed.2473... [Pg.501]

Tetramethyl- or tetraphenyl- (cyclobutadiene)nickel dihalides undergo reductive ligand substitution with nitrogen donor ligands such as 2,2 -bipyridine or 1,4-diaza-1,3-dienes with the addition of sodium metal237. The 2,2/-bipyridyl ligand is readily displaced and reaction of this complex with a variety of olefins and alkynes leads to cycloaddition reactions with the cyclobutadiene ligand. [Pg.969]

The kinetics and mechanisms of substitution reactions of metal complexes are discussed with emphasis on factors affecting the reactions of chelates and multidentate ligands. Evidence for associative mechanisms is reviewed. The substitution behavior of copper(III) and nickel(III) complexes is presented. Factors affecting the formation and dissociation rates of chelates are considered along with proton-transfer and nucleophilic substitution reactions of metal peptide complexes. The rate constants for the replacement of tripeptides from copper(II) by triethylene-... [Pg.9]

Ten years ago Rorabacher (13) observed the substitution rate constants for aquonickel(II) ion with different amines (Table II). There is a decrease in the rate constants by a factor of 14 in going from ammonia to dimethylamine. If nickel-(II) substitution reactions are dissociative, then why is the effect this large Is this a steric effect with some associative contribution or is it an outer-sphere effect There has been surprisingly little investigation of the nature of the entering ligand so far as its bulk or its nucleophilicity is concerned even for what have been generally considered as simple substitution reactions. [Pg.11]

Dale Margerum Ralph Wilkins has mentioned the interesting effect of terpyridine on the subsequent substitution reaction of the nickel complex. I would like to discuss this point—namely the effect of coordination of other ligands on the rate of substitution of the remaining coordinated water. However, before proceeding we should first focus attention on the main point of this paper-which is that a tremendous amount of kinetic data for the rate of formation of all kinds of metal complexes can be correlated with the rate of water substitution of the simple aquo metal ion. This also means that dissociation rate constants of metal complexes can be predicted from the stability constants of the complexes and the rate constant of water exchange. The data from the paper are so convincing that we can proceed to other points of discussion. [Pg.66]

The field of nickel complexes with macrocydic ligands is enormous and continuous interest in this area in recent years has resulted in innumerable publications. A number of books and review articles are also available covering the general argument of the bonding capability of the various macrocydic ligands towards transition and non-transition metals. 22 2627 Synthetic procedures for metal complexes with some tetraaza macrocycles have been reported.2628 Kinetics and mechanism of substitution reactions of six-coordinate macrocydic complexes have also been reviewed.2629... [Pg.226]

Binuclear complexes have also been obtained by the electrophilic substitution reaction of [Ni(Me2[Z]dienatoN4)]+ (Z = 13,14) with -substituted benzoyl chlorides (Scheme 53), 2791 A series of dimeric nickel(II) complexes of type (385) has been synthesized as outlined in Scheme 54.2792 In the complex with m-xylene bridges the two nickel(II) atoms are 1360 pm apart, separated by the cavity of the pair of 16-membered macrocyclic ligands. [Pg.255]

Nickel(II) complexes with cryptands are still rare. In general the encapsulation of nickel(II) in this type of macrocyclic ligand makes the complexes extraordinarily resistant to dissociation and substitution reactions. [Pg.270]

The significant changes imposed on the dithioaromatic ligands and complexes upon sulfur addition are illustrated in the structure of the Ni(p-/-PrPhDtaXp-(-PrPhDtaS) complex (Fig. 48) (Table XXII), determined by Fackler et al. (233, 257). The same workers explored the sulfur addition and abstraction reaction in depth (232) (see also Section IV). The rates and mechanisms of substitution reactions of square planar nickel(II) 1,1 -dithiolate complexes (502) is discussed in Section IV. [Pg.418]

The analogy between imines and carbonyls was introduced earlier, and just as 1,3-dike-tonate complexes undergo electrophilic substitution reactions at the 2-position, so do their nitrogen analogues. Reactions of this type are commonly observed in macrocyclic ligands, and many examples are known. Electrophilic reactions ranging from nitration and Friedel-Crafts acylation to Michael addition have been described. Reactions of 1,3-diimi-nes and of 3-iminoketones are well known. The reactions are useful for the synthesis of derivatised macrocyclic complexes, as in the preparation of the nickel(n) complex of a nitro-substituted ligand depicted in Fig. 5-12. [Pg.95]

See other pages where Nickel ligand substitution reaction is mentioned: [Pg.451]    [Pg.515]    [Pg.322]    [Pg.200]    [Pg.12]    [Pg.169]    [Pg.349]    [Pg.331]    [Pg.22]    [Pg.75]    [Pg.395]    [Pg.311]    [Pg.33]    [Pg.43]    [Pg.221]    [Pg.6]    [Pg.106]    [Pg.222]    [Pg.203]    [Pg.67]    [Pg.23]    [Pg.150]    [Pg.273]    [Pg.168]    [Pg.395]    [Pg.37]    [Pg.57]    [Pg.3606]    [Pg.371]   
See also in sourсe #XX -- [ Pg.107 , Pg.111 , Pg.123 ]



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