Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Coordination complexes, palladium

Coordination Compounds. Palladium forms numerous complexes with ammonia and with simple amines. Examples ate [Pd(NH2)4] ... [Pg.182]

A review17 with 25 references of five-coordination in palladium(II) and platinum(II) chemistry is presented. The complexes have invariably a trigonal bipyramidal geometry with the bidentate ligand and the alkene in the equatorial plane. [Pg.557]

A review20 with 101 references includes topics on coordination complexes of palladium and catalysis. [Pg.557]

The susceptibility of phosphites to hydrolysis limits their application as ligands for homogeneous catalysis. The fused tricyclic monophosphites derived from ca 1 i x[4]arenes260-262 form coordination complexes with palladium.263... [Pg.576]

Kostic el al. discovered that Pd11 complexes, when attached to tryptophan residues, can rapidly cleave peptides in acetone solutions to which a stoichiometric amount of water is added, for hydrolysis.436 The indole tautomer in which a hydrogen has moved from the nitrogen to C(3) is named indolenine. Its palladium(II) complexes that are coordinated via the nitrogen atom have been characterized by X-ray crystallography and spectroscopic methods.451 Binuclear dimeric complexes between palladium(II) and indole-3-acetate involve cyclopalladation.452 Bidentate coordination to palladium(II) through the N(l) and the C(2) atoms occurs in binuclear complexes.453 Reactions of palladium(II) complexes with indole-3-acetamide and its derivatives produced new complexes of unusual structure. Various NMR, UV, IR, and mass spectral analyses have revealed bidentate coordination via the indole carbon C(3) and the amide oxygen.437... [Pg.594]

The carbonylation was explained by the following mechanism. Formation of dimeric 7r-allylic complex 20 from two moles of butadiene and the halide-free palladium species is followed by carbon monoxide insertion at the allylic position to give an acyl palladium complex which then collapses to give 3,8-nonadienoate by the attack of alcohol with regeneration of the zero-valent palladium phosphine complex. When halide ion is coordinated to palladium, the formation of the above dimeric 7r-allylic complex 20 is not possible, and only monomeric 7r-allylic complex 74 is formed. Carbon monoxide insertion then gives 3-pentenoate (72). [Pg.166]

If the unsaturated hydrocarbon is a diene, both double bonds may coordinate to palladium ). (Diene)palladium(II) complexes have been isolated and characterized. For example, 2 and 3 are stable complexes in which both double bonds are coordinated to the metal10. Conjugated dienes constitute a special case and although /j4-diene complexes, e.g. 4, are postulated as intermediates, they have not yet been isolated. The butadiene complex 4 is in equilibrium with the zr-allyl complex 5 in solution, and attempts to isolate the diene complex from this mixture lead to formation of a yellow crystalline complex 511. [Pg.654]

Thallium(i) Derivatives of Nickel, Palladium, Platinum, and Gold Coordination Complexes 395... [Pg.343]

Table 14 Palladium, platinum, and gold coordination complexes that bind thallium... Table 14 Palladium, platinum, and gold coordination complexes that bind thallium...
Good diastereoselectivity was obtained with BQ as the oxidant in acidic media but the reaction times were relatively long (1-2 days at 40 °C). Using the copper(II)-oxy-gen system in slightly basic media permits a much faster reaction (0.5-1 h at 20 °C) with better isolated yields but with poor or even reversed diastereoselectivity. The slower reaction with BQ as oxidant is due to the fact that this oxidant requires an acidic medium, which lowers the nucleophilicity of the acid moiety. It is also likely that BQ or copper(II) has to coordinate to palladium(II) before the second nucleophile can attack to make the Jt-allyl complex more electrophilic. Coordination of cop-per(II) would make a more electrophilic intermediate than coordination of BQ. The relation between reaction time and diastereoselectivity supports a mechanism analogous to that in Scheme 17.7. [Pg.979]

The hydride cycle starts with palladium hydride and a fast migratory insertion of ethene. Insertion of CO is also a last reaction, enhanced by the preferential coordination of CO with respect to ethene. The product is formed by reaction of propanoylpalladium with methanol which coordinates to palladium cis to the acyl group. A palladium zero complex may form that regenerates palladium hydride via an oxidative addition with a proton. [Pg.259]

The active species in the catalytic cycles are square-planar Pd complexes of the formula [Pd (X)(S)(L-L)]Y where L-L is a chelating ligand with the same or different donor atoms among P, N, O and S X is the growing polyketone chain or hydride S may be a solvent molecule, a co-monomer, or a keto group from the chain. Finally, Y is a counter-anion of weak nucleophilicity in order to avoid competition with the co-monomer for coordination to palladium (Scheme 7.1). [Pg.271]

A study of Pd(PPhs)4,4, reported recently by Roth and coworkers, reveals yet another mechanistic pathway for Pd° oxygenation [122]. Complete dissociation of one PPha ligand from Pd occurs in solution to produce a three-coordinate palladium(O) species, 26. Kinetic studies reveal that 26 reacts with dioxygen via parallel associative and dissociative pathways (Scheme 5). The latter dissociative pathway results in the formation of the two-coordinate complex 27, which undergoes very rapid reaction with dioxygen in a manner directly analogous to that of the well-defined two-coordinate NHC complexes 23 and 24. [Pg.90]

However, most of this section will be concerned with apparently hexa-coordinated complexes of palladium(II) and of platinum(II). Most of the evidence for the existence of such complexes comes from spectroscopic and conductivity studies on solutions, but there is a certain amount of crystallographic information available. [Pg.173]

In general, penta-coordinated complexes are rather rare. So far as nickel, palladium, and platinum are concerned, it seems that such complexes may be formed as intermediates when square-planar complexes accept further ligands in their tendency to become hexa-coordinated. The... [Pg.177]

In the same way, the existence of two isomers, yellow and orange, of Pt(NH3)2Cl2 showed that these complexes are square planar, rather than tetrahedral (Fig. 13.2) the yellow one has no electric dipole moment and therefore is the trans isomer, whereas the orange does and is cis. A tetrahedral Pt(NH3)2Cl2 would have just one isomer (with a dipole moment). Four-coordinate complexes of platinum(II), palladium(II), and gold(III) are virtually always square planar, but tetrahedral complexes such as the purple... [Pg.242]

Tire early-late transition metal complex of Raymond et al. is interesting in that it requires both metal atoms to form the basic C3 structure (ideally D i, may form). Titanium complexation to three catechol units leads to a tridentate ligand, and, only when palladium bromide is added, trans coordination to palladium gives the agglomerate 31 [78]. [Pg.280]

Two selective processes are important in the oxidation of ethylene the production of ethylene oxide and acetaldehyde. The first process is specifically catalyzed by silver, the second one by palladium-based catalysts. Silver catalysts are unique and selective for the oxidation of ethylene. No similar situation exists for higher olefins. The effect of palladium catalysts shows a resemblance to the liquid phase oxidation of ethylene in the Wacker process, in which Pd—C2H4 coordination complexes are involved. The high selectivity of the liquid phase process (95%), however, is not matched by the gas phase route at present. [Pg.126]


See other pages where Coordination complexes, palladium is mentioned: [Pg.182]    [Pg.226]    [Pg.1439]    [Pg.203]    [Pg.250]    [Pg.9]    [Pg.585]    [Pg.593]    [Pg.596]    [Pg.597]    [Pg.646]    [Pg.78]    [Pg.264]    [Pg.297]    [Pg.392]    [Pg.392]    [Pg.1066]    [Pg.594]    [Pg.85]    [Pg.395]    [Pg.245]    [Pg.325]    [Pg.326]    [Pg.146]    [Pg.337]    [Pg.92]    [Pg.106]    [Pg.208]    [Pg.210]    [Pg.153]   
See also in sourсe #XX -- [ Pg.221 ]

See also in sourсe #XX -- [ Pg.221 ]




SEARCH



Palladium Penta-coordinate complexes

Palladium complexes 5-coordinate

Palladium complexes effect of ligand size on coordination number

Palladium five-coordinate complexes

Palladium-carbon dioxide complex, coordination

© 2024 chempedia.info