Nucleophilic substitution reactions complexes

Each of the following nucleophilic substitution reactions has been reported in the chemical literature Many of them involve reactants that are somewhat more complex than those we have dealt with to this point Nevertheless you should be able to predict the product by analogy to what you know about nucleophilic substitution in simple systems... 

Monomeric thiazyl halides can be stabilized by coordination to transition metals and a large number of such complexes are known (Section 7.5). In addition, NSX monomers undergo several types of reactions that can be classified as follows (a) reactions involving the n-system of the N=S bond (b) reactions at the nitrogen centre (c) nucleophilic substitution reactions (d) halide abstraction, and (e) halide addition. Examples of each type of behaviour are illustrated below. 

The alkylation process possesses the advantages that (a) a wide range of cheap haloalkanes are available, and (b) the substitution reactions generally occur smoothly at reasonable temperatures. Furthermore, the halide salts formed can easily be converted into salts with other anions. Although this section will concentrate on the reactions between simple haloalkanes and the amine, more complex side chains may be added, as discussed later in this chapter. The quaternization of amines and phosphines with haloalkanes has been loiown for many years, but the development of ionic liquids has resulted in several recent developments in the experimental techniques used for the reaction. In general, the reaction may be carried out with chloroalkanes, bromoalkanes, and iodoalkanes, with the reaction conditions required becoming steadily more gentle in the order Cl Br I, as expected for nucleophilic substitution reactions. Fluoride salts cannot be formed in this manner. 

Application of the principle of microscopic reversibility can be used to eliminate a mechanism suggested at one time for the nucleophilic substitution reactions of square-planar platinum(II) complexes. For the sake of specificity, we take PtCl - as a typical... 

The Ullman reaction has long been known as a method for the synthesis of aromatic ethers by the reaction of a phenol with an aromatic halide in the presence of a copper compound as a catalyst. It is a variation on the nucleophilic substitution reaction since a phenolic salt reacts with the halide. Nonactivated aromatic halides can be used in the synthesis of poly(arylene edier)s, dius providing a way of obtaining structures not available by the conventional nucleophilic route. The ease of halogen displacement was found to be the reverse of that observed for activated nucleophilic substitution reaction, that is, I > Br > Cl F. The polymerizations are conducted in benzophenone with a cuprous chloride-pyridine complex as a catalyst. Bromine compounds are the favored reactants.53,124 127 Poly(arylene ether)s have been prepared by Ullman coupling of bisphenols and... 

With the iron atom in its most negative oxidation state of —2 this complex possesses nucleophilic properties and thus can be used in nucleophilic substitution reactions. As the iron atom in this complex formally has ten valence electrons, it is isoelectronic with Pd(0), which is a well-known catalyst in allylic substitution reactions [49]. 

Additional experimental, theoretical, and computational work is needed to acquire a complete understanding of the microscopic dynamics of gas-phase SN2 nucleophilic substitution reactions. Experimental measurements of the SN2 reaction rate versus excitation of specific vibrational modes of RY (equation 1) are needed, as are experimental studies of the dissociation and isomerization rates of the X--RY complex versus specific excitations of the complex s intermolecular and intramolecular modes. Experimental studies that probe the molecular dynamics of the [X-. r - Y]- central barrier region would also be extremely useful. 

The susceptibility of d6 Ru, Os, and Ir halocarbene complexes to nucleophilic substitution reactions (see Section V) can also be understood in terms of this model, e.g.,... 

According to this mechanism, there is a first-order dependence on both the concentration of [ A B] and B, and the reaction is called an SN2 process (substitution, nucleophilic, second-order). Although many nucleophilic substitution reactions follow one of these simple rate laws, many others do not. More complex rate laws such as... 

Nucleophilic substitution reactions of halide anions in aprotic solvents are often accompanied by elimination reactions. For instance, reactions of secondary alkyl halides with potassium fluoride solubilized in acetonitrile with the aid of 18-crown-6 [3] give olefins as the main reaction product (Liotta and Harris, 1974). Similarly, the dicyclohexyl-18-crown-6 complex of potassium iodide acted exclusively as a base in its reaction with 2-bromo-octane in DMF (Sam and Simmons, 1974). The strongly basic character of weakly solvated fluoride has been exploited in peptide synthesis (Klausner and Chorev, 1977 Chorev and Klausner, 1976). It was shown that potassium fluoride solubilized... 

Hiibner GM, Reuter C, Seel C, Vogtle F (2000) Rotaxane synthesis via nucleophilic substitution reactions the trapping of electrophilic threads by organic anion-wheel complexes. Synthesis 1 103-108... 

Biirgi studied also a series of five coordinated cadmium complexes, 38, that contain three equatorial sulfur ligands, but in which the fourth and fifth, axial ligands, X and Y, are sometimes iodine, sometimes sulfur, and sometimes oxygen (84). The structural correlations have a clear interpretation in terms of the ligand exchange reaction and are reminiscent of the kind of process that is believed to occur in S 2-type nucleophilic substitution reactions ... 

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-... 

Nucleophilic substitution reactions of trien with copper-(II)-tripeptide complexes. I have long been fascinated by... 

Solvent exchange and complex formation are special cases of nucleophilic substitution reactions. 

This is not strictly correct, in that hydride, from say sodium hydride, never acts as a nucleophile, but because of its small size and high charge density it always acts as a base. Nevertheless, there are a number of complex metal hydrides such as lithium aluminium hydride (LiAlHj LAH) and sodium borohydride (NaBH4) that deliver hydride in such a manner that it appears to act as a nucleophile. We have already met these reagents under nucleophilic substitution reactions (see Section 6.3.5). Hydride is also a very poor leaving group, so hydride reduction reactions are also irreversible (see Section 7.1.2). 

Bonds typically hydrolyzed include carboxylic and phosphoric esters, amides, acetals, amidines, as well as metal ion complexes. (When a nucleophilic substitution reaction uses the solvent as the nucleophile, the reaction is often referred to as solvolysis.)... 

Couplings can also be carried out by simple nucleophilic substitution reactions of arenechromium tricarbonyls . For example, in the synthesis of biaryl 469, asymmetric lithiation of 463 using in situ silylation provides the complex 466 via 464 and 465. Nucleophilic substitution by the tolyl Grignard 467 yields 468 as a single atropisomer in 68% yield, and decomplexation gives the biaryl 469 in 92% yield (Scheme 184). 

The first step in the addition of alkoxides to Cgg is, consistently, the formation of the alkoxy Cgg anion. The subsequent process is strongly dependent on the presence of oxygen. In the presence of oxygen, 1,3-dioxolane derivatives of Cgg are formed [110]. In the absence of oxygen the oligo alkoxy fullerenide anions can be formed [111, 112]. Reaction of alkoxides with Cgg usually results in complex mixtures. This may be why only a few reactions of Cgg with alkoxides have been described [113]. Nevertheless, defined alkoxy fullerenes can be obtained by nucleophilic substitution reactions of alkoxides with halogenofullerenes (Chapter 9) [113]. 

The barrier that the reaction must overcome in order to proceed is determined by the difference in the solvation of the activated complex and the reactants. The activated complex itself is generally considered to be a transitory moiety, which cannot be isolated for its solvation properties to be studied, but in rare cases it is a reactive intermediate of a finite lifetime. The solvation properties of the activated complex must generally be inferred from its postulated chemical composition and conformation, whereas those of the reactants can be studied independently of the reaction. For organic nucleophilic substitution reactions, the Hughes-lngold rales permit qualitative predictions on the behavior of the rate when the polarity increases in a series of solvents, as is shown in Reichardt (Reichardt, 1988). 

The reaction rate is primarily determined by the enthalpy of activation (A// ), which is usually the case in square planar nucleophilic substitution reactions. Of greater importance, so far as a dissociative versus an associative mechanism is concerned, are the entropies and volumes of activation, AS and AY, respectively. Note that the values are negative for both the fct and the steps. The observed decrease in entropy is what we would expect for a mechanism in which two particles come together to give an activated complex. The volume of activation is determined by doing the reaction under high pressure ... 

If the thiophene ring bears one or more N02 groups, it becomes susceptible to nucleophilic attack by alkoxide ion an anionic cr-complex is thus produced which can be isolated in some cases. This is called a Meisenheimer adduct, and corresponds to the first step in many nucleophilic substitution reactions on activated thiophene substrates. The similarity between these adducts and heterocyclic pseudobases has been pointed out (79AHC(25)l). Kinetic data lead to similar rate equations for both processes both are characterized by negative entropies of activation of similar magnitude. 

The base hydrolyses of PtCl(NH3) + and c/s-PtCl2(NH3)4+ are possibly examples of nucleophilic substitution reactions 204 these remain the only cases which have not been proven otherwise. These reactions follow a rate law which is first order in the platinum(IV) complex, and a hydroxide ion dependence which is intermediate between zero and first order. The reaction is not catalyzed by Pt(NH3)2+. 

The Cr(EtSXant)3 complex (jueff = 3.94 BM, room temp.) (504) should be an ideal candidate for a study of the nucleophilic substitution reactions on the coordinated EtSXant ligand. 

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