Dihydrogen insertion

Acidic salts contain anions derived from ternary polyprotic acids in which one or more acidic hydrogen atoms remain. These salts are named as if they were the usual type of ternary salt, with the word hydrogen or dihydrogen inserted after the name of the cation to show the number of acidic hydrogen atoms. 

E) Sigma-bond metathesis. Dihydrogen is observed to react with transition-metal-alkyl bonds even when the metal lacks lone pairs. In this case the reaction cannot be explained in terms of the oxidative-addition or reductive-elimination motif. Instead, we can view this reaction as a special type of insertion reaction whereby the ctmr bond pair takes the donor role of the metal lone pair and donates into the cthh antibond. When the M—R bonds are highly polarized as M+R, the process could also be described as a concerted electrophilic H2 activation in which R acts as the base accepting H+. 

A ruthenium dihydrogen complex G or a ruthenacycle D, which was proposed as a potential intermediate, catalyzed the insertion of ethylene into sp2-C-H bonds, with TONs reaching 19 after 48 h of reaction and under very mild conditions (room temperature as opposed to the usual 135 °C) (Equation (96)).91,91a91c... 

Extensive computational calculations have been performed by using molecular mechanics (MM) [79], quantum mechanics (QM) [80], or combined MM/QM methods [81]. As major contributions, these theoretical studies predict the greater stability of the major isomer, explain the higher reactivity of the minor diastereomer, introduce the formation of a dihydrogen adduct as intermediate in the oxidative addition of H2 to the catalyst-substrate complexes, and propose the migratory insertion, instead of the oxidative addition, as a turnover-limiting step. 

The mechanism is dominated by the remarkable stability of the Fe( 72-H2) bond, which is one of the most stable 72-H2 complexes reported in the literature [8, 10]. Remarkably, the free coordination site for the incoming alkyne is provided by the reversible dissociation of one of the phosphine moieties of the PP3 ligand rather than dissociation of the dihydrogen ligand (see Scheme 14.1). The coordinated alkyne subsequently inserts into the Fe-H bond and the emerging Fe-vinyl bond is... 

The first step consists of the substitution of one of the ligands (L) of 18 by dioxane (39) in an oxidative addition (a) (Scheme 20.16). / -Elimination of 40 releases 2,3-dihydro-dioxine (41) and the 16-electron dihydrogen rhodium complex (42) (b). Alkene 43 coordinates to the vacant site of 42 (c) to give complex 44. A hydride insertion then takes place (d), affording complex 45. After a reductive elimination (e) of the product 46, the coordination of a ligand reconstitutes the Wilkinson-type catalyst (18). 

The accepted mechanism for hydrogenation of alkenes by Wilkinson s catalyst involves the addition of dihydrogen prior to coordination of the alkene, followed by migratory insertion [31]. The new demonstrations of the existence of solvate dihydride complexes inevitably raise the question as to whether the same mechanism can apply in rhodium enantioselective hydrogenation. The evidence in support of this possibility is analyzed in more detail later. 

As briefly discussed in section 1.1, and shown in Figure 1, the accepted mechanism for the catalytic cycle of hydrogenation of C02 to formic add starts with the insertion of C02 into a metal-hydride bond. Then, there are two possible continuations. The first possibility is the reductive elimination of formic acid followed by the oxidative addition of dihydrogen molecule to the metal center. The second possible path goes through the a-bond metathesis of a metal formate complex with a dihydrogen molecule. In this section, we will review theoretical investigations on each of these elementary processes, with the exception of oxidative addition of H2 to the metal center, which has already been discussed in many reviews. 

Based on DFT calculations Brandt et al. proposed a catalytic cycle via Ir(III) and Ir(V) intermediates, in which an additional dihydrogen molecule coordinated to an Ir-dihydride undergoes oxidative addition during migratory insertion [31]. However, since an extremely truncated model for the ligand and substrate (ethylene) was used which neglected the severe steric interactions present in the actual catalysts it... 

Other, the dihydrogen bond is already broken and the unsaturated bond is weakened. Next, the unsaturated bond inserts into one of the Rh-H bonds and thus the first hydrogen is transferred to the product molecule. Transfer of the second hydrogen leads to reductive elimination of the product molecule and the catalyst is ready for the next cycle. 

Sander applied DFT (B3LYP) theory to carbenic philicity, computing the electron affinities (EA) and ionization potentials (IP) of the carbenes." " The EA tracks the carbene s electrophilicity (its ability to accept electron density), whereas the IP represents the carbene s nucleophilicity (its ability to donate electron density). This approach parallels the differential orbital energy treatment. Both EA and IP can be calculated for any carbene, so Sander was able to analyze the reactivity of super electrophilic carbenes such as difluorovinylidene (9)" which is sufficiently electrophilic to insert into the C—H bond of methane. It even reacts with the H—H bond of dihydrogen at temperamres as low as 40 K, Scheme 7.2) ... 

Some of the silylene-like reactions which take place at the silylene centers are displayed in Scheme 12. The divalent silicon inserts into the H—H bond of dihydrogen, the S—H and O-H bonds of H2S and H20, and the C-S bond of Me2S348. 

Metal(II) species, homobimetallic complexes - During a rhodium insertion into H2(TPP) using [Rh(CO)2Cl]2 in HOAc/NaOAc, a paramagnetic rhodium(II) porphyrin was observed [57] which could be transformed into a hydridorho-dium(III) porphyrin with dihydrogen (path — p) and subsequently into its corresponding base, the anion [Rh(TPP)], which may be likewise regarded as... 

Rh2(DPB). In contrast to the dimers [Rh(P)]2, this compound reacted with dihydrogen only after intermediate addition of CO to yield a hydride (RhH)2(DPB) with two Rh-H bonds probably located inside the cavity, An insertion of CO into the Rh-H bonds, as with RhH(P) (see Sect. 4.2), was not observed. The dihydride was able to be dehydrogenated with molecular oxygen to reform Rh2(DPB) the formation of a dioxygen adduct (p-peroxo derivative) of the dirhodium(II) species which might be expected according to Scheme 3 (paths — q, t, u) was not observed. 

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