Transition metal hydride deprotonation

One must always keep in mind that in aqueous solutions the transition metal hydride catalysts may participate in further (or side) reactions in addition to being involved in the main catalytic cycle. H and P NMR studies established that in acidic solutions [RhCl(TPPMS)3] gave cis-fac-and ci5-7 er-[RhClH2(TPPMS)3] [86,88], while in neutral and basic solutions these were transformed to [RhHX(TPPMS)3] (X = H2O or Cl ) [86]. Simultaneous pH-potentiometiic titrations revealed, that deprotonation of the dihydride becomes significant only above pH 7, so this reaction of the catalyst plays no important role in the pH effects depicted on Figs. 3.2.a and 3.2.b. 

In view of the acidity of hydride complexes, one might expect them to form hydrogen-bonded intennediates during proton-transfer reactions. However, it is relatively uncommon for neutral hydride complexes to form hydrogen bonds M-H A because most M-H bonds are polarized as M(8+)-H(8-), not as M(8-)-H(8+). (The need to reverse the observed polarization during deprotonation is a major cause of the low kinetic acidity of transition metal hydrides, mentioned previously.) The first M-H Ahydrogen bond from a neutral hydride has just been reported CpM(CO)3H (M = Mo and W) serves as a hydrogen bond donor to (octyl)3P=0 and even to pyridine, apparently because there is M(8-)-H(8+) polarization in its M-H bond. °... 

The cationic tantalum dihydride Cp2(CO)Ta(H)2]+ reacts at room temperature with acetone to generate the alcohol complex [Cp2(C0)Ta(H01Pr)]+, which was isolated and characterized [45]. The mechanism appears to involve protonation of the ketone by the dihydride, followed by hydride transfer from the neutral hydride. The OH of the coordinated alcohol in the cationic tantalum alcohol complex can be deprotonated to produce the tantalum alkoxide complex [Cp2(C0)Ta(01Pr)]. Attempts to make the reaction catalytic by carrying out the reaction under H2 at 60 °C were unsuccessful. The strong bond between oxygen and an early transition metal such as Ta appears to preclude catalytic reactivity in this example. 

Electron-rich olefins are nucleophilic and therefore subject to thermal cleavage by various electrophilic transition metal complexes. As the formation of tetraaminoethylenes, i.e., enetetramines, is possible by different methods, various precursors to imidazolidin-2-ylidene complexes are readily available. " Dimerization of nonstable NHCs such as imidazolidin-2-ylidenes is one of the routes used to obtain these electron-rich olefins [Eq. (29)]. The existence of an equilibrium between free NHC monomers and the olefinic dimer was proven only recently for benzimidazolin-2-ylidenes. In addition to the previously mentioned methods it is possible to deprotonate imidazolidinium salts with Grignard reagents in order to prepare tetraaminoethylenes. " The isolation of stable imidazolidin-2-ylidenes was achieved by deprotonation of the imidazolidinium salt with potassium hydride in THF. ... 

Once the hydroxy functionalised imidazolium salt is formed, it can be deprotonised and reacted with various metal complexes to form (transition) metal carbene complexes. The hydroxy group ensures that the ligand can be coordinated even to metals that are normally reluctant to form stable carbene complexes. A good example is the deprotonation of a hydroxyethyl functionalised imidazolium salt with potassium hydride [36]. The potassium cation coordinates to the oxygen atom of the alkoxide sidechain and forms cubes as structural elements (see Figure 4.6). The carbene end then coordinates to the respective... 

The products are versatile auxiliaries not only for enantioselective deprotonation and elimination (Section C.), but are also valuable chiral ligands for complex hydrides in the enantioselective reduction of ketones (Section D.1.4.5.)- They are also applied in enolate reactions (Section D.l.5.2.1., D.1.5.2.4.). transition-metal-catalyzed Michael additions (Section D.l.5.8.), 1,3-dipolar cycloadditions (Section D.l.6.1.2.1.), and additions ofGrignard reagents (Section D.l.3.1.4.2.5.). (5 )-2-(Phenylaminomethyl)pyrrolidine has found most application and is also commercially available. Several methods exist for the preparation of such compounds. Two typical procedures for the synthesis of (.S)-2-(l-pyrrolidinylmcthyl)pyrrolidine are presented here. The methodology can be readily extended to other amides and alkylamino derivatives of proline. 

Isolable transition metal complexes containing hydride and terminal oxo ligands are rare however, Tp Re( = 0)(H)X (X = Cl, H or OTf) and TpRe( = 0)(H)Cl have been synthesized, isolated and characterized. Reactions of Tp Re( = 0)(H) OTf (12) with unsaturated substrates (e.g., ethene, propene or acetaldehyde) result in insertion of C = C or C = 0 bonds into the Re-H bond to yield Tp Re( = 0)(R) (OTf) (R = ethyl or propyl) or Tp Re( = 0)(0Et)(0Tf) (Scheme 6). Oxidation of 12 with pyridine-iV-oxide or DMSO produces Tp Re( = 0)3, acid and free pyridine or dimethylsulfide, respectively. A likely mechanism involves initial oxidation of 12 to produce [Tp Re( = 0)2H][0Tf] (13) followed by the formation of Tp Re( = 0) (OH)(OTf) (14) via a 1,2-migration of the hydride to an oxo ligand (Scheme 6). Reaction of 14 with a second equivalent of oxidant in the presence of base yields Tp Re( = 0)3 (15). Direct deprotonation of 13 is noted as less likely than the pathway shown in Scheme 6 due to the lack of precedent for acidity of related rhenium hydride systems. 

The transition metals can be reduced in basic aqueous solutions via other mechanism. For example, the metal carbonyls could be attacked by the hydroxide ions and the metal reduced to metal hydride species by the elimination of carbon dioxide to yield a hydride, which could then be deprotonated with the excess of hydroxide ions (Figure 17). The reduction of the metal complexes by CO in aqueous phase is indeed a very important step in the Reppe-type catalysis and water-gas shift reactions. 

Route I (oxidative addition) involves a concerted oxidative addition process with the formation of metal-hydride species A. Alternatively, an electrophilic attack by the metal center on the aryl ip o-carbon may afford a metal arenium (Wheland) complex B followed by proton loss. In the agostic C-H bond activation route, the six-membered transition state C including a hydrogen-metal interaction has been found to initiate the C-H activation process, leading to an agostic intermediate D and acting simultaneously as an intramolecular base for deprotonation. 

The HAT reactions of transition metal complexes described here all involve redox change at the metal coupled to proton transfer to/from a ligand (eqn (1.16)). One example is shown in equation (1.17), in which oxidation of an Os(iii) center is coupled to deprotonation of an aniline to an anilide ligand. There is also an extensive literature of HAT reactions of metal-hydride species, L M-H, which in some ways more closely resemble organic HAT reactions. ... 

The title compound is commonly used as a base in transition metal-catalyzed reactions. Because these reactions involve multiple elementary steps, KOAc may act as a base in many different ways, and the precise mechanism of deprotonation may not always be known. A study on the influence of base on the palladium-black-catalyzed methoxycarbonylation of aryl iodides identified potassium acetate as a suitable base. This method has been widely adopted, and both sodium and potassium acetate are commonly used (e.g., eq 29). Alternatively, the acetate base may directly remove a proton from a metal center. For example, the Heck reaction (e.g., eq 30) generates a palladium(II) complex that bears hydride and halide ligands, and generation of the catalytically active palladium(0) corr5>lex requires deprotonation with stoichiometric base (eq 31). 

Amine activatitMi pathway has been well studied in catalysis by lanthanides, early transition metals, and alkali metals. In metal amide chemistry of late transition metals, there are mainly two pathways to synthesize metal amide complexes applicable under hydroamination conditions [54], One is oxidative addition of amines to produce a metal amide species bearing hydride (Scheme 8a). The other gives a metal amide species by deprotonation of an amine metal intermediate derived from the coordination of amines to metal center, and it often occurs as ammonium salt elimination by the second amine molecule (Scheme 8b). Although the latter type of amido metal species is rather limited in hydroamination by late transition metals, it is often proposed in the mechanism of palladium-catalyzed oxidative amination reaction, which terminates the catalytic cycle by p-hydride elimination [26]. Hydroamination through aminometallation with metal amide species demands at least two coordination sites on metal, one for amine coordination and another for C-C multiple bond coordination. Accordingly, there is a marked difference between the hydroamination via C-C multiple bond activation, which demands one coordination site on metal, and via amine activation. 

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