Amides Bidentate ligands

Following the general trend of this account, monodentate phosphinous amide ligands and bidentate AT-phosphino phosphinous amides or bis(amino-phosphanes) are included in the following discussion, but not other bidentate ligands bearing additional, different phosphorus functionalities, as for instance phosphinous amide-phosphane bidentate ligands. 

Phosphinous amides, based on proline and tetrahydroisoquinoline carboxylic acid, bearing a second donor center (50, Ar=Ph R =H, CH3,Tr, Ph R =H, CH3,Tr, Ph and 51, R =H,Tr R =H,Tr) (Scheme 40) have been developed for use in allylic alkylation and amination of substituted propenyl acetates, yielding the corresponding products in 87-98% (5-94% ee) and 29-97% (14-93% ee) respectively [55, 167]. With bidentate ligands of type 38 where R=(S)-PhMeCH, and with the bis(aminophosphanes) 52 (R=Ph) similar allylic alkylations have been also tested [168,169]. 

It has been found that a number of bidentate ligands greatly expand the scope of copper catalysis. Copper(I) iodide used in conjunction with a chelating diamine is a good catalyst for amidation of aryl bromides. Of several diamines that were examined, rra s-yV,yV -dimethylcyclohexane-l,2-diamine was among the best. These conditions are applicable to aryl bromides and iodides with either ERG or EWG substituents, as well as to relatively hindered halides. The nucleophiles that are reactive under these conditions include acyclic and cyclic amides.149... 

Bidentate ligand systems are also known with selenium and nitrogen donors. For example, Se/N bidentate phosphinochalcogenoic ligand and zinc amides react to form a distorted tetrahedral complex with two di-t-butylphosphinoselenoic isopropylamidate ligands.590... 

Amides of phosphorous acid (e.g., P(NMe2)3 and the bicyclic compound (L16)) are useful ligands for cross-coupling of arylboronic acids with aryl bromides and chlorides (system Pd(OAc)2/2L, Cs2C03, toluene, 80 °C), the bicyclic amide being markedly more effective than simple acyclic ones.421 Amides of phosphinous acids are also excellent bidentate ligands with PN coordination mode ((L6), Section 9.6.3.4.2). 

In contrast, the mono-anionic bidentate ligand bis(diphenyl-thiophosphoryl)amide Na(dtp)... 

Cationic transition metal amide complexes have been investigated in part because of their potential in catalysis p irticularly for olefin polymerization. Much of this work has concerned polydentate amido, linked cyclopentadienyl-amido or delocalized nitrogen centred bidentate ligands (see later). However, the structures of a small number of cationic complexes containing monodentate amido ligands have been determined. These include... 

Higher metal coordination numbers are also observed in the distorted square pyramidal indium(lll) amides [MeIn N(Me)(2-py) 2]2 ° and [MeIn 2-(N(CH2Ph)aj de(2-py) 2] in which the bidentate ligands occupy equatorial positions (mean In—N bond lengths are... 

The major structural types found for lithium amide complexes in the solid state are illustrated in Fig. 34. These comprise ladders of limited extent when the L Li ratio is less than 1 1 (Fig. 34a), dimeric (NLi)2 rings, when this ratio is 1 1 and, usually, when the complexants are monodentate (Fig. 34b), and monomers, both contact-ion pairs (CIPs) and solvent-separated ion pairs (SSIPs) (Fig. 34c). Monomers occur always when there are two or more monodentate complexants per Li. This also is usual with bidentate ligands, and is always found when the ligands have higher denticity. 

Many more recent stoichiometric studies of cobalt(III) complexes have been responsible for most of the developments in this area of research. Cobalt(III) ammine complexes effect hydrolysis of ethyl glycinate in basic conditions via intramolecular attack of a coordinated amide ion hydrolysis by external hydroxide ion attack also occurs (equation 74).341 Replacement of ammonia ligands by a quadridentate or two bidentate ligands allows the formation of aquo-hydroxo complexes and enables intramolecular hydroxide ion attack on a coordinated amino ester, amino amide... 

Members of a second prominent group of mechanism-based inhibitors contain a peptide isostere, an element mimicking an intermediate formed during amide bond cleavage. Inhibitors of metalloproteases often contain a metal-chelating unit such as hydroxamate or phosphonic acids, which act as a bidentate ligand. 

Since Asami7 presented his seminal ligand (4) in 1984 based on a diamine, most of the ligands developed and used as chiral lithium amides have been based on bidentate ligands. Malhotra s results clearly show that monodentate bases can also be used for highly selective deprotonations. 

Presumably, the use of a bidentate ligand such as ( )-BINAP or DPPF results in the occupation of a vacant coordination site, preventing -hydride elimination of the Pd (II) amide intermediate [53]. Dissociation of the imine and C-H bond reductive elimination results in formation of the reduced aryl bromide. If this -hydride elimination is rapid relative to reductive elimination and reversible, then significant erosion of the enantiomeric excess of optically active a-substituted amines maybe observed during the reaction (Scheme 3). 

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