Axially chiral phosphoric acid

Axially chiral phosphoric acid 3 was chosen as a potential catalyst due to its unique characteristics (Fig. 2). (1) The phosphorus atom and its optically active ligand form a seven-membered ring which prevents free rotation around the P-0 bond and therefore fixes the conformation of Brpnsted acid 3. This structural feature cannot be found in analogous carboxylic or sulfonic acids. (2) Phosphate 3 with the appropriate acid ity should activate potential substrates via protonation and hence increase their electrophilicity. Subsequent attack of a nucleophile and related processes could result in the formation of enantioenriched products via steren-chemical communication between the cationic protonated substrate and the chiral phosphate anion. (3) Since the phosphoryl oxygen atom of Brpnsted acid 3 provides an additional Lewis basic site, chiral BINOL phosphate 3 might act as bifunctional catalyst. 

Soon after these initial reports, the groups of Antilla [92] and You [93] indepen dently applied the chiral phosphoric acid catalysis to the enantioselective hydro genation of a imino esters. The method provides an alternative route to the enantioselective synthesis of a amino esters. Antilla and coworkers employed a new type of axially chiral phosphoric acid (9) derived from VAPOL originally developed by his research group (Scheme 3.42), whereas lg was used in You s case. In both cases, excellent enantioselectivities were achieved. You and coworkers further applied the method to the enantioselective reduction of a imino esters having an alkynyl substituent at the a position (Scheme 3.43) [94]. Both alkyne and imine moieties were reduced under transfer hydrogenation conditions with an excess amount of... 

In 2008, Du and coworkers designed and synthesized novel double axially chiral phosphoric acid catalysts based on BINOL [28]. Subsequently, these catalysts have been successfully applied in asymmetric transfer hydrogenation of 2 substitued (Table 10.8) and 2,3 disubstitued quinolines (Scheme 10.26). They found that ether was the best solvent. For 2 substitued quinolines, up to 98% ee was obtained when the substitutent of catalyst was cyclohexanyl. 

SCHEME 2.17 Axially chiral phosphoric acid catalysis of vinylogous Mannich reaction. 

In the presence of catalytic amounts of axially chiral phosphoric acids, achiral -binaphthyl hydrazines undergo a [3,3]-sigmatropic rearrangement to give enantiomerically enriched BINAM derivatives (Scheme A review of the Claisen rearrangement in natural product synthesis has appeared. Stereoselective total syntheses of Limazepine E and Barmumycin has been... 

A one-pot Michael and aza-Michael addition with concomitant ring closure has been achieved on addition of tryptamine (309) to 2 equiv of enones in the presence of the axially chiral phosphoric acid (18) as a Brpnsted catalyst. The resulting adducts (310) were obtained with <83%... 

The previously described double hydrogenation of quinolines to tetrahydroqui-nolines was also investigated with axially chiral phosphoric acid catalysts. 2-Substituted quinolines were readily reduced in high enantioselectivities using... 

An inverse electron demand aza D A reaction of electron rich alkenes with N aryl imines as 2 azadiene (Povarov reaction) provides tetrahydroquinolines. Reactions catalyzed by chiral phosphoric acids yielded different absolute ste reochemical outcomes when ethyl vinyl efher and enecarbamate are employed as electron rich alkenes, although chiral phosphoric acids have the same axial chirality in both cases (see Scheme 3.26). 

There is also one example in which a chiral phosphoric acid has been employed as catalyst in the reaction. In particular, the addition of several cyclic p-ketoesters to methyl vinyl ketone was found to occur smoothly in the presence of several chiral phosphoric acids (Scheme 4.35). As mentioned earlier, a key feature of the chiral phosphoric acid catalyst is the backbone binaphthyl axial chirality together with the incorporation of bulky substituents at the 2 positions. In this case, 60b was identified as an appropriate promoter of the reaction leading to the corresponding Michael adducts in excellent yields, although with moderate enantioselectivity. In addition, the authors succeeded in applying this reaction to a procedure to carry out a subsequent Robinson-type annulation. 

The alkaloids have also been used for the resolution of various phosphoric and carboxylic adds 4—10, including axially chiral compounds, such as biaryl derivatives 4, 5 and 7 [13], allenic acids 9, and planar chiral naphthalenophane carboxylic acids 10 (Figure 13.5). 

DFT has been employed to probe the mechanisms of chiral BINOL-phosphoric-acid-catalysed allylboration and propargylation reactions, with a particular focus on whether the catalyst interacts with the pseudo-axial or pseudo-equatorial oxygen of the boronate. °... 

Recently, chiral bis-phosphoric acid 77 bearing a new chiral scaffold with triple axial chirality assisted by intramolecular hydrogen-bonding between two phosphoric acid moieties was designed as a new chiral Bronsted acid catalyst by the Terada group [33], Application of this catalyst in the Diels-Alder reaction between substituted acroleins 66 and amido-dienes 76 produced the corresponding cycloadducts 78 with excellent enantioselectivities (Scheme 38.22). In comparison with the mono-phosphoric acid, bis-phosphoric acid 77 showed obviously higher catalytic activity and selectivity. 

However, soluble metal chiral complex catalysts are better, even though ketone hydrogenation under these conditions is more difficult to run than olefin hydrogenation. Notable achievements have been made using Rh and Ru metals. Phosphine ligands are often used, which contain either an asymmetric alkyl group have the phosphorous atom as the asymmetric center, or have an axial element of chirality (atropisomerism) . Other chiral ligands commonly used are derived from amino acids, from L-hydroxyproline and from ferrocene. 

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