BINOL asymmetric catalysis

Over the last few years several examples have been reported in the field of asymmetric catalysis that are based on the interaction of two centers.6,119 Recently, Shibasaki and coworkers have developed an asymmetric two-center catalyst. Scheme 3.14 shows preparation of optically active La binaphthol (BINOL). This catalyst is effective in inducing the asymmetric nitro-aldol reaction, as shown in Scheme 3.15. 

The self-assembly of a chiral Ti catalyst can be achieved by using the achiral precursor Ti(OPr )4 and two different chiral diol components, (R)-BINOL and (R,R)-TADDOL, in a molar ratio of 1 1 1. The components of less basic (R)-BINOL and the relatively more basic (R,R)-TADDOL assemble with Ti(OPr )4 in a molar ratio of 1 1 1, yielding chiral titanium catalyst 118 in the reaction system. In the asymmetric catalysis of the carbonyl-ene reaction, 118 is not only the most enantioselective catalyst but also the most stable and the exclusively formed species in the reaction system. 

Takaya and co-workers in 1993 were the first to report on asymmetric hydroformylation using phosphite-phosphine ligands [59]. In an attempt to combine the effectiveness of the BINOL chemistry for asymmetric catalysis and the effectiveness of the phosphite moiety for asymmetric hydroformylation, they developed the (.R,S)-BINAPHOS ligand 3, which turned out to be very efficient (Fig. 6). 

Keywords Asymmetric catalysis BINOL Dicarboxylic acids A-Triflyl phosphoramides Phosphoric acids Strong chiral Brpnsted acids... 

The last few years have witnessed major advances in the use of small organic molecules as organic acid catalysts in asymmetric catalysis [1], Selected examples of such organic acid catalysts include urea and thiourea [2], TADDOL [3], BINOL [4], and phosphoric acid derived from BINOL [5] (Figure 2.1). 

Yamamoto et al. have reported the asymmetric catalysis of a chiral Lewis acid in a carbonyl-ene reaction, which uses chloral as the enophile and an aluminum catalyst with enantiopure 3,3 -bissilylated binaphthol (BINOL) to give the corresponding homoallylic alcohol with 78% ee in 79% yield (Scheme 8C.2) [6]. It should be noted that 3,3 -diphenyl-BINOL-derived aluminum catalyst provides the racemic product in low yield. 

BINOL-Ti catalysis is also applicable to carbonyl-ene reaction with formaldehyde or vinylogous and alkynylogous analogs of glyoxylates in the catalytic desymmetrization (vide infra) approach to the asymmetric synthesis of isocarbacycline analogs (Scheme 8C.7) [24],... 

Asymmetric catalysis of BINOL-Ti complexes in the reaction of aliphatic and aromatic aldehydes with an allylstannane has also been reported independently by Umani-Ronchi [54] and Keck [55]. The former group has suggested that a new complex generated by the reaction of the BINOL-Ti complex with allylstannane is the catalytic species that provides remarkably high enantioselectivity (Scheme 8C.23). It is interesting that no reaction occurs if dry MS 4A... 

BINOL and its derivatives have been utilized as versatile chiral sources for asymmetric catalysis, and efficient catalysts for their syntheses are, ultimately, required in many chemical fields [39-42]. The oxidative coupling of 2-naphthols is a direct synthesis of BINOL derivatives [43, 44], and some transition metals such as copper [45, 46], iron [46, 47] and manganese [48] are known as active metals for the reaction. However, few studies on homogeneous metal complexes have been reported for the asymmetric coupling of 2-naphthols [49-56]. The chiral self-dimerized V dimers on Si02 is the first heterogeneous catalyst for the asymmetric oxidative coupling of 2-naphthol. 

Asymmetric Catalysis for Oxidative Coupling of2-Naphthol to BINOL... 

BINOL-phosphates as efficient Brpnsted acid catalysts in the enantios-elective Strecker reaction shows that C-nucleophiles can be applied in the chiral ion-pair catalysis procedure. This, in turn, not only increases the diversity of possible transformations of this catalyst but also shows the great potential chiral Brpnsted acids in asymmetric catalysis. 

In this study of catalyst optimization with achiral and meso ligands, a single chiral ligand, (5 )-Ph2-BINOL, was employed and led to enantioselectivities between 96% R) and 76% This study definitively demonstrates that asymmetric catalysts can be optimized by screening achiral and meso ligands. This approach can be adapted to other asymmetric catalysts and holds great promise in asymmetric catalysis. 

Carbonyl-Ene Reaction. BINOL-TiX2 reagent exhibits a remarkable level of asymmetric catalysis in the carbonyl-ene reaction of prochiral glyoxylates, thereby providing practical access to a-hydroxy esters. These reactions exhibit a remarkable positive nonlinear effect (asymmetric amplification) that is of practical and mechanistic importance (eq 19). The desymmetrization of prochiral ene substrates with planar symmetry by the enantiofacial selective carbonyl-ene reaction provides an efficient solution to remote internal asymmetric induction (eq 20). The kinetic resolution of a racemic allylic ether by the glyoxylate-ene reaction also provides efficient access to remote but relative asymmetric induction (eq 21). Both the dibromide and dichloride catalysts provide the (2R,5S)-syn product with 97% diastereoselectivity and >95% ee. 

Ene Cyclization, " The asymmetric catalysis of the intramolecular carbonyl-ene reaction not only of type (3,4) but also (2,4) employs the BINOL-derived titanium complexes [(I )-BINOL-TiX2 X = C104 or OTf], modified by the perchlorate and trifluoromethanesulfonate ligands. The tmns-... 

Cyanosilylation. Another preparative procedure of BINOL-TiCl2 and the use thereof was reported in the asymmetric catalysis of the addition reaction of cyanotrimethylsilane to aldehydes. The dilithium salt of BINOL in ether was treated with... 

In our research on the asymmetric catalysis of the carbonyl-ene reaction, we found that the BINOL-Ti complexes (1) [30], prepared in situ, in the presence of 4-A molecular sieves, from diisopropoxytitanium dihalides (X2Ti(OPr )2 X = Br [31] or Cl [32]) and optically pure BiSfOL (vide infra), catalyze [33], rather than promote stoichiome-trically, the carbonyl addition reaction of allylic silanes and stannanes [34]. The addition to glyoxylate of ( )-2-butenylsilane and -stannane proceed smoothly to afford the syn product in high enantiomeric excess (Sch. 5). The s yn-product thus obtained could be readily converted to the iaetone portion of verrucaline A [35]. 

Asymmetric catalysis of ene reactions was initially investigated for the intramolecular examples, because intramolecular versions are much more facile than their inter-molecular counterparts. The first reported example of an enantioselective 6-(3,4) car-bonyl-ene cyclization employed a BINOL-derived zinc reagent [81]. This, however, was successful only when excess zinc reagent (at least 3 equiv.) was used. An enantioselective 6-(3,4) olefin-ene cyclization has also been developed which uses a stoichiometric amount of a TADDOL-derived chiral titanimn complex (Sch. 26) [82]. In this ene reaction, a hetero Diels-Alder product was also obtained, the periselectivity depending critically on the solvent system employed. In both cases, geminal disubstitution is required of high ee are to be obtained. Neither reaction, however, constitutes an example of a truly catalytic asymmetric ene cyclization. 

We reported the first examples of asymmetric catalysis of intramolecular carbonyl-ene reactions of types (3,4) and (2,4) using the BINOL-derived titanium complex (1) [80,83]. The catalytic 7-(2,4) carbonyl-ene cyclization gives the oxepane with high ee, and gem-dimethyl groups are not required (Sch. 27). In a similar catalytic 6-(3,4) ene cyclization, the fram-tetrahydropyran is preferentially produced, with high ee (Sch. 28). The sense of asymmetric induction is exactly the same as observed for the glyoxylate-ene reaction—the (f )-BINOL-Ti catalyst provides the (R)-cyclic alcohol. 

Keck also investigated asymmetric catalysis with a BINOL-derived titanium complex [102,103] for the Mukaiyama aldol reaction. The reaction of a-benzyloxyalde-hyde with Danishefsky s dienes as functionalized silyl enol ethers gave aldol products instead of hetero Diels-Alder cycloadducts (Sch. 40) [103], The aldol product can be transformed into hetero Diels-Alder type adducts by acid-catalyzed cyclization. The catalyst was prepared from BINOL and Ti(OPr )4, in 1 1 or 2 1 stoichiometry, and oven-dried MS 4A, in ether under reflux. They reported the catalyst to be of BINOL-Ti(OPr% structure. 

The Lewis acid-catalyzed conjugate addition of silyl enol ethers to a,y3-unsaturated carbonyl derivatives, the Mukaiyaraa Michael reaction, is known to be a mild, versatile method for carbon-cabon bond formation. Although the development of catalytic asymmetric variants of this process provides access to optically active 1,5-dicarbonyl synthons, few such applications have yet been reported [108], Mukiyama demonstrated asymmetric catalysis with BINOL-Ti oxide prepared from (/-Pr0)2Ti=0 and BINOL and obtained a 1,4-adduct in high % ee (Sch. 43) [109]. The enantioselectiv-ity was highly dependent on the ester substituent of the silyl enol ether employed. Thus the reaction of cyclopentenone with the sterically hindered silyl enol ether derived from 5-diphenylmethyl ethanethioate proceeds highly enantioselectively. Sco-lastico also reported that reactions promoted by TADDOL-derived titanium complexes gave the syn product exclusively, although with only moderate enantioselectiv-ity (Sch. 44) [110]. 

As shown above, asymmetric catalysis of Diels-Alder reactions has been achieved by use of chiral titanium complexes bearing chiral diol ligands. Yamamoto has reported a chiral helical titanium complex derived from Ti(OPr )4 and a BINOL-derived tetraol ligand (Sch. 54) [134], The Diels-Alder products are obtained with uniformly high enantioselectivity, irrespective of the substituent pattern of a,/3-unsaturated aldehydes. Corey has also reported a new type of chiral titanium complex derived from an amino alcohol ligand (Sch. 55) [135]. The chiral titanium complex serves as an efficient asymmetric catalyst for the reaction of 2-bromoacrolein the Diels-Alder product is obtained with high enantioselectivity. 

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