Binaphthols, -Binaphthyl

Just as selective oxidation can be carried out on these systems, reduction also occurs with considerable selectively. Hydrogenation of binaphthol (Pd catalyst) in glacial acetic acid at room temperature for seven days affords the octahydro (bis-tetrahydro) derivative in 92% yield with no apparent loss of optical activity when the reaction is conducted on optically pure material. The binaphthol may then be converted into the bis-binaphthyl crown in the usual fashion. 

The principal variations on the normal crown synthesis methods were applied in preparing mixed crowns such as those shown in Eq. (3.55) and in forming isomers of the dibinaphthyl-22-crown-6 systems. The latter has been discussed in Sect. 3.5 (see Eq. 3.21) . The binaphthyl unit was prepared to receive a non-naphthyl unit as shown in Eq. (3.57). Binaphthol was allowed to react with the tetrahydropyranyl ether or 2-chloroethoxyethanol. Cleavage of the THP protecting group followed by tosyla-tion of the free hydroxyl afforded a two-armed binaphthyl unit which could serve as an electrophile in the cyclization with catechol. Obviously, the reaction could be accomplished in the opposite direction, beginning with catechol". ... 

Pu and co-workers incorporated atropisomeric binaphthols in polymer matrixes constituted of binaphthyl units, the macromolecular chiral ligands obtained being successfully used in numerous enantioselective metal-catalyzed reactions,97-99 such as asymmetric addition of dialkylzinc reagents to aldehydes.99 Recently, they also synthesized a stereoregular polymeric BINAP ligand by a Suzuki coupling of the (R)-BINAP oxide, followed by a reduction with trichlorosilane (Figure 10).100... 

An optically active polymethacrylate (2) having a binaphthol moiety in the side chain was synthesized by radical polymerization. This polymer coated on silica gel resolved several racemates.50 However, no data on the influence of the stereoregularity of the main chain on resolution have been reported. The chiral recognition by this polymer may simply arise from the binaphthyl group. 

Chiral 1,1 -binaphthol derivatives are well established as readily available chiral catalysts and auxiliaries for the production of various useful optically active compounds. Tanabe et al. investigated [11] a crystalline-liquid resolution of (1R) -// . v - c h rysanthemic acid utilizing l,l -binaphthyl monoethyl ether (25) (Scheme 3). 

The monobenzhydiyl derivative of (S)-binaphthol has played an important role, not only in the synthesis of chiral bisbinaphthyl crown ether derivatives, for example, (55)-124, containing two different bridges between the two binaphthyl units, but also in the provision of an entry into the constimtionally isomeric derivative (5S)-125. Rational stepwise syntheses of macrocyles containing three binaphthyl units have been devised and applied to the synthesis of (SSS)-126 and (RSS)-127. Cleariy, in all these procedures, the C2 symmetry of the chiral building block restricts the number of products (to one ) and defines the symmetries of the macrocycles formed. 

This compound, in common with other suitable substituted biphenyls, possesses a chiral axis (p. 6) and is isolated from the reaction as a racemate. Although several resolution procedures have been reported, the superior method to date4 is that in which the binaphthol is first converted by treatment with phosphorus oxychloride into the binaphthyl phosphoric acid (14). Resolution is then effected by formation of diastereoisomeric salts with (+ )-cinchonine, appropriate fractional crystallisation and recovery of the (S)-( + )-binaphthyl phosphoric acid. Suitable hydrolysis gives (S)-( — )-l,l -bi-2-naphthol (15). 

The quantum yields decreases by changing from planar naphtholes to the perpendicular binaphthole independent on the absence or presence of pyridine [162], Also, in the case of optical active l,T-binaphthyl-2,2 -diamine (BNA) compared with A-phenyl-p-naphthylamine (PNA), the quantum yield of electron transfer is for BNA by a factor of 0.5 lower due to the perpendicular structure [161]. A possible explanation is that the approach of the perpendicular donors BN(OH)2 and BNA to the almost spherical fullerenes is hindered, while the planar 2-NOH and PNA more easily contact with the fullerenes [161,162], The quantum yields of C70 in the absence of pyridine are slightly higher than those of C6o suggesting a slightly stronger acceptor ability of C70 [162],... 

Stereoselective synthesis of perylenequinones. Synthesis of the symmetrical perylenequinone phleichrome (4) has been effected by coupling of two identical naphthalene units to provide a binaphthol, which is then oxidized to a perylenequinone. Thus the bromonaphthalene 1 on halo-lithium exchange (f-BuLi) followed by reaction of anhydrous FeCl3 dimerizes to two optically active binaphthyls, (+)-and (— )-2, with 3 1 diastereoselectivity. 

In the synthesis of the swivel-cruciform binaphthyl-based oligomers 27 and 28, bromination of commercially available l,l -binaphthol followed by a Williamson reaction gives binaphthyl ethers with various alkoxy groups [43], The dibromi-... 

For example, the synthesis of racemic binaphthyl moieties using iron reagents has been greatly improved from the initial Pummerer report [54]. Bjornholm and co-workers presented a way of preparing binaphthol on a large scale in a minimal amount of solvent (THF) (Scheme 16) [55]. 

Phenol coupling occurs chemically under oxidation with Fe(III). The most famous example is the coupling of 2-naphthol to give binaphthol—an ortho ortho coupling. The stereochemistry of binaphthyls like this was discussed in Chapter 45. 

The most frequently applied ligands are 2,2 -binaphthol (BINOL la) and 2,2 -bis(diphenyl-phosphino)binaphthyl (BINAP lb). Both antipodes of these compounds are commercially available in enantiopure form, though not at little cost [3]. It is rewarding, therefore, to become acquainted with the syntheses of these compounds, which have been described in detail [4J and have been simplified substantially on the basis of recent publications [5J. The iron(lIl)-catalyzed dimerization of 2-naphthol (2) to give racemic BINOL (rac)-la succeeds smoothly and on a large scale (Scheme 1). Its resolution can be achieved easily with N-benzylcinchoidinium chloride (3) and yields both (/ )- and (5 )-la in high enantiomeric excesses. After conversion into the ditri-flate 4, enantiopure la can be coupled with diphe-nylphosphine (or, in lower yield, with cheaper chlorodiphenylphosphine) in a nickel-catalyzed... 

Optically active l,l -binaphthols are among the most important chiral ligands of a variety of metal species. Binaphthol-aluminum complexes have been used as chiral Lewis acid catalysts. The l,T-binaphthyl-based chiral ligands owe their success in a variety of asymmetric reactions to the chiral cavity they create around the metal center [107,108]. In contrast with the wide use of these binaphthyls, the polymer-supported variety has been less popular. The optically active and sterically regular poly(l,l -bi-naphthyls) 96 have been prepared by nickel-catalyzed dehalogenating polycondensation of dibromide monomer 95 (Sch. 7) [109] and used to prepare the polybinaphthyl aluminum(III) catalyst 97 this had much greater catalytic activity than the corresponding monomeric catalyst when used in the Mukaiyama aldol reaction (Eq. 29). Unfortunately no enantioselectivity was observed in the aldol reaction. 

Reduction of (S)-(+)- and (R)-(-)-BNP methyl esters or acids by lithium aluminum hydride, or by Red-Al (this volume, p. 13) yields (S)- -)-and (R)-(+)-binaphthol, respectively. This is, at present, the most convenient access to optically active binaphthols, used by Cram and co-workers to prepare macrocyclic polyethers and by Japanese authors in asymmetric synthesis of cyclic binaphthyl-esters. 

The classical Ullmann reaction has also attracted renewed interest in recent years. Miyano has prepared optically enriched binaphthyl derivatives by intramolecular biaryl coupling, as shown in equation (9). " Diastereoselectivities of up to 70% have been obtained with a binaphthol chiral auxiliary in the linking chain. Intermolecular cross-coupling is best accomplished with preformed arylcopper compounds. "... 

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