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Chiral BINOL

Yamamoto et al. were probably the first to report that chiral aluminum(III) catalysts are effective in the cycloaddition reactions of aldehydes [11]. The use of chiral BINOL-AlMe complexes (R)-S was found to be highly effective in the cycloaddition reaction of a variety of aldehydes with activated Danishefsky-type dienes. The reaction of benzaldehyde la with Danishefsky s diene 2a and traws-l-methoxy-2-methyl-3-(trimethylsilyloxy)-l,3-pentadiene 2b affords cis dihydropyrones, cis-3, as the major product in high yield with up to 97% ee (Scheme 4.6). The choice of the bulky triarylsilyl moiety in catalyst (J )-8b is crucial for high yield and the en-antioselectivity of the reaction in contrast with this the catalysts derived from AlMe3 and (J )-3,3 -disubstituted binaphthol (substituent = H, Me, Ph) were effective in stoichiometric amounts only and were less satisfactory with regard to reactivity and enantioselectivity. [Pg.156]

The adduct derived from (a-benzyloxyacetaldehyde (97 % ee) is an important intermediate en route to compactin and mevinolin [76]. In contrast, modest enantioselectivity was attained when the cycloadditions were catalyzed by a chiral BINOL-ytterbium-derived catalyst [77]. Pyridines were used as additives, and the best enantioselection (93% ee) was attained only in the case of p-methoxybenzaldehyde using 2,6-lutidine. [Pg.123]

Colloredo-Melz, S. Dorr, R. T. Verga, D. Freccero, M. Photogenerated quinone methides as useful intermediates in the synthesis of chiral BINOL ligands. J. Org. Chem. 2006, 71, 3889-3895. [Pg.328]

Preparation of diethyl (S)-a-hydroxybenzylphosphonate — Reaction of an aldehyde with a dialkyl phosphite facilitated by a chiral BINOL complex... [Pg.9]

Although disubstituted alkynes are used successfully as two-carbon components in chromium-mediated and -catalyzed [6 + 2]-reactions, the use of terminal alkynes produces a [6 + 2 + 2]-reaction (Section 10.13.3.7). Buono and co-workers have discovered that when a cobalt catalyst is employed, several monosubstituted alkynes can be used in [6 + 2]-cycloadditions with cycloheptatriene (Scheme 35). The use of a chiral BINOL-phosphoramidite cobalt complex affords an enantioselective [6 + 2]-cycloaddition reaction (Equation (18)).121... [Pg.622]

In recent years, there is no doubt that BINOL is one of the most extensively studied motifs. Incorporating a chiral binol unit into the chiral or achiral backbone constitutes a straightforward way in which to generate new chiral ligands [109]. [Pg.978]

Concurrent with studies on cyclometalation, studies on the effects of the structure of phosphoramidite ligand had been conducted. Several groups studied the effect of the stmcmre of ligand on the rate and selectivity of these iridium-catalyzed allylic substitutions. LI contains three separate chiral components - the two phenethyl moieties on the amine as well as the axially chiral BINOL backbone. These portions of the catalyst structure can control reaction rates by affecting the rate of cyclometalation, by inhibiting catalyst decomposition, or by forming a complex that reacts faster in the mmover-limiting step(s) of the catalytic cycle. [Pg.185]

While this manuscript was under preparation, a considerable number of examples of sohd-phase-attached catalysts appeared in the literature which is a clear indication for the dynamic character of this field. These include catalysts based on palladium [131, 132], nickel [133] and rhodium [134] as well applications in hydrogenations including transfer hydrogenations [135, 136] and oxidations [137]. In addition various articles have appeared that are dedicated to immobilized chiral h-gands for asymmetric synthesis such as chiral binol [138], salen [139], and bisoxa-zoline [140] cinchona alkaloid derived [141] complexes. [Pg.234]

Enantiomerically pure 3-amino alcohols which are important intermediates for many bioactive compounds can be directly synthesized by the ARO reaction of readily accessible racemic and meso epoxides with appropriate amines. Indeed, some simple and multifunctional p-amino alcohols have been obtained using this strategy by the promotion of chiral BINOL [30-32,88,89], salen [35,52], bipyridine [33,40,90-94] and proline-A,JV-dioxide based metal complexes [95]. However, none of these systems demonstrated the recyclability of the precious chiral catalyst. [Pg.330]

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. [Pg.399]

Three years later, the same group showed that oxygen-containing nucleophiles can also be used (Scheme 35) [58], IV-Benzoylated aldimines 32 were treated with alcohols 92 in the presence of chiral BINOL phosphate R)-3m (5 mol%, R = 9-anthryl) to provide iV,0-aminals 93 in high yields (62-99%) and good enantiose-lectivities (65-95% ee). [Pg.424]

In 2006, Akiyama and coworkers established an asymmetric Brpnsted acid-catalyzed aza-Diels-Alder reaction (Scheme 36) [59]. Chiral BINOL phosphate (R)-3o (5 mol%, R = 2,4,6- Pr3-CgH2) bearing 2,4,6-triisopropylphenyl groups mediated the cycloaddition of aldimines 94 derived from 2-amino-4-methylphenol with Danishefsky s diene 95 in the presence of 1.2 equivalents of acetic acid. Piperidinones 96 were obtained in good yields (72 to >99%) and enantioselectivi-ties (76-91% ee). While the addition of acetic acid (pK= 4.8) improved both the reactivity and the selectivity, the use of benzenesulfonic acid (pK= -6.5) as an additive increased the yield, but decreased the enantioselectivity. A strong achiral Brpnsted acid apparently competes with chiral phosphoric acid 3o for the activation of imine 94 and catalyzes a nonasymmetric hetero-Diels-Alder reaction. The role of acetic acid remains unclear. [Pg.424]

The same group expanded the scope of the aza-Diels-Alder reaction of electron-rich dienes to Brassard s diene 97 (Scheme 37) [60]. In contrast to Danishefsky s diene, it is more reactive, but less stable. Akiyama et al. found chiral BINOL phosphate (R)-3m (3 mol%, R = 9-anthryl) with 9-anthryl substituents to promote the [4 + 2] cycloaddition of A-arylated aldimines 94 and Brassard s diene 97. Subsequent treatment with benzoic acid led to the formation of piperidinones 98. Interestingly, the use of its pyridinium salt (3 mol%) resulted in a higher yield (87% instead of 72%) along with a comparable enantioselectivity (94% ee instead of 92% ee). This method furnished cycloadducts 98 derived from aromatic, heteroaromatic, a,P-unsaturated, and aliphatic precursors 94 in satisfactory yields (63-91%) and excellent enantioselectivities (92-99% ee). NMR studies revealed that Brassard s diene 97 is labile in the presence of phosphoric acid 3m (88% decomposition after 1 h), but comparatively stable in the presence of its pyridinium salt (25% decomposition after 1 h). This observation can be explained by the fact that the pyridinium salt is a weak Brpnsted acid compared to BINOL phosphate 3m. [Pg.425]

On the one hand. Rueping s protocol involved a combination of chiral BINOL phosphate (R)-3j (10 mol%, R = 2-naphthyl) bearing 2-naphthyl substituents and achiral acetic acid (20 mol%) [62], While stronger Brpnsted acid 3j is expected to activate electrophile 86, the weaker Brpnsted acid is proposed to facilitate the keto-enol tautomerism of nucleophile 101 (Scheme 40). On the other hand, Gong... [Pg.427]

Recently, several research gronps reported on the use of chiral BINOL phosphates as Brpnsted acid catalysts in MCRs involving imine activation. [Pg.429]

In 2007, Terada et al. extended their previously described chiral phosphoric acid-catalyzed aza-ene-type reaction of M-acyl aldimines with disubstituted enecarbamates (Scheme 28) to a tandem aza-ene-type reaction/cyclization cascade as a one-pot entry to enantioenriched piperidines 121 (Scheme 48). The sequential process was rendered possible by using monosubstituted 122 instead of a disubstituted enecarbamate 76 to produce a reactive aldimine intermediate 123, which is prone to undergo a further aza-ene-type reaction with a second enecarbamate equivalent. Subsequent intramolecular cychzation of intermediate 124 terminates the sequence. The optimal chiral BINOL phosphate (R)-3h (2-5 mol%, R = 4-Ph-C H ) provided the 2,4,6-sub-stituted M-Boc-protected piperidines 121 in good to exceUent yields (68 to > 99%) and accomplished the formation of three stereogenic centers with high diastereo- and exceUent enantiocontrol (7.3 1 to 19 1 transicis, 97 to > 99% ee(trans)) [72]. [Pg.433]

In 2008, Toste and coworkers reported the desymmetrization of me o-episulfonium ions 131 generated in situ from ring closure of sulfides 132 featuring a P-trichloro-acetimidate leaving group [76], Chiral BINOL-derived phosphoric acid (5)-3o (15 mol%, R = triggered the formation of the intermediate mera-epi-... [Pg.437]

In 2008, the Ackennann group reported on the use of phosphoric acid 3r (10 mol%, R = SiPhj) as a Brpnsted acid catalyst in the unprecedented intramolecular hydroaminations of unfunctionaUzed alkenes alike 144 (Scheme 58) [82], BINOL-derived phosphoric acids with bulky substituents at the 3,3 -positions showed improved catalytic activity compared to less sterically hindered representatives. Remarkably, this is the first example of the activation of simple alkenes by a Brpnsted acid. However, the reaction is limited to geminally disubstituted precursors 144. Their cyclization might be favored due to a Thorpe-Ingold effect. An asymmetric version was attempted by means of chiral BINOL phosphate (R)-3( (20 mol%, R = 3,5-(CF3)2-CgH3), albeit with low enantioselectivity (17% ee). [Pg.441]

In 2006, Yamamoto and Nakashima picked np on this and designed a chiral A -triflyl phosphoramide as a stronger Brpnsted acid catalyst than the phosphoric acids based on this concept. In their seminal report, they disclosed the preparation of new chiral BINOL-derived A -triflyl phosphoramides and their application to the asymmetric Diels-Alder (DA) reaction of a,p-unsaturated ketones with sily-loxydienes [83], As depicted in Scheme 59, chiral A-triflyl phosphoramides of the general type 4 are readily synthesized from the corresponding optically active 3,3 -substituted BINOL derivatives 142 through a phosphorylation/amidation route. [Pg.442]

Scheme 59 Preparation of chiral BINOL-derived iV-tiiflyl phosphoramides... Scheme 59 Preparation of chiral BINOL-derived iV-tiiflyl phosphoramides...
Simon L, Goodman JM (2008) Theoretical study of the mechanism of Hantzsch ester hydrogenation of imines catalyzed by chiral BINOL-phosphoric acids. J Am Chem Soc 130 8741-8747... [Pg.271]

Liu et al. 43) prepared chiral BINOL ligands bearing dendritic Frechet-type polybenzyl ether wedges ((J )-41-(J )-44), which were assessed in enantioselective Lewis acid-catalyzed addition of Et2Zn to benzaldehyde. [Pg.109]

M. Shi and Y.-L. Shi reported the synthesis and application of new bifunctional axially chiral (thio) urea-phosphine organocatalysts in the asymmetric aza-Morita-Baylis-Hillman (MBH) reaction [176, 177] of N-sulfonated imines with methyl vinyl ketone (MVK), phenyl vinyl ketone (PVK), ethyl vinyl ketone (EVK) or acrolein [316]. The design of the catalyst structure is based on axially chiral BINOL-derived phosphines [317, 318] that have already been successfully utilized as bifunctional catalysts in asymmetric aza-MBH reactions. The formal replacement of the hydrogen-bonding phenol group with a (thio)urea functionality led to catalysts 166-168 (Figure 6.51). [Pg.301]

TABLE 32. Results of the aluminum-catalyzed asymmetric Baeyer-VilUger oxidation using chiral BINOL ligand and achiral and chiral hydroperoxides... [Pg.555]

TRANSFER HYDROGENATION USING CHIRAL BINOL-PHOSPHATES AS CATALYSTS. 162... [Pg.161]

In 1997 Pu reported a new type of main chain chiral polymer derived from BINOLs [24]. Polymer 16 catalyzed enantioselective ethylation using diethylzinc to give secondary alcohols in up to 94% ee. It is noteworthy that 16 is a derivative of chiral BINOL but the addition of Ti(IV) is unnecessary unlike other reported chiral monomeric diols. In 1998, Pu reported that polymer 17, which has a phenylene spacer between two BINOL moieties, results in better ees of up to 98% [24]. [Pg.98]

In an effort to develop new chiral BINOL-Ti complexes, chemical modifications of the chiral complex (f )-BINOL-Ti(OPr )2 (R-2) that can easily be prepared by simply mixing ( PrO)4Ti and (/ )-BINOL in the absence ofMS4A have been studied [37c-e]. A dimeric form has been reported for the single-crystal X-ray structure of complex R-2 [38], (I )-BINOL-Ti-p3-oxo complex, prepared via hydrolysis of complex R-2 has been shown to serve as an efficient and moisture-tolerable asymmetric catalyst [37d,e]. It is noteworthy that the (/ )-BINOL-Ti-)i3-oxo catalyst [37e] shows a remarkable level of (+)-NLE (asymmetric amplification), thereby attaining the maximum enantioselectivity for this system by using (/ )-BINOL with only 55-60% ee as the chiral source (consult Scheme 8C. 14). [Pg.552]

Keck reported an asymmetric allylation with a catalytic amount of chiral titanium catalyst [24]. The enantioselective addition of methallylstannane to aldehydes is promoted by a chiral catalyst 13 prepared from chiral BINOL and Ti(0-i-Pr)4 (Scheme 9.10). An example of asymmetric amplification was reported by using (R)-BINOL of 50% ee, and the degree of asymmetric amplification was dependent on the reaction temperature. Tagliavini also observed an asymmetric amplification in the enantioselective allylation with a BIN0L-Zr(0-i-Pr)2 catalyst [25]. [Pg.705]

Asymmetric amplification has also been observed in lanthanum-catalyzed nitro-aldol reaction, Shibasaki used a chiral lanthanum complex 15 prepared from LaCl3 and dilithium alkoxide of chiral BINOL for the enantioselective aldol reaction between naphthoxyacetaldehyde 14 and nitromethane (Scheme 9.11) [26]. When chiral catalyst 15 was prepared from BINOL with 56% ee, the corresponding aldol adduct 16 with 68% ee was obtained. This result indicates that the lanthanum 15 complex should exist as oligomer(s). [Pg.705]

Uemura reported a highly enantioselective oxidation of sulfides to sulfoxides using a chiral titanium complex prepared from chiral BINOL and Ti(0-i-Pr)4, and this reaction exhibits a remarkable asymmetric amplification (Scheme 9.15) [33]. [Pg.708]

Chiral BINOL (60) is a bifunctional organocatalyst in addition to the phenolic Brpnsted acid groups, it has a Lewis base unit attached via a spacer moiety.167 This particular combination holds the groups in a conformational lock, where they can doubly activate a substrate while giving a high level of stereocontrol. For this example of an aza-Morita-Baylis-Hillman reaction of an enone and an imine, yields up to 100% and ees up to 96% have been achieved. [Pg.22]

Dialkylzinc reagents combine with BINOL to generate, in situ, a catalyst for homogeneous epoxidation of (/y)-o /3-enoncs to the corresponding f raws-epoxy ketones. TBHP and cumene hydroperoxide (CHP) are effective terminal oxidants for this process ees of up to 96% have been achieved. Mechanistic investigations point towards an electrophilic activation (Scheme 11) of the substrates by the chiral BINOL-zinc catalyst and a subsequent nucleophilic attack of the oxidant227... [Pg.116]

A chiral BINOL-indium(in) complex has been used to catalyse the addition of allyltributylstannane to aldehydes in high ee.184... [Pg.21]

Chiral BINOL-indium(ni) complexes have been employed in several enantioselective allylations (i) in the ionic liquid, hexylmethylimidazolium-PF6, for aldehydes,190 (ii) a moisture tolerant version, for a wide variety of aldehyde types,191 and (iii) a recyclable example, useful for aromatic, aliphatic, and a,/S-unsaturated ketones.192... [Pg.22]


See other pages where Chiral BINOL is mentioned: [Pg.45]    [Pg.157]    [Pg.164]    [Pg.75]    [Pg.223]    [Pg.79]    [Pg.377]    [Pg.215]    [Pg.395]    [Pg.410]    [Pg.417]    [Pg.108]    [Pg.558]   
See also in sourсe #XX -- [ Pg.174 , Pg.463 , Pg.466 , Pg.468 , Pg.475 ]

See also in sourсe #XX -- [ Pg.426 ]




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BINOL

BINOL based chiral phosphate

Binol-derived chiral boronic acid

Chiral BINOL derived amine

Chiral BINOL-derived phosphoric acids

Chiral BINOL-phosphoric acid catalyst

Chiral BINOL-phosphoric acids

Chiral binol derived bifunctional amine

Chiral ligands BINOL

Metal-free reduction of imines enantioselective Br0nsted acid-catalyzed transfer hydrogenation using chiral BINOL-phosphates as catalysts

Two-Center Chiral Phase-Transfer Catalyst Derived from BINOL

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