Boranes, tert, chiral

Chiral boranes have been recommended as Lewis acids catalysts by Reetz [689], Yamamoto [787, 788], Kiyooka [795, 1302], Masamune and their coworicers [796, 797], These groups used, respectively, boranes 2.61, 3.9 (R = H, R = /-Pr), 3.10 (R = i-Pr or tert-Bu, R = H) and derivatives of 3.12 and 3.13. These boranes are very efficient catalysts in asymmetric additions of symmetrically substituted ketene silylacetals 6.113 to aldehydes (Figure 6.94). Similar reactions can also be conducted with enoxysilanes derived from methylketones or from tert-Bu thiolacetate [787, 794, 796], Oxazaborolidine 3.10 derived from tryptophan 3.11 is also a very potent catalyst [794],... 

The opening of oxazaphospholidine rings (/ p)-122 with tert-butyllithium occurred diastereoselectively with retention of absolute configuration on the phosphorus atom, affording the borane complex of aminophosphine (Rp)-124 [67, 68]. The reaction possibly proceeds via formation of chiral o X -phosphenium cation 126, which was obtained from (Sc)-chlorophosphine 125 and then isolated as borane complex 127 (Scheme 38). 

In this chapter, catalytic methods for ligand synthesis are described in detail. In spite of that, the enantioselective deprotonation of tert-butyldimethylpho-sphine borane with a catalytic amount of (—)-sparteine or a (+)-sparteine surrogate, reported by O Brien and co-workers, is included for convenience in Chapter 5, Section 5.4.2, following the discussion on the general strategy of desymmetrisation by enantioselective deprotonation. The coverage of Section 6.2 is mainly limited to systems in which the chiral catalyst acts in the step where the... 

In 1998, Livinghouse s group introduced a route to chiral aryldialkyl-phosphines wherein racemic tert-butylphenylphosphine-borane underwent... 

In parallel with the search for catalytic systems, has emerged an impressive amount of results in the field of enantioselective allylation. The pioneering work of Marshall using a chiral (acyloxy)borane (CAB) system [216] was readily followed by titanium/BINOL catalysts [217], leading to homoallylic alcohols with enantiomeric excess up to 98%. An extension of this work in fluorous phase was also developed with 6,6 -perfluoroalkylated BINOLs [218]. Replacing the titanium by zirconium (IV) salts, led to more reactive catalyst for the allylation of aromatic and aliphatic aldehydes [219]. One of the more active catalyst is the zirconium-BINOL system associated with 4-tert-butylcalix [4]arene, which remains active with only 2% of the chiral inductor [220]. The use of activators, such as iPrSSiMe3, iPrSBEt2,... 

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