Butane chirality

Only reaction 1 provides a direct pathway to this chiral molecule the intermediate 2-methyl-butanal may be silylated and reacted with formaldehyde in the presence of the boronated tartaric ester described on page 61. The enantiomeric excess may, however, be low. 

Addition to double bonds is not the only kind of reaction that converts an achiral molecule to a chiral one Other possibilities include substitution reactions such as the formation of 2 chlorobutane by free radical chlorination of butane Here again the prod uct IS chiral but racemic... 

When a reactant is chiral but optically inactive because it is racemic any products derived from its reactions with optically inactive reagents will be optically inactive For example 2 butanol is chiral and may be converted with hydrogen bromide to 2 bromo butane which is also chiral If racemic 2 butanol is used each enantiomer will react at the same rate with the achiral reagent Whatever happens to (/ ) (—) 2 butanol is mir rored m a corresponding reaction of (5) (+) 2 butanol and a racemic optically inactive product results... 

It is unlikely that a (8-chelate analogous to 2 is responsible for the very high syn diastereoselectivity which is observed with the chiral vinyllithium reagent (7 )-3 upon addition to (/t)-3-(benzyl oxy)butanal (Table 13)11 °. 

The second option involves the incorporation of either chiral amines or chiral alcohols into the heteroatom-carbene side chain (R ), which represents the most versatile approach to diastereoselective benzannulation. The optically pure (2R,3R)-butane-2,3-diol was used to tether the biscarbene complex 37. The double intramolecular benzannulation reaction with diphenylbutadiyne allowed introduction of an additional stereogenic element in terms of an axis... 

It may be observed that the gauche conformation of butane (L) or any other similar molecule is chiral. The lack of optical activity in such compounds arises from the fact that L and its mirror image are always present in equal amounts and interconvert too rapidly for separation. 

ABSTRACT Zeolite Y modified with chiral sulfoxides has been foimd catal rtically to dehydrate racemic butan-2-ol enantioselectively depending on the chiral modifier used. Zeolite Y modified with R-l,3-dithiane-1-oxide shows a higher selectivity towards conversion of S-butan-2-ol and the zeolite modified with S-2-phenyl-3-dithiane-1-oxide reacts preferentially with R-butan-2-ol. Zeolite Y modified with dithiane oxide demonstrates a significantly higher catalsdic activity when compared to the unmodified zeolite. Computational simulations are described and a model for the catalytic site is discussed. 

In a further set of experiments racemic butan-2-ol was reacted with zeolite Y modified with chiral sulfoxides. In the first set of experiments racemic butan-... 

Chiral diphosphites based on (2R,3R)-butane-2,3-diol, (2R,4R)-pentane-2,4-diol, (25, 5S)-hexane-2,5-diol, (lS -diphenylpropane-hS-diol, and tV-benzyltartarimide as chiral bridges have been used in the Rh-catalyzed asymmetric hydroformylation of styrene. Enantioselectivities up to 76%, at 50% conversion, have been obtained with stable hydridorhodium diphosphite catalysts. The solution structures of [RhH(L)(CO)2] complexes have been studied NMR and IR spectroscopic data revealed fluxional behavior. Depending on the structure of the bridge, the diphosphite adopts equatorial-equatorial or equatorial-axial coordination to the rhodium. The structure and the stability of the catalysts play a role in the asymmetric induction.218... 

Early work in the field of asymmetric hydroboration employed norbornene as a simple unsaturated substrate. A range of chiral-chelating phosphine ligands were probed (DIOP (5), 2,2 -bis(diphenyl-phosphino)-l,l -binaphthyl (BINAP) (6), 2,3-bis(diphenylphosphino)butane (CHIRAPHOS) (7), 2,4-bis(diphenylphosphino)pentane (BDPP) (8), and l,2-(bis(o-methoxyphenyl)(phenyl)phos-phino)ethane) (DIPAMP) (9)) in combination with [Rh(COD)Cl]2 and catecholborane at room temperature (Scheme 8).45 General observations were that enantioselectivities increased as the temperature was lowered below ambient, but that variations of solvent (THF, benzene, or toluene) had little impact. 

The nontrivial synthetic procedures to give the tertiary phosphines chiral at phosphorus (10) led Morrison s group (221, 222) to synthesize neomenthyldiphenylphosphine [(+)-NMDPP] (12) and led Kagan s group (10. 223, 224) to synthesize 2,3-o-isopropylidene-2,3-dihydroxy-1,4-bis(diphenylphosphino)butane [(-)-DIOP] (13) from the commercially... 

Remarkable success has been achieved by Fryzuk and Bosnich (247) using the complex [Rh(5,5-chiraphos)(COD)]+, where the chiral ligand 25,55-bis(diphenylphosphino)butane, a diphosphine chiral at carbons (25), is readily synthesized from 2R,3R-butane diol. TheZ-isomers of the prochiral a-N-acylaminoacrylic acid substrates were hydrogenated at ambient conditions to / -products with very high enantiomeric excess indeed, leucine and phenylalanine derivatives were obtained in complete optical purity. Catalytic deuteration was shown to lead to pure chiral f3-carbon centers as well as a-carbon centers in the leucine and phenylal-... 

H. B. Kagan, T.-P. Dang, Asymmetric Catalytic Reduction with Transition Metal Complexes. I. A Catalytic System of Rhodium(I) with (-)-2,3-0-Isopropylidene-2,3-dihydroxy-l,4-bis(diphenylphosphino)butane, a New Chiral Diphosphine, J. Am. Client Soc. 1972, 94, 6429-6433. 

M. Mons, E Piuzzi, I. Dimicoli, A. Zehnacker, and F. Lahmani, Binding energy of hydrogen bonded complexes of the chiral molecule 1 phenylethanol, as studied by 2C R2PI Comparison between diastereoisomeric complexes with butan 2 ol and the singly hydrated complex. Phys. Chem. Chem. Phys. 2, 5065 5070 (2000). 

J. Paul, I. Hearn, and B. J. Howard, Chiral recognition in a single molecule A study of homo and heterochiral butan 2,3, diol by Fourier transform microwave spectroscopy. Mol. Phys. 105, 825 839 (2007). 

Irradiation of the enantiomerically enriched allenenone 42 afforded alkylididecy-clobutane 43 with high levels of chirality transfer. The silyl moiety of optically active allenylsilanes 44 and 47 functioned as a removable auxiliary to control the stereochemistry. Thus, the silyl-substituted photoadducts 45 and 48 underwent protode-silylation on treatment with TBAF to give the unsubstituted exo-mcth ylenccyclo-butanes 46 and 49, respectively [46]. 

Bidentate chiral water-soluble ligands such as (S,S)-2,4-bis(diphenyl-sulfonatophosphino)butane BDPPTS (Fig. 2) or (R,R) 1,2-bis(diphenylsul-fonatophosphinomethyl)cyclobutane have been prepared [25]. Their palladium complexes catalyze the synthesis of chiral acids from various viny-larenes and an ee of 43% has been reached for p-methoxystyrene with the BDPPTS ligand. Furthermore, recycling of the aqueous phase has shown that the regio- and enantioselectivity are maintained and that no palladium leaches. 

Seebach and Daum (75) investigated the properties of a chiral acyclic diol, 1,4-bis(dimethylamino)-(2S,35)- and (2K,3/ )-butane-2,3-diol (52) as a chiral auxiliary reagent for complexing with LAH. The diol is readily available from diethyl tartrate by conversion to the dimethylamide and reduction with LAH. The diol 52 could be converted to a 1 1 complex (53) with LAH (eq. [18]), which was used for the reduction of aldehydes and ketones in optical yields up to 75%. Since both enantiomers of 53 are available, dextro- or levorotatory products may be prepared. The chiral diol is readily recoverable without loss of optical activity. The (- )-52-LAH complex reduced dialkyl and aryl alkyl ketones to products enriched in the (S)-carbinol, whereas (+ )-52-LAH gives the opposite result. The highest optical yield of 75% was obtained in the reduction of 2,4,6-... 

In the intermolecular reaction of tetraynes, where two 1,6-diyne moieties were directly connected, with monoalkynes, CHIRAPHOS (2,3-bis(diphenylphosphino) butane) was the choice of chiral ligand, and axial chirality was enantiomericaUy generated between the formed benzene rings (Scheme 11.17). Hexaynes with a 1,3-diyne moiety also underwent an intramolecular [2-i-2-i-2] cycloaddition, and the Ir-xylylBINAP (2,2 -bis[di(3,5-xylyl)phosphino]-l,l -binaphthyl) catalyst induced an excellent enantiomeric excess (ee) (Scheme 11.18) [24]. 

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