A modular library of readily available phosphite-oxazoline ligands (L1-L16a-f) has been successfully applied for the first time in the Ir-catalyzed asymmetric hydrogenation of a broad range of highly unfunctionalized 1,1,-disubstituted terminal alkenes. Enantioselectivities up to >99% and full conversions were obtained in several 1,1-disubstituted alkenes, including substrate classes that have never been asymmetrically hydrogenated before (i.e., 1,1-heteoraryl-alkyl, 1,1-diaryl, trifluoromethyl, etc.). The results indicated that these catalytic systems have high tolerance to the steric and electronic requirements of the substrate and also to the presence of a neighboring polar group. The asymmetric hydrogenations were also performed using propylene carbonate as solvent, which allowed the Ir catalyst to be reused and maintained the excellent enantioselectivities.
A range of saturated chiral azacycles has been prepared in high yield and with high selectivity from simple starting materials. A modular approach with ring-closing metathesis as a key step was used to produce a number of five-, six-, and seven-membered cyclic alkenes. Asymmetric hydrogenation catalyzed by N,P-ligated iridium complexes gave saturated azacycles in high optical purity. This methodology was demonstrated in the synthesis of a pharmaceutical precursor.
Several types of chiral hetero-and carbocyclic compounds have been synthesized using the asymmetric hydrogenation of cyclic alkenes. N, P-ligated iridium catalysts reduced six-membered cyclic alkenes with various substituents and heterofunctionality in good to excellent enantioselectivity; whereas the reduction of five-membered cyclic alkenes was generally less selective, giving modest enantiomeric excesses. The stereoselectivity of hydrogenation depended more strongly on substrate structure for the five-rather than sixmembered cyclic alkenes. The major enantiomer formed in the reduction of six-membered alkenes could be predicted from a selectivity model and isomeric alkenes had complementary enantioselectivity, giving opposite optical isomers upon hydrogenation.The utility of the reaction was demonstrated by using it as a key step in the preparation of chiral 1,3-ciscyclohexane carboxylates.
By extracting lignin, pulp production can be increased without heavy investments in a new recovery boiler, the typical bottleneck of a pulp mill. The extraction is performed by using 0.20 and 0.15 weight equivalents of CO 2 and H 2 SO 4 respectively. Herein, we describe lignin esterification with fatty acids using benign reagents to generate a lignin ester mixable with gas oils. The esterification is accomplished by activating the fatty acid and lignin with acetic anhydride which can be regenerated from the acetic acid recycled in this reaction. The resulting mass balance ratio is fatty acid/lignin/acetic acid (2 : 1 : 0.1). This lignin ester can be hydroprocessed to generate hydrocarbons in gasoline, aviation, and diesel range. A 300-hour continuous production of fuel was accomplished. By recirculating reagents from both the esterification step and applying a water gas shift reaction on off-gases from the hydroprocessing, a favorable overall mass balance is realized.
Black
liquor (BL) from the kraft pulping process has been treated
at elevated temperatures (380 °C) in a batch reactor to give
high yields of a bio oil comprising monomeric phenolic compounds that
were soluble in organic solvents and mineral oil and a water fraction
with inorganic salts. The metal content in the product was <20
ppm after a simple extraction step. A correlation between concentration,
temperature, and reaction time with respect to yield of desired product
was found. At optimal reaction conditions (treating BL with 16 wt
% dry substance at 380 °C for 20 min), the yield of extractable
organics was around 80% of the original lignin with less than 7% of
char. The product was analyzed by gel permeable chromatography, mass
spectroscopy, nuclear magnetic resonance, elemental analysis, and
inductively coupled plasma. It was found that a large fraction composed
of mainly cresols, xylenols, and mesitols. This process provides a
pathway to convert a major waste stream from a pulp mill into a refinery
feed for fuel or chemical production, whereas at the same time the
inorganic chemicals are recovered and can be returned back to the
pulp mill.
We have described the first successful application of a phosphite-oxazoline ligand library in the asymmetric Ir-catalyzed hydrogenation of several unfunctionalized olefins. The introduction of a bulky biaryl phosphite moiety in the ligand design is highly adventitious in the product outcome. By carefully selecting the ligand components, we obtained high activities (TOFs up to >1500 mol x (mol x h)(-1) at 1 bar of H2) and enantioselectivities (ee values up to >99%) and, at the same time, show a broad scope for different substrate types. So, this is an exceptional ligand class that competes favorably with a few other ligand series that also provide high ee values for tri- and disubstituted substrate types.
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