This work deals with the development of a new family of planar chiral phosphoric acids based on a ferrocenophane/paracyclophane scaffold. The synthetic approach has been improved by taking advantage of a chiral phosphorylating agent to access enantiomerically enriched acids via diastereomers separation. These phosphoric acids have been used as catalysts for the enantioselective H‐transfer reduction of α‐substituted quinolines with Hantzsch esters. Optimization of both the catalyst and the Hantzsch reductant allowed ee values in the range 82–92% to be attained starting from α‐arylquinolines.
The palladium‐catalyzed direct C H bond acetoxylation of [2.2]paracyclophanes has been investigated. Various mono‐ and disubstituted [2.2]paracyclophanes were subjected to typical Sanford acetoxylation conditions. Oxime ethers, an oxime acetate, a pyridine, and a pyrazole with [2.2]paracyclophane cores underwent direct ortho‐acetoxylation in good to excellent yields using 1–5 mol% of palladium(II) acetate in combination with iodobenzene diacetate as oxidant. The reactions could be performed on a multigram scale, and the ortho‐acetoxylated [2.2]paracyclophanes were suitable for further functionalizations affording a hydroxy[2.2]paracyclophane derivative and a planar chiral benzoxazole. 相似文献
The transfer hydrogenation of 2‐substituted bicyclic and monocyclic ketimines using HCO2H/ Et3N as the hydrogen source and TsDPEN‐based Ru(II) and Ir(III) catalysts proceeds with dynamic kinetic resolution to afford the corresponding cis‐cycloalkylamines with moderate to excellent levels of diastero‐ and enantioselectivity. A “one‐pot” procedure starting from ketones as starting materials with in situ formation of the reacting imines has also been developed. 相似文献
The diastereomeric 1,4‐diphosphine ligands, (S,S,S,S)‐ 1a , (R,S,S,R)‐ 1b and (R,S,S,S)‐ 1c , with the imidazolidin‐2‐one backbone were synthesized, and utilized for an investigation of the effects of backbone chirality on the enantioselectivity in the Rh(I)‐catalyzed hydrogenation of various functionalized olefinic substrates. It was found that the catalytic efficiencies are largely dependent on the configurations of the α‐carbons to phosphine. Thus, the Rh complex of the pseudo‐C2‐symmetrical diphosphine, (R,S,S,S)‐ 1c , showed excellent enantioselectivities (93.0–98.6% ees) in the hydrogenations of a broad spectrum of substrates, and especially in the hydrogenations of methyl α‐(N‐acetyamino)‐β‐arylacrylates (95.3–97.0% ees). However, the enantioselectivities obtained with the C2‐symmetrical (R,S,S,R)‐ 1b were largely dependent on the substrate (19.8–97.3% ees). The Rh complex of ligand 1a having the (S,S,S,S)‐configuration showed the lowest catalytic efficiency for all of the substrates examined (0–84.8% ees). 相似文献
Synthetic routes to pseudo‐geminal, pseudo‐ortho and ortho hydroxy‐oxazolinyl[2.2]paracyclophanes (and the diastereoisomers of each) for use as N,O ligands in asymmetric catalysis have been devised. The substitution pattern was found to have a strong effect on the rate and enantioselectivity of the formed catalyst in the addition of diethylzinc to benzaldehyde. 相似文献
The synthesis of chiral 3‐hydroxy‐2‐methylpropanoic acid esters (e.g., “Roche ester” 3a ) based on the rhodium‐catalyzed stereoselective hydrogenation of Baylis–Hillman reaction products was investigated. Full conversions and enantioselectivities of up to 99% at a substrate/catalyst ratio of up to 500/1 were achieved by application of bisphospholanes of the catASium M series as ancillary ligands. An interesting kinetic resolution was observed by the diastereoselective hydroxy‐directed hydrogenation of related racemic β‐branched precursors affording mainly anti‐isomers with up to 96%ee. 相似文献
Quasi-equilibrium between catalytic reactive intermediates and reactant or product molecules is a common assumption. As process conditions vary, this assumption may cease to be valid because of kinetic coupling between steps in the catalytic cycle. In the case of coupled catalytic cycles, kinetic coupling manifests itself by substantial changes in selectivity. An elegant example of catalytic coupling in and between catalytic cycles is the change in enantioselection with H2 pressure for the asymmetric hydrogenation of a prochiral alkene, as discovered in the Halpern laboratory. 相似文献
The asymmetric transfer hydrogenation (ATH) of ketones is an efficient method for producing enantio-enriched alcohols which are used as intermediates in a variety of industrial processes. Here we report the synthesis of new iron ATH precatalysts (S,S)-[FeBr(CO)(Ph2PCH2CH2NHCHPhCHPhNC=CHCH2PR′2)][BPh4] (R′=Et, and ortho-tolyl (o-Tol)) where one of the phosphine groups is modified with small alkyl and large aryl substituents to probe the effect of this change on the activity and selectivity of the catalytic system. A simple reversible equilibrium kinetic model is used to obtain the initial TOF and the inherent enantioselectivity S=kR/kS of these catalysts along with those for the previously reported catalysts with R′=Ph and Cy for the ATH of acetophenone. With an increase in the size of the PR′2 group, the TOF goes through a maximum at PPh2 while the S value goes through a maximum of 510 at R′=Cy. The complex with R′=o-Tol starts with a high S value of 200 but is rapidly changed to a second catalyst with an S value of 28. For the reduction of acetophenone to (R)-1-phenylethanol, turnover numbers of up to 5200 and ee up to 98 % were achieved. The chemotherapeutic pharmaceutical precursor (R)-(3′,5′-bis(trifluoromethyl))-1-phenylethanol is synthesized in up to 95 % ee. Several other alcohols can be prepared in greater than 90 % ee by choosing the precatalyst with the correctly matched steric properties. A hydride complex derived from the catalyst with R′=Cy is characterized by NMR spectroscopy. It is proposed that low concentration trans-hydride carbonyl complexes with the FeH parallel to the NH of the ligand are the active catalysts in all of these systems. 相似文献
Herein, we present a chiral boro-phosphate catalyzed atroposelective asymmetric transfer hydrogenation method, leading to a family of axially chiral styrene-type allylalcohols. This dynamic kinetic resolution approach portrays simple procedure, mild conditions and good enantiocontrol (51–95% ee), thus providing an important alternative to assemble the challenging atropisomeric aryl-acyclic alkene scaffolds.
We report the asymmetric allylic alkylation of allylic chlorides with silyl enolates as a carbon nucleophile using a planar‐chiral cyclopentadienyl‐ruthenium (Cp′Ru) catalyst. The reaction proceeds under unusually mild conditions to give the desired branched products with complete regioselectivity and high enantioselectivity, and reactive functional groups, such as aldehyde, can be tolerated. In this reaction system, Cp′Ru plays an important role in activating both silyl enolate and allylic chloride.
A concise, enantioselective total synthesis of symbioramide, starting from simple achiral compounds and racemic α‐amino‐β‐keto ester derivatives is reported. This highly flexible strategy allowed the efficient preparation of seven structural isomers of the natural product as well. The synthesis relies on a convergent route that involves the efficient stereoselective reduction of a α‐keto‐β‐yne ester, and the dynamic kinetic resolution of an α‐amino‐β‐keto ester through ruthenium‐mediated asymmetric hydrogenation. 相似文献
The dynamic kinetic resolution of sulfinyl chlorides by addition of the optically active alcohol DAGOH (diacetone D ‐glucose) in the presence of non‐chiral bases was theoretically studied at the ONIOM (Becke3LYP:UFF) level. The dependence of the stereochemical outcome on the nature of the base observed in this reaction was explored considering two electronically similar bases, pyridine and collidine, that are experimentally known to promote opposite diastereoselectivities. Our calculations reproduced the experimental result that the absolute configuration of sulfur in the major reaction product is R with pyridine but S with collidine. The analysis of the optimized geometries revealed that the most sterically active substituent around sulfur is the methyl of the substrate with pyridine but the base itself with collidine. This leads to an inversion of the chiral distribution of steric hindrance around sulfur that induces the reversal of the stereochemical outcome. 相似文献
A one-pot synthesis of fluorinated chiral alcohols from α-bromoarylketones and fluoroalcohols is described. The fluorinated ketone intermediates were formed from α-bromoarylketones with fluoroalcohols as nucleophiles and solvents, which were reduced subsequentially by adding a chiral Ru catalyst and a mixture of formic acid and triethyl amines (FA: TEA=1.1:1) as hydrogen donor to give 27 examples of fluorinated chiral alcohols in 60–93% yields and 85–98% ee values. Notably, K3PO4 acts as a base in nucleophilic substitution and an additive in reductive step to enhance the reactivity and enantioselectivity, which is crucial for constructing compatible conditions for one-pot process. This one-pot process is also applicable to gram-scale synthesis. 相似文献
A one pot, three‐step cascade reaction to provide functionalized proline derivatives was developed. The Michael addition reaction of N‐allylated proline and activated alkyne forms a zwitterionic intermediate that further undergoes cyclization and [2,3]‐rearrangement to provide Cα‐alkylated proline bicyclic derivatives. This transformation was highly stereoselective and the chirality of the N‐allylated prolines was completely transferred to the product via a C−N−C chirality transfer process. The developed reaction is operationally simple and does not require any reagents other than the substrates.
Two novel diastereomeric [2.2]paracyclophane ketimine ligands (SP,S)‐ 2 and (RP,S)‐ 2 , which unite a planar chiral element and a central chiral element, were used towards the enantioselective diethylzinc addition onto aliphatic aldehydes. These improved second‐generation ligands, which are stable in air and water and are easy to obtain, showed significant improvements with respect to the ligands that were previously used. 相似文献
Novel P2N4‐donors containing chiral 22‐membered macrocyclic ligands have been synthesized and the structures have been determined by an X‐ray diffraction study. The catalytic systems in situ generated from triiron dodecarbonyl, Fe3(CO)12, and the chiral macrocyclic ligand exhibited high activity (TOF up to 1940 h−1) and excellent enantioselectivity with up to 99% ee in the asymmetric transfer hydrogenation of various aromatic ketones. 相似文献
Herein, we report the successful transformation of a 1st generation Grubbs metathesis catalyst into an asymmetric transfer hydrogenation (ATH) catalyst. Upon addition of a chiral amine ligand, an alcohol and a base, the 1st generation Hoveyda–Grubbs catalyst ( HG‐I ) was found to promote the enantioselective reduction of acetophenone to 1‐phenylethanol. After optimizing the order of addition and the reaction conditions, the substrate scope was assessed leading to enantiomeric excesses up to 97% ee. NMR experiments were run in order to get information about the in situ‐generated ATH catalyst. Furthermore, the possibility to perform olefin metathesis and ketone transfer hydrogenation sequentially in one pot was demonstrated, and the first tandem olefin metathesis–ketone asymmetric transfer hydrogenation was carried out.
Here we report theoretical studies on the ruthenium‐catalyzed reduction of acetophenone (and 2‐hexanone) with the intent of understanding the relative roles of catalyst and substrate along the reaction path. Overall ten reaction pathways are examined. The first eight are for acetophenone: they arise from the presence of two catalysts, with the more enantioselective one labeled 1 , and the poorer one labeled 2 , multiplied by the two configurations that the metal center of the catalysts can assume, multiplied by the two approaches, Re‐ and Si‐side, of the substrate to the catalyst. Two pathways are examined for 2‐hexanone and entail the two approaches to the ketone of the more effective catalyst. Density functional theory calculations provide structures of the minima and transition states, which subsequently have been assessed with the “continuous chirality measure” model developed by Avnir and collaborators. The picture that emerges is that the asymmetric induction is due to the interplay between the organometallic system and the organic substrate. This is effective only for catalyst 1 , which can interact effectively with acetophenone along only one in four of the reaction pathways, but not for 2 for which two out of four pathways are opened. For the hydrogenation of 2‐hexanone, the same catalyst 1 cannot produce enantiomeric excesses because the conformation of the substrate in the transition state induced by the catalyst has a relative low chirality. 相似文献
