CO2 fixation : catalytic synthesis of β-hydroxycarboxylic acids

Flowers, Brendan John Scott

27 August 2008

Although carbon dioxide as a greenhouse gas is a serious environmental concern, it remains a valuable C1 source if viable methods are available for its conversion into useful products. Herein, we present recent progress in the synthesis of aliphatic, aromatic, cyclic, and bicyclic beta-ketocarboxylic acids and the promising results from subsequent asymmetric hydrogenation to give beta-hydroxycarboxylic acids. For the synthesis of the beta-ketocarboxylic acids, we investigated the effects of temperature, reaction time, and amount of 1,8-diazabicyclo(5.4.0)undec-7-ene (DBU), which is a promoter for carbon-carbon bond formation with CO2. The highest-yielding conditions for this DBU-promoted carboxylation reaction were used to carboxylate a number of aliphatic and aromatic substrates. In order to determine whether the hydrogenation reaction will effectively compete with the in situ decarboxylation of the beta-ketocarboxylic acids, 1H NMR spectroscopy was used to monitor the rate of decarboxylation. The solvent, electronic, and steric effect on the rate of decarboxylation was investigated by testing a variety of beta-ketocarboxylic acids. Using œRuCl2{(S)-BINAP} catalyst precursor, we determined the effect that solvent, H2 pressure, base, and substrate substitution had on the enantioselectivity of the asymmetric hydrogenation. CH2Cl2 and MeOH were determined to be the best solvents because of the high hydrogenation selectivity, high enantioselectivity, and decreased reaction times. These standard conditions were used to hydrogenate the variety of aliphatic and aromatic beta-ketocarboxylic acids previously synthesized. Additional experiments, including deuterium labelling, were performed in an attempt to elucidate the hydrogenation mechanism and the actively hydrogenated tautomer. These results lead us to believe that different reaction pathways occur in protic versus aprotic solvents. The results discussed herein represent the first in depth investigation of transition metal catalyzed hydrogenation of beta-ketocarboxylic acids. These results are very encouraging because enantioselectivities greater than 99 % were achieved for multiple beta-keto acids. This synthesis is industrially advantageous due to the limited number of reactants required, their low-cost, and the potential for recycling unused materials. / Thesis (Master, Chemistry) -- Queen's University, 2008-08-26 10:17:34.703

Carbon dioxide fixation

Asymmetric catalysis

Carboxylation

Hydrogenation

Ketones

Proline catalyzed enantioselective retro-aldol reaction

2013 December 1900

In the Ward Group, stereoselective aldol reactions of thiopyran derived templates play an important role in polypropionate natural product syntheses. Central to this approach is the diastereo- and enantioselective synthesis of all possible aldol adducts 3 arising from tetrahydro-4H-thiopyran-4-one (1) and 1,4-dioxa-8-thiaspiro[4.5] decane-6- carboxaldehyde (2). There are four possible diastereomers of 3 indicated by the relative configurations at positions 3 and 1’ (syn or anti) and positions 1’ and 6’ (syn or anti). Up to date, the asymmetric aldol reaction of 1 with 2 catalyzed by L-proline or its tetrazole analogue 12 provides efficient access to 3,1’-anti-1’,6’-syn-3 (3-AS) without need for chromatography (>40 g scale; 75% yield, >98% ee) and 3,1’-syn-1’,6’-syn-3(3-SS) (via isomerization of 3-AS; >75% yield, 2 cycles); however, the preparation of enantiopure 3,1’-anti-1’,6’-anti-3 (3-AA) and 3,1’-anti-1’,6’-syn-3 (3-SA) still requires the use of enantiopure aldehyde 2 in a diastereoselective synthesis. Without a simple and scalable route, access to enantioenriched iterative aldol adducts and polypropionate natural products that are based on 3-AA and 3-SA skeletons are hindered. It was observed that conducting the asymmetric aldol synthesis of 3-AS on large scale gave enantioenriched 3-AA as a very minor product. This observation triggered the hypothesis of using L-proline to resolve racemic 3-AA via a retro-aldol reaction.In this thesis, the development, optimization, and application of an unprecedented L-proline catalyzed enantioselective retro-aldol reaction is described. Interesting mechanistic insights were uncovered. An unexpected isomerization process between 3-AA and 3-SA occurs in parallel with the retro-aldol process. The method was demonstrated to be a robust, flexible, and readily scalable process to access highly enantioenriched 3-AA (ee > 95%) and 3-SA (ee > 95%). To the best of our knowledge, this reaction represents the only reported enantioselective retro-aldol reaction catalyzed by L-proline.

L-proline

enantioselective

retro-aldol

asymmetric catalysis

polypropionate

aldol

Transition Metal Catalysis: Construction of Chiral Lactones, Ketones, Sulfoxides and 6-deoxyerythronolide B

Dornan, Peter

07 August 2013

The products of organic synthesis affect countless aspects of our everyday lives, from our medicines to our fuels, plastics and more. The discovery of new methods for organic synthesis is of paramount importance if we are to find greener and more efficient ways to synthesize commodity and fine chemicals, and lower the impact of the chemical industry on our environment. The aim of my doctoral thesis is to discover fundamentally new enantioselective transformations using transition metal catalysis, which can be applied to the synthesis of pharmaceutical agents, natural products or other fine chemicals. Hydroacylation is the atom economical addition of an aldehyde C–H bond across an unsaturated functional group such as an olefin or ketone. Theoretical studies on an intramolecular ketone hydroacylation catalyzed by rhodium were performed. The insights gained from this mechanistic study were then applied to the development of an asymmetric olefin hydroacylation using ethers, sulfides and sulfoxides as directing groups. Motivated by a desire to discover new catalysts with high activity and selectivity in rhodium catalyzed transformations, a chiral tridentate sulfoxide ligand was designed and synthesized. This ligand was found to be highly enantioselective in rhodium catalyzed 1,4-addition reactions. The use of allylic sulfoxides in a dynamic kinetic resolution was then investigated. The sulfoxide was found to direct a rhodium catalyzed olefin hydrogenation with simultaneous substrate racemization through a rhodium π-allyl pathway. Progress was made towards the total synthesis of a complex polyketide natural product, 6-deoxyerythronolide B. The key macrocyclization step was achieved in a model system by ring closing metathesis, and future work will be directed at completing the synthesis of the natural product.

Asymmetric catalysis

Rhodium

Sulfoxide

Natural product synthesis

0490

Transition Metal Catalysis: Construction of Chiral Lactones, Ketones, Sulfoxides and 6-deoxyerythronolide B

Dornan, Peter

07 August 2013

The products of organic synthesis affect countless aspects of our everyday lives, from our medicines to our fuels, plastics and more. The discovery of new methods for organic synthesis is of paramount importance if we are to find greener and more efficient ways to synthesize commodity and fine chemicals, and lower the impact of the chemical industry on our environment. The aim of my doctoral thesis is to discover fundamentally new enantioselective transformations using transition metal catalysis, which can be applied to the synthesis of pharmaceutical agents, natural products or other fine chemicals. Hydroacylation is the atom economical addition of an aldehyde C–H bond across an unsaturated functional group such as an olefin or ketone. Theoretical studies on an intramolecular ketone hydroacylation catalyzed by rhodium were performed. The insights gained from this mechanistic study were then applied to the development of an asymmetric olefin hydroacylation using ethers, sulfides and sulfoxides as directing groups. Motivated by a desire to discover new catalysts with high activity and selectivity in rhodium catalyzed transformations, a chiral tridentate sulfoxide ligand was designed and synthesized. This ligand was found to be highly enantioselective in rhodium catalyzed 1,4-addition reactions. The use of allylic sulfoxides in a dynamic kinetic resolution was then investigated. The sulfoxide was found to direct a rhodium catalyzed olefin hydrogenation with simultaneous substrate racemization through a rhodium π-allyl pathway. Progress was made towards the total synthesis of a complex polyketide natural product, 6-deoxyerythronolide B. The key macrocyclization step was achieved in a model system by ring closing metathesis, and future work will be directed at completing the synthesis of the natural product.

Asymmetric catalysis

Rhodium

Sulfoxide

Natural product synthesis

0490

Transition Metal Catalysis for Selective Synthesis and Sustainable Chemistry

Verendel, J. Johan

January 2012

This thesis discusses the preparation and use of transition-metal catalysts for selective organic chemical reactions. Specifically, two different matters have been studied; the asymmetric hydrogenation of carbon-carbon double bonds using N,P-ligated iridium catalysts and the metal-catalyzed transfer of small molecules from biomass to synthetic intermediates. In the first part of this thesis, chiral N,P-ligands were synthesized and evaluated in iridium catalysts for the asymmetric hydrogenation of non- and weakly functionalized alkenes (Papers I & II). The new catalysts were prepared via chiral-pool strategies and exhibited superior properties for the reduction of certain types of alkenes. In particular, some of the catalysts showed excellent activity and selectivity in the enantioselective reduction of terminal alkenes, and the preparation of a modular catalyst library allowed the asymmetric hydrogenation of a wide range of 1,1-disubstituted alkenes with unprecedented efficiency and enantioselectivity (Paper III). Methods for the selective preparation of chiral hetero- and carbocyclic fragments using iridium-catalyzed asymmetric hydrogenation as an enantiodetermining key step were also developed. A range of elusive chiral building blocks that have applications in pharmaceutical and natural-product chemistry could thus be conveniently prepared (Papers IV & V). The second part of this thesis deals with the catalytic decomposition of polysaccharides into sugar alcohols and the incorporation of their decomposition products into alkene substrates. Iridium-catalyzed dehydrogenative decarbonylation was found to decompose polyols into CO:H2 mixtures that could be used immediately in the ex situ low-pressure hydroformylation of styrene (Paper VI). The net process was thus the hydroformylation of alkenes with biomass-derived synthesis gas.

Catalysis

Transition metals

Asymmetric catalysis

Hydrogenation

Sustainable chemistry

Development of novel low-oxidation state main group catalysis : gallium & aluminium

Qin, Bo

January 2016

This PhD thesis is focused on the development of novel catalysis with low-oxidation main group species, mainly based on the group 13 element gallium, a relatively abundant, inexpensive, and low-toxic metal. Gallium in its stable high-oxidation state ‘+III’ is a commonly used Lewis acid catalyst in organic synthesis. In contrast, gallium in its less stable low-oxidation state ‘+I’ is under-explored, but may display both acceptor and donor properties at a single site (ambiphilicity). Based on the hypothesis that potentially ambiphilic gallium(I) –oxidatively generated in situ from gallium(0) using a silver salt– may activate both basic and acidic reagents, various gallium(I)-catalyzed carbon–carbon bond formations have been developed. These include catalytic C–O and C–B bond activations of electrophiles (acetals and aminals) and pro-nucleophiles (allyl and allenyl boronates), respectively. Gallium(III) and other metal Lewis acids have proved to be ineffective. These results represent the first catalytic use of gallium(0) in organic synthesis and a rare example of gallium(I) catalysis. The identity of the gallium(I) catalyst and its regeneration have been confirmed by 71Ga NMR analysis, and a reactive allyl–Ga(I) intermediate has been detected for the first time. In combination with 11B NMR and HRMS analyses, an SN1 reaction mechanism has been proposed. Importantly, the potential for asymmetric gallium(I) catalysis has been demonstrated using a chiral silver co-catalyst (40% ee). This gallium(I) chemistry has proved to be applicable to the catalytic activation of other electrophiles, including ethers or aldehydes, and pro-nucleophiles such as boranes, silanes, or tin-based reagents. Finally, the potential of a related low-oxidation aluminium catalyst has been explored for C–C bond formation.

546

Studies on Design of 3d Transition Metal Lewis Acid Catalysts for Efficient Activation of Aldehydes and Imines / アルデヒド及びイミンの高活性化を志向した3d遷移金属ルイス酸触媒の設計に関する研究

Tomifuji, Rei

23 March 2020

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第22454号 / 工博第4715号 / 新制||工||1736(附属図書館) / 京都大学大学院工学研究科材料化学専攻 / (主査)教授 松原 誠二郎, 教授 杉野目 道紀, 教授 中尾 佳亮 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Lewis acid

Asymmetric catalysis

Fe

reaction mechanism

500

Asymmetric Multicomponent Aza-Diels-Alder Reaction for Construction of Multicyclic Heterocycles and Development of XZH-5 Derivatives as Inhibitors of Signal Transducer and Activator of Transcription 3 (STAT3)

Csatary, Erika Elizabeth

13 July 2015

No description available.

Chemistry

asymmetric catalysis

enamines

Lewis acids

STAT3 inhibitors

TheSynthetic Applications of 1,4-Hydrogen Atom Abstraction via Co(II)-Based Metalloradical Catalysis:

Xie, Jingjing

January 2022

Thesis advisor: Peter X. Zhang / Thesis advisor: James P. Morken / Radical reactions have attracted continuous research interest in recent year considering their diverse reactivities. Hydrogen-atom abstraction (HAA), as one type of the most well-explored radical reactions, has been identified as one of powerful tools for C–H functionalization. Reactions involving 1,4-HAA, which is typically a challenging process both entropically and enthalpically, are rather scarce, while 1,5-HAA have been well demonstrated for variety of synthetic applications. Guided by the concept of metalloradical catalysis (MRC), 1,4-HAA was for the first time utilized as the key step to achieve asymmetric construction of chiral ring structures: cyclobutanones, azetidines and tetrahydropyridines. The design of different D2-symmetric chiral amidoporphyrin as the supporting ligand is the key to all these transformations. The reactions can be conducted under mild conditions, affording corresponding ring structure in good yields with excellent selectivity. Furthermore, The combined computational and experimental studies have shed light on the mechanistic details of these new asymmetric radical intramolecular C–H alkylation processes, which are fundamentally different from existing catalytic systems involving metallocarbenes for concerted C–H insertion. We envision that these asymmetric radical processes via Co(II)-based MRC could become an alternative method for important chiral ring structures synthesis and potentially provide new opportunities for complex molecule construction. / Thesis (PhD) — Boston College, 2022. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

14-Hydrogen Atom Abstraction

Asymmetric Catalysis

Metalloradical Catalysis

Methodology Development

Conformationally Controlled Chiral Phenanthrolines for Asymmetric Catalysis

Dotsenko, Irina

01 January 2014

Asymmetric catalysis is vitally important for modern organic chemistry. However, many chiral catalysts are readily available only in a single absolute configuration. This often prevents practical access to both enantiomers of a product. To address this shortcoming, we propose a novel type of accessible ligands based on the structure of trans-5,6-disubstituted-5,6-dihydro-1,10-phenanthroline. Conformers of this molecule have opposite twist in the bipyridine fragment (opposite helicity or axial chirality). Thus, a relative stabilization of one or the other conformer of the same chiral precursor could potentially give access to two ligands with opposite axial chirality and hence to two catalysts with opposite enantioselectivity. We proposed structural modifications of substituents attached to 5,6-dihydro-1,10- phenanthroline as a convenient and reliable approach for stabilization of one or another conformer. To validate this strategy, multiple oxygen- and sulfur-substituted ligands were synthesized and fully characterized. In particular, their conformational behavior was studied by 1H NMR. Some ligands and their metal complexes were designed and proved to be conformationally (axially) constrained. Chiral resolution of these ligands through separation of their diastereomeric derivatives was accomplished, resulting in material of high optical purity. The absolute configuration of chiral elements (centers and axis) were established by 1H NMR, CD and X-ray analysis. Metal complexes with a range of novel chiral 5,6-dihydro-1,10-phenanthrolines were assessed as chiral catalysts for the asymmetric alkylation of aldehydes, Henry reaction and allylic substitution. Moderate to high activities were achieved in all catalytic transformations while low to moderate degree of enantioselectivity was observed. The results of asymmetric catalysis confirmed the crucial role of the twist in the ligand’s bipyridine moiety (of its sign and magnitude) in the induction of stereoselectivity. Exploring an undesired aromatization of products in cleavage of 5,6-epoxy-5,6- dihydro-1,10-phenanthroline with various thiols in presence of base, we developed a new simple procedure and synthesized a broad library of novel valuable ligands: 5-aryl(alkyl)sulfanyl-1,10-phenanthrolines and bis(1,10-phenanthrolines). Other functional groups attached to the thiol moiety allow using these products as building blocks for versatile ligands and in functionalization of surfaces. Besides, the new sulfur- substituted derivatives were found to be potent modulators of fungal glycosidases.

Pure sciences

asymmetric catalysis

Bipyridine fragment

Chiral catalysts

Organic chemistry