Bio‐inspired Small Molecular Catalysis

Cai, Mao-cheng; Yang, Chunming; Luo, Sanzhong

doi:10.1002/cjoc.202200628

Cited by 9 publications

(6 citation statements)

References 152 publications

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“…22,23 In the past few years, we have endeavored much effort in exploring primary amine-based synergistic catalysis. 24,25 One type of vicinal chiral primary−tertiary diamine catalyst has been found to work synergistically or cooperatively with a number of transition metal catalysts, such as Pd, Rh, Ag, Co, and Cu; as well as other organocatalysts, such as B(C 6 F 5 ) 3 , ketone, selenium, and iodide; photocatalysis; and electrochemical processes. In this unique "1 + x" synergistic scenario, the secondary enamine intermediate can be modulated with respect to all three major properties (Scheme 1I−III), by the joint force with its catalytic partners.…”

Section: Introductionmentioning

confidence: 99%

“…Both secondary and primary aminocatalysts have been widely examined and have proved to be viable for synergistic catalysis. , However, a single type of aminocatalyst able to incorporate all different synergistic strategies is still very rare. Previously, we reported chiral primary–tertiary vicinal diamines as a functional and mechanistic mimic of Type I aldolase. , In the past few years, we have endeavored much effort in exploring primary amine-based synergistic catalysis. , One type of vicinal chiral primary–tertiary diamine catalyst has been found to work synergistically or cooperatively with a number of transition metal catalysts, such as Pd, Rh, Ag, Co, and Cu; as well as other organocatalysts, such as B(C 6 F 5 ) 3 , ketone, selenium, and iodide; photocatalysis; and electrochemical processes. In this unique “1 + x ” synergistic scenario, the secondary enamine intermediate can be modulated with respect to all three major properties (Scheme I–III), by the joint force with its catalytic partners.…”

Section: Introductionmentioning

confidence: 99%

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Enantioselective Transformations by “1 + x” Synergistic Catalysis with Chiral Primary Amines

Cai,

Zhang,

Zhang

et al. 2024

Acc. Chem. Res.

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Metrics & MoreArticle Recommendations CONSPECTUS: Synergistic catalysis is a powerful tool that involves two or more distinctive catalytic systems to activate reaction partners simultaneously, thereby expanding the reactivity space of individual catalysis. As an established catalytic strategy, organocatalysis has found numerous applications in enantioselective transformations under rather mild conditions.Recently, the introduction of other catalytic systems has significantly expanded the reaction space of typical organocatalysis. In this regard, aminocatalysis is a prototypical example of synergistic catalysis. The combination of aminocatalyst and transition metal could be traced back to the early days of organocatalysis and has now been well explored as an enabling catalytic strategy. Particularly, the acid−base properties of aminocatalysis can be significantly expanded to include usually electrophiles generated in situ via metal-catalyzed cycles. Later on, aminocatalyst has also been exploited in synergistically combining with photochemical and electrochemical processes to facilitate redox transformations. However, synergistically combining one type of aminocatalyst with many different catalytic systems remains a great challenge. One of the most daunting challenges is the compatibility of aminocatalysts in coexistence with other catalytic species. As nucleophilic species, aminocatalysts may also bind with metal, which leads to mutual inhibition or even quenching of the individual catalytic activity. In addition, oxidative stability of aminocatalyst is also a nonneglectable issue, which causes difficulties in exploring oxidative enamine transformations.In 2007, we developed a vicinal diamine type of chiral primary aminocatalysts. This class of primary aminocatalysts was developed and evolved as functional and mechanistic mimics to the natural aldolase and has been widely applied in a number of enamine/ iminium ion-based transformations. By following a "1 + x" synergistic strategy, the chiral primary amine catalysts were found to work synergistically or cooperatively with a number of transition metal catalysts, such as Pd, Rh, Ag, Co, and Cu, or other organocatalysts, such as B(C 6 F 5 ) 3 , ketone, selenium, and iodide. Photocatalysis and electrochemical processes can also be incorporated to work together with the chiral primary amine catalysts. The 1 + x catalytic strategy enabled us to execute unexploited transformations by fine-tuning the acid−base and redox properties of the enamine intermediates and to achieve effective reaction and stereocontrol beyond the reach individually. During these efforts, an unprecedented excited-state chemistry of enamine was uncovered to make possible an effective deracemization process. In this Account, we describe our recent efforts since 2015 in exploring synergistic chiral primary amine catalysis, and the content is categorized according to the type of synergistic partner such that in each section the developed synergistic catalysis, reaction scopes, and mechanistic features...

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Enantioselective Transformations by “1 + x” Synergistic Catalysis with Chiral Primary Amines

Cai,

Zhang,

Zhang

et al. 2024

Acc. Chem. Res.

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“…Methyl acetate applications are limited and its economic value is moderate. [ 1 ] Therefore, many investigations are carried out to convert it to more valuable products of longer‐chain alkyl acetate. [ 1–9 ] Methyl acetate can be converted to other alkyl easters such as n ‐propyl acetate and n ‐butyl acetate that have more applications and higher economical value via transesterification reactions.…”

Section: Introductionmentioning

confidence: 99%

“…[ 1 ] Therefore, many investigations are carried out to convert it to more valuable products of longer‐chain alkyl acetate. [ 1–9 ] Methyl acetate can be converted to other alkyl easters such as n ‐propyl acetate and n ‐butyl acetate that have more applications and higher economical value via transesterification reactions. Although these alkyl acetates can be produced directly through esterification reactions, the transesterification path is considered mild and versatile in comparison to esterification.…”

Section: Introductionmentioning

confidence: 99%

Production of esters with numerous applications: Kinetics of Dowex 50W catalyzed transesterification of methyl acetate with three‐ and four‐carbon structured alcohols

Albusairi,

Almusallam,

Ali

et al. 2024

Can J Chem Eng

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In this investigation, a strongly acidic exchange resin was used for the transesterification of methyl acetate with n‐propanol, n‐butanol, and iso‐butanol. Kinetic and equilibrium experiments for the three systems were conducted using a temperature‐controlled batch reactor setup. The effects of the following operating parameters on the transesterification were explored: reaction temperature, catalyst loading, and methyl acetate‐to‐alcohol molar ratio. The conversion of the limiting reactant in the reaction mixture increased with increasing reaction temperature, catalyst loading, and varying reactant proportions from 1:1 to other ratios. It was found that excess methyl acetate would result in higher limiting reactant conversion than using excess alcohol with the same initial molar proportionality between the excess and the limiting reactants. It was found that an increase in the chain length of the alcohol and/or branching suppressed the conversion of the reactants owing to steric hindrance. To mathematically correlate the data, several kinetic models were tested, and the Eley–Rideal model was selected. Accordingly, a reaction mechanism was proposed.

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“…Previously, it is known that the reaction with singlet oxygen could be promoted by a favorable H-bonding . In our model, the protonated tertiary amine would direct Re -facial attack of enamine to 1 O 2 , which is also hydrogen-bonded by HFIP (Scheme , below). The dual hydrogen-bonding network would significantly enhance the polarity of 1 Δ g state of 1 O 2 , thus promote the nucleophilic C–O bond formation process.…”

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confidence: 99%

Visible Light-Promoted Enantioselective Aerobic Hydroxylation of β-Ketocarbonyls by Chiral Primary Amine Catalysis

Cai

Jia

et al. 2023

ACS Catal.

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Highly effective and stereoselective enamine-singlet oxygen coupling was achieved by synergistic chiral primary amine and photocatalysis in hexafluoroisopropanol. The current enamine catalysis enables α-hydroxylation of β-ketocarbonyls with good yields and high enantioselectivity across a broad range of substrates. Mechanistic studies revealed a direct participation of solvents in the critical enamine coupling step, and a solvent-1O2 H-bonding mode was invoked to account for the dramatic solvent effect.

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Bio‐inspired Small Molecular Catalysis

Cited by 9 publications

References 152 publications

Enantioselective Transformations by “1 + x” Synergistic Catalysis with Chiral Primary Amines

Enantioselective Transformations by “1 + x” Synergistic Catalysis with Chiral Primary Amines

Production of esters with numerous applications: Kinetics of Dowex 50W catalyzed transesterification of methyl acetate with three‐ and four‐carbon structured alcohols

Visible Light-Promoted Enantioselective Aerobic Hydroxylation of β-Ketocarbonyls by Chiral Primary Amine Catalysis

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