Supramolecular Ensemble of a TICT-AIEE Active Pyrazine Derivative and CuO NPs: A Potential Photocatalytic System for Sonogashira Couplings

Deol, Harnimarta; Pramanik, Subhamay; Kumar, M.; Khan, Imran A.

doi:10.1021/acscatal.6b00393

Cited by 58 publications

(27 citation statements)

References 69 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Heterogeneous catalysts are important owing to their recyclability and easy separation/recovery, especially in industrial applications. Recently, a few reports demonstrated the feasibility of photoinduced heterogeneous catalysis for Sonogashira cross‐coupling at room temperature, such as: a) using a supramolecular ensemble of a twisted intramolecular charge‐transfer states aggregation‐induced emission enhancement (TICT‐AIEE) active pyrazine and CuO nanoparticles (Scheme b); b) a silicon carbide‐supported Pd–Cu alloy (Pd 3 Cu 1 /SiC) or TiO 2 supported palladium NPs (Pd@TiO 2 ) (Scheme c); and c) TiO 2 ‐supported CuO bimetallic photocatalysts (Scheme d), for which cocatalysis of Ti to Cu ions is required for the coupling reactions to occur . Despite increased attention, most heterogeneous NP‐based catalysts still have some limitations.…”

Section: Methodssupporting

confidence: 87%

Cu₂O Nanocrystals‐Catalyzed Photoredox Sonogashira Coupling of Terminal Alkynes and Arylhalides Enhanced by CO₂

et al. 2019

View full text Add to dashboard Cite

Herein the first visible-light-activated Sonogashira CÀCc oupling reaction at room temperature catalyzed by single-metal heterogeneous Cu 2 Ot runcated nanocubes (Cu 2 OT NCs) was developed. Aw ide varietyo fa ryl halidesa nd terminal alkynes workedw ell in this recyclable heterogeneous photochemical process to form the corresponding Sonogashira CÀCc oupling products in good yields. Mechanistic control studies indicated that CO 2 enhances the formation of light-absorbing heterogeneous surface-bound Cu I -phenylacetylide (l max = 472 nm), which further undergoes single-electron transfer with aryl iodides/bromides to enable Sonogashira C sp 2ÀC sp bond formation. In contrastt ol iterature-reported bimetallic TiO 2 -containing nanoparticles as photocatalyst, this work avoided the need of cocatalysis by TiO 2 .S ingle-metalC u I in Cu 2 OT NCs wass olely responsible for the observed C sp 2ÀC sp couplingr eactions under CO 2 atmosphere.The Sonogashira coupling reactioniso ne of the most powerful and straightforwardm ethods forc onstruction of aryl alkynes/conjugated alkynes through C sp 2À C sp cross-coupling of aryl/alkenyl halidesa nd terminal alkynes, which are the most substantial intermediates in the synthesis of natural products as well as pharmaceutical, polymeric, and organic materials. [1] In such transformations, conventional methodologies involvet he use of palladiump hosphine complexes along with copper as ac ocatalyst in the presence of excess organic amine bases (Scheme 1a). [2] However, these methodso ften requiree xpensive Pd catalysts and Cu salts as cocatalyst with excessive ligands/ amines or harsh thermal conditions. Recently,a number of reports have demonstrated different modifications in ac atalytic fashion, [3] such as a) Cufree Pd-catalytic systems, [3a-d] b) Pd-free Fe-, Ni-, or Cu-complexes, [3e,f] and c) Cu-catalystsw ith ligandsu nder harsh conditions. [3g] Among them,P d-free copper-catalyzed Sonoga-shira cross-couplings are the predominant inexpensive protocols for constructing conjugated alkynes, [3d, 4, 5] However,t he usage of excessl igands and the harsh thermalr eaction conditions diminish their merits.To addresst he above challenges, we previously reported visible-light-triggered CuCl-catalyzed Sonogashira crosscoupling between aryl halides and terminal alkynes at room temperature. [6] We envisioned that the CÀCc oupling reactions can be initiated by photoexcited copper(I)-phenylacetylide that undergoes as ingle-electron transfer (SET) process with ground-state aryl halidesv ia inner-coordination sphere to initiate the CÀCc oupling reactionu pon visible-light irradiation. We questioned whether it is possible to replace the molecular CuCl catalystw ith recyclable solid copper-containing nanoparticles (NPs) for the Sonogashira C sp 2ÀC sp cross-coupling reactions between aryl halides and terminal alkynes under visiblelight irradiation at room temperature. Such recyclableh eterogeneous photocatalysts are highly desirable for Sonogashira coupling reactions and remainunexplored in th...

show abstract

Section: Methodssupporting

confidence: 87%

Cu₂O Nanocrystals‐Catalyzed Photoredox Sonogashira Coupling of Terminal Alkynes and Arylhalides Enhanced by CO₂

et al. 2019

View full text Add to dashboard Cite

show abstract

“…Thus,wedesigned and synthesized pyrazine derivative 1 which has l-alanine moieties as the chiral handle and amide linkages as binding units.Wechose pyrazine as ascaffold because of its known potential to form fluorescent aggregates through p-p intermolecular stacking and the hydrophobic effect in an aggregated state in aqueous media. [19] Derivative 1 undergoes self-assembly to generate fluorescent helical fibers in aqueous media and the alanine groups can transfer chirality in the aggregated state.T he as-prepared helical fibers exhibit as elective affinity towards Ni 2+ ions,a nd the co-assembly of helical fibers and Ni 2+ ions results in ac hirality transformation. Fortunately,c hirality inversion was accompanied by further aggregation of the helical fibers to generate as upercoiled 1:Ni 2+ ensemble.…”

Section: Introductionmentioning

confidence: 99%

Entropically Favoured Assembly of Pyrazine‐Based Helical Fibers into Superstructures: Achiral/ Chiral Guest‐Induced Chirality Transformation

2019

Self Cite

View full text Add to dashboard Cite

The development of synthetic helical structures undergoing stimuli-responsive chirality transformations is important for an understanding of the role of chirality in natural systems.However,controlling supramolecular chirality in entropically driven assemblies in aqueous media is challenging.T odevelop stimuli-responsive assemblies,wedesigned and synthesized pyrazine derivatives with l-alanine groups as chiral building blocks.These systems undergo self-assembly in aqueous media to generate helical fibers and the embedded alanine groups transfer their chirality to the assembled structures.F urthermore,t hese helical fibers undergo aN i 2+induced chirality transformation. The study demonstrates the role of intermolecular hydrogen bonding, p-p stacking,a nd the hydrophobic effect in the Ni 2+ -mediated transition of helical fibers to supercoiled helical ensembles which mimic the formation of superstructures in biopolymers. Figure 13. a) TEM image of the 1:Ni 2+ :d-histidines uperhelix in aqueous media. b) TEM image showing alamellar morphology.

show abstract

“…However, poor recyclability of this noble‐metal free photocatalyst for the Suzuki coupling reaction was found that the yield was decreased by 30 % after 4 recycles. Also, they prepared other noble‐metal free photocatalyst for visible light photocatalyzed Sonogashira C−C cross coupling . The photocatalyst was composed of TICT‐AIEE active pyrazine derivative and CuO nanoparticles, which exhibited excellent catalytic efficiency in Sonogashira couplings under mild conditions with a wide variety of substrates.…”

Section: Pd Free Photocatalysts For Visible‐light C−c Cross‐coupling mentioning

confidence: 99%

Heterogeneous Photocatalyzed C−C Cross‐coupling Reactions Under Visible‐light and Near‐infrared Light Irradiation

Jia

Long

et al. 2018

ChemCatChem

View full text Add to dashboard Cite

With the development of photocatalytic technology and organic synthesis chemistry, the photocatalyzed cross‐coupling reaction provides one of the most attractive methodologies for the C−C bond formation and has been booming in recent years. The advantages of the heterogeneous photocatalyzed C−C cross‐coupling reaction lie in its environment friendly, easily separated and conveniently recovered catalysts. In this review, we summarized and highlighted recent achievements of heterogeneous photocatalyzed C−C cross‐coupling reactions through four aspects: visible light induced C−C cross‐coupling reactions catalyzed by Pd supported semiconductor photocatalysts; visible light induced C−C cross‐coupling reactions catalyzed by Pd based plasmonic photocatalysts; visible light induced C−C cross‐coupling reactions catalyzed by palladium‐free photocatalysts; near‐infrared light induced C−C cross‐coupling reactions.

show abstract

Supramolecular Ensemble of a TICT-AIEE Active Pyrazine Derivative and CuO NPs: A Potential Photocatalytic System for Sonogashira Couplings

Cited by 58 publications

References 69 publications

Cu₂O Nanocrystals‐Catalyzed Photoredox Sonogashira Coupling of Terminal Alkynes and Arylhalides Enhanced by CO₂

Cu₂O Nanocrystals‐Catalyzed Photoredox Sonogashira Coupling of Terminal Alkynes and Arylhalides Enhanced by CO₂

Entropically Favoured Assembly of Pyrazine‐Based Helical Fibers into Superstructures: Achiral/ Chiral Guest‐Induced Chirality Transformation

Heterogeneous Photocatalyzed C−C Cross‐coupling Reactions Under Visible‐light and Near‐infrared Light Irradiation

Contact Info

Product

Resources

About

Supramolecular Ensemble of a TICT-AIEE Active Pyrazine Derivative and CuO NPs: A Potential Photocatalytic System for Sonogashira Couplings

Cited by 58 publications

References 69 publications

Cu2O Nanocrystals‐Catalyzed Photoredox Sonogashira Coupling of Terminal Alkynes and Arylhalides Enhanced by CO2

Cu2O Nanocrystals‐Catalyzed Photoredox Sonogashira Coupling of Terminal Alkynes and Arylhalides Enhanced by CO2

Entropically Favoured Assembly of Pyrazine‐Based Helical Fibers into Superstructures: Achiral/ Chiral Guest‐Induced Chirality Transformation

Heterogeneous Photocatalyzed C−C Cross‐coupling Reactions Under Visible‐light and Near‐infrared Light Irradiation

Contact Info

Product

Resources

About

Cu₂O Nanocrystals‐Catalyzed Photoredox Sonogashira Coupling of Terminal Alkynes and Arylhalides Enhanced by CO₂

Cu₂O Nanocrystals‐Catalyzed Photoredox Sonogashira Coupling of Terminal Alkynes and Arylhalides Enhanced by CO₂