Please use this identifier to cite or link to this item: http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/8584
Title: Urea-Tethered Porous Organic Polymer (POP) as an Efficient Heterogeneous Catalyst for Hydrogen Bond Donating Organocatalysis and Continuous Flow Reaction
Authors: DAM, GOURAB K.
LET, SUMANTA
JAISWAL, VARTIKA
GHOSH, SUJIT K.
Dept. of Chemistry
Keywords: Catalysts
Chemical reactions
Condensation
Indoles
Urea
2024
2024-MAR-WEEK1
TOC-MAR-2024
Issue Date: Feb-2024
Publisher: American Chemical Society
Citation: ACS Sustainable Chemistry & Engineering, 12(08), 3000–3011.
Abstract: Hydrogen bond donating (HBD) heterogeneous organocatalysis has come to light as a powerful surrogate to Lewis acid activation toward manufacturing biologically important C–C bonds. Notwithstanding the emergence of urea as a functionally diverse moiety to drive homogeneous HBD reactions, its catalytic competency is often muted by self-quenching behavior. Keeping this in perspective, spatial isolation of catalytically active urea functionality inside a porous framework can alleviate this pitfall, rendering a potential solution. The current work reports the fabrication of a porous urea network (IPpop-1) as a superior heterogeneous HBD catalyst toward Friedel–Crafts alkylation of β-nitrostyrene and indole (yield up to 99%) under mild conditions advocating green chemistry. Experimental evidence that supports the critical step of the catalytic reaction leading to a plausible mechanism was unveiled along with theoretical assistance. Additionally, the versatile bifunctional nature of the catalyst was established from its competence in catalyzing multicomponent Knoevenagel-Michael condensation as well as cyanosilylation reactions efficiently. One-pot cascade catalysis was also achieved under milder reaction conditions with excellent product yields exploiting the dual active sites of IPpop-1. Pertaining to practicality, spherical composite beads were fabricated to perform continuous flow multicomponent Knoevenagel-Michael condensation without compromising the catalytic activity of IPpop-1. Furthermore, regeneration of the spent catalyst (up to 10 cycles) and scalability combined with wide substrate tolerance manifested conceptual feasibility of the polymer catalyst.
URI: https://doi.org/10.1021/acssuschemeng.3c06108
http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/8584
ISSN: 2168-0485
Appears in Collections:JOURNAL ARTICLES

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