Litcius/Paper detail

Spontaneous Catalytic Paal–Knorr Reactions for <i>N</i>-Substituted Pyrrole Synthesis by Microdroplet Chemistry

Jiayao Li, Jiannan Sun, Yizhou Wang, Jinhua Liu, Heyong Cheng

2024ACS Sustainable Chemistry & Engineering15 citationsDOI

Abstract

It is well recognized in recent studies that water molecules at the gas–liquid interface of microdroplets spontaneously dissociate into hydronium and hydroxide and form superacids/superbases and reactive species (hydrated electrons, hydroxide radicals, hydrogen peroxide, water radical cations/anions, etc.) due to the 10 9 V m –1 electric field. In contrast to extensive interest in spontaneous redox reactions by the reactive species in microdroplet studies, limited attention has been attracted by gram-scale organic synthesis catalyzed by the spontaneously formed superacids/superbases. This study demonstrates spontaneous organic catalysis of the superacids for Paal–Knorr reactions, one of the most classic pathways to construct N -substituted pyrroles with biologically and pharmaceutically important roles. Paal–Knorr reactions can proceed well with no external catalysts in isopropanol microdroplets within 10 min at room temperature. Sixteen N -substituted pyrroles were synthesized using the microdroplet method with 83–99% yields, several orders of magnitude reaction acceleration (a typical rate acceleration factor of 1.18 × 10 3 based on the ratio of the rate constants), and a scale-up rate of 5.50 g h –1 . By avoiding external catalysts, thermal irradiation, long reaction times, and problematic solvents required by conventional Paal–Knorr methods, the microdroplet method was a green, efficient, and attractive alternative for the construction of pyrroles and their derivatives.

Topics & Concepts

CatalysisChemistryHydroxideRadicalRedoxHydrogen peroxidePhotochemistryHydroniumPyrroleOrganic chemistryInorganic chemistryMoleculeSynthesis and Characterization of PyrrolesFluorine in Organic ChemistryOrganic and Inorganic Chemical Reactions
Spontaneous Catalytic Paal–Knorr Reactions for <i>N</i>-Substituted Pyrrole Synthesis by Microdroplet Chemistry | Litcius