Stereoselective Oxidative Mannich Reaction of Ketones with Dihydrodibenzo-Oxazepines via a Merger of Photoredox-/Electro-Catalysis with Organocatalysis

The formation reaction of a carbon-carbon bond promoted by Eosin-Y under visible light

In recent years, photochemical organic conversion promoted by visible light has attracted the interest of many organic chemists. Compared with traditional methods, visible light for the photoredox catalysis of renewable energy has been proved to be a mild and powerful tool that can promote the activation of organic molecules through the single electron transfer (SET) process. Therefore, the formation reaction of a C-C bond can be achieved by activating these molecules with visible light, which can effectively modify the structure of these compounds and obtain compounds with multiple structures and functions. At present, this research has become an important research field in organic synthesis. Eosin-Y, a cheap and widely-used organic dye, has been employed as an economically and environmentally friendly substitute for many transition-metal-based photocatalysts. In recent years, it has gained much more attention due to its ease of handling and eco-friendliness, and it has great potential for applications in visible-light-mediated organic synthesis. This article reviews the research results on the formation of carbon-carbon bonds promoted by the organic photocatalyst Eosin-Y under visible light in recent years, and discusses representative examples and their different mechanistic pathways (such as SET, HAT, and energy transfer).

Visible-Light-Induced α-Arylation of Ketones with (Hetero)aryl Halides

An enamine-mediated photoredox catalyzed C(sp2)-C(sp3) cross-coupling of dual radical precursors for the arylation of ketone is presented in this Letter. These reactions led to the formation of an enamine by using pyrrolidine to functionalize the C(sp3)-H bond in ketone substrates, which could be smoothly converted to α-arylated ketones with inert aryl bromides and even aryl chlorides in moderate to good yields under mild reaction conditions. The photocatalytically induced C(sp2)-C(sp3) cross-coupling between unactivated noncyclic ketones and aryl halides was achieved, and multiple carbonyl α-arylated backbones containing various natural products and drug molecules were successfully constructed.

A tutorial on asymmetric electrocatalysis

Electrochemistry has emerged as a powerful means to enable redox transformations in modern chemical synthesis. This tutorial review delves into the unique advantages of electrochemistry in the context of asymmetric catalysis. While electrochemistry has historically been used as a green and mild alternative for established enantioselective transformations, in recent years asymmetric electrocatalysis has been increasingly employed in the discovery of novel asymmetric methodologies based on reaction mechanisms unique to electrochemistry. This tutorial review first provides a brief tutorial introduction to electrosynthesis, then explores case studies on homogenous small molecule asymmetric electrocatalysis. Each case study serves to highlight a key advance in the field, starting with the historic electrification of known asymmetric transformations and culminating with modern methods relying on unique electrochemical mechanistic sequences. Finally, we highlight case studies in the emerging reasearch areas at the interface of asymmetric electrocatalysis with biocatalysis and heterogeneous catalysis.

Electro-Oxidative Synthesis of Phenazines

We disclose herein electro-oxidative synthesis as the general protocol for procuring phenazines under mild reaction conditions. Using aerial oxygen as an oxidant, inexpensive electrolyte, and electrodes, a diverse range of phenazines have been accessed in good yields via the ring contraction of 10,11-dihydro-5H-dibenzo[b,e][1,4]diazepines. In addition, the syntheses of phenazines and diamino phenazines via direct electro-oxidation of dihydrophenazines and electro-dimerization of o-phenylenediamines, respectively, have also been accomplished.