Abstract
The direct synthesis of amides and nitriles from readily available aldehyde precursors provides access to functional groups of major synthetic utility. To date, most reliable catalytic methods have typically been optimized to supply one product exclusively. Herein, we describe an approach centered on an operationally simple iron-based system that, depending on the reaction conditions, selectively addresses either the C═O or C–H bond of aldehydes. This way, two divergent reaction pathways can be opened to furnish both products in high yields and selectivities under mild reaction conditions. The catalyst system takes advantage of iron’s dual reactivity capable of acting as (1) a Lewis acid and (2) a nitrene transfer platform to govern the aldehyde building block. The present transformation offers a rare control over the selectivity on the basis of the iron system’s ionic nature. This approach expands the repertoire of protocols for amide and nitrile synthesis and shows that fine adjustments of the catalyst system’s molecular environment can supply control over bond activation processes, thus providing easy access to various products from primary building blocks.
Highlights
Nature’s biological instruments can operate countless parallel processes with incomparable levels of efficiency.1 This chemical machinery demonstrates that, despite a complex reaction medium with numerous prospective reaction partners, precise control over the bond activation processes and catalytic sequences can be achieved, furnishing products in high selectivity
Responsive systems may modulate their activity based on external stimuli;5 in contrast, adaptive catalysts may change their chemical reactivity in response to the reaction conditions, and components, to generate different products.3e Here, reaction parameters are combined rather than isolated, and their function and interactions are studied within the entire system
On the basis of these considerations, we developed an operationally simple iron-based system that, depending on the reaction conditions, offers control over C O versus C−H bond activation in aldehydes to convert a broad substrate scope to the desired amide and nitrile products in excellent yields under mild reaction conditions (Scheme 1, panel D)
Summary
Basujit Chatterjee,# Soumyashree Jena,# Vishal Chugh, Thomas Weyhermüller, and Christophe Werlé*. Downloaded via 54.234.143.241 on February 8, 2022 at 09:50:08 (UTC). See https://pubs.acs.org/sharingguidelines for options on how to legitimately share published articles
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