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Ammonia Synthesis at Room Temperature and Atmospheric Pressure from N<sub>2</sub>: A Boron‐Radical Approach

Soukaina Bennaamane, Barbara Rialland, Lhoussain Khrouz, Marie Fustier‐Boutignon, Christophe Bucher, Eric Clot, Nicolas Mézailles

2022Angewandte Chemie International Edition53 citationsDOIOpen Access PDF

Abstract

Abstract Ammonia, NH 3 , is an essential molecule, being part of fertilizers. It is currently synthesized via the Haber–Bosch process, from the very stable dinitrogen molecule, N 2 and dihydrogen, H 2 . This process requires high temperatures and pressures, thereby generating ca 1.6 % of the global CO 2 emissions. Alternative strategies are needed to realize the functionalization of N 2 to NH 3 under mild conditions. Here, we show that boron‐centered radicals provide a means of activating N 2 at room temperature and atmospheric pressure whilst allowing a radical process to occur, leading to the production of borylamines. Subsequent hydrolysis released NH 4 + , the acidic form of NH 3 . EPR spectroscopy supported the intermediacy of radicals in the process, corroborated by DFT calculations, which rationalized the mechanism of the N 2 functionalization by R 2 B radicals.

Topics & Concepts

AmmoniaBoronAtmospheric pressureAmmonia productionChemistryInorganic chemistryMaterials sciencePhotochemistryMeteorologyOrganic chemistryPhysicsAmmonia Synthesis and Nitrogen ReductionHydrogen Storage and MaterialsInorganic Fluorides and Related Compounds
Ammonia Synthesis at Room Temperature and Atmospheric Pressure from N<sub>2</sub>: A Boron‐Radical Approach | Litcius