Formation of N-H and N-C bonds from functionalization of N2 is a potential route to utilization of this abundant resource. One of the key challenges is to make the products of N2 activation reactive enough to undergo further reactions under mild conditions. This paper explores the strategy of "alkali control," where the presence of an alkali metal cation enables the reduction of N2 under mild conditions, and then chelation of the alkali metal cation uncovers a highly reactive species that can break benzylic C-H bonds to give new N-H and Fe-C bonds. The ability to "turn on" this C-H activation pathway with 18-crown-6 is demonstrated with three different N2 reduction products of N2 cleavage in an iron-potassium system. The alkali control strategy can also turn on an intermolecular reaction of an N2-derived nitride with methyl tosylate that gives a new N-C bond. Since the transient K(+)-free intermediate reacts with this electrophile but not with the weak C-H bonds in 1,4-cyclohexadiene, it is proposed that the C-H cleavage occurs by a deprotonation mechanism. The combined results demonstrate that a K(+) ion can mask the latent nucleophilicity of N2-derived nitride and imide ligands within a trimetallic iron system and points a way toward control over N2 functionalization.
Formation of N-H and N-C bonds from functionalization of N2 is a potential route to utilization of this abundant resource. One of the key challenges is to make the products of n class="Chemical">N2 activation reactive enough to undergo further reactions under mild conditions. This paper explores the strategy of "alkali control," where the presence of an alkali metal cation enables the reduction of N2 under mild conditions, and then chelation of the alkali metal cation uncovers a highly reactive species that can break benzylic C-H bonds to give new N-H and Fe-C bonds. The ability to "turn on" this C-H activation pathway with 18-crown-6 is demonstrated with three different N2 reduction products of N2 cleavage in an iron-potassium system. The alkali control strategy can also turn on an intermolecular reaction of an N2-derived nitride with methyl tosylate that gives a new N-C bond. Since the transient K(+)-free intermediate reacts with this electrophile but not with the weak C-H bonds in 1,4-cyclohexadiene, it is proposed that the C-H cleavage occurs by a deprotonation mechanism. The combined results demonstrate that a K(+) ion can mask the latent nucleophilicity of N2-derived nitride and imide ligands within a trimetalliciron system and points a way toward control over N2 functionalization.
Authors: Sean F McWilliams; Eckhard Bill; Gudrun Lukat-Rodgers; Kenton R Rodgers; Brandon Q Mercado; Patrick L Holland Journal: J Am Chem Soc Date: 2018-06-29 Impact factor: 15.419
Authors: Shaoguang Zhang; Peng Cui; Tianchang Liu; Qiuran Wang; Thomas J Longo; Laura M Thierer; Brian C Manor; Michael R Gau; Patrick J Carroll; Georgia C Papaefthymiou; Neil C Tomson Journal: Angew Chem Int Ed Engl Date: 2020-06-09 Impact factor: 15.336
Authors: Daniël L J Broere; Brandon Q Mercado; James T Lukens; Avery C Vilbert; Gourab Banerjee; Hannah M C Lant; Shin Hee Lee; Eckhard Bill; Stephen Sproules; Kyle M Lancaster; Patrick L Holland Journal: Chemistry Date: 2018-06-07 Impact factor: 5.236
Authors: Polly L Arnold; Tatsumi Ochiai; Francis Y T Lam; Rory P Kelly; Megan L Seymour; Laurent Maron Journal: Nat Chem Date: 2020-05-04 Impact factor: 24.427
Authors: Brian M Lindley; Richt S van Alten; Markus Finger; Florian Schendzielorz; Christian Würtele; Alexander J M Miller; Inke Siewert; Sven Schneider Journal: J Am Chem Soc Date: 2018-06-19 Impact factor: 15.419
Authors: Sean F McWilliams; Daniël L J Broere; Connor J V Halliday; Samuel M Bhutto; Brandon Q Mercado; Patrick L Holland Journal: Nature Date: 2020-08-12 Impact factor: 49.962