The reaction of soluble iron-oxygen-potassium assemblies with N2 gives insight into the mechanisms of multimetallic N2 coordination. We report a series of very electron-rich three-coordinate, β-diketiminate-supported iron(I) phenoxide complexes, which are metastable but have been characterized under Ar by both crystallography and solution methods. Both monomeric and dimeric Fe-OPh-K compounds have been characterized, and their iron environments are very similar in the solid and solution states. In the dimer, potassium ions hold together the phenoxide oxygens and aryl rings of the two halves, to give a flexible diiron core. The reactions of the monomeric and dimeric iron(I) compounds with N2 are surprisingly different: the mononuclear iron(I) complexes give no reaction with N2, but the dimeric Fe2K2 complex reacts rapidly to give a diiron-N2 product. Computational studies show that the key to the rapid N2 reaction of the dimer is the preorganization of the two iron atoms. Thus, cooperation between Fe (which weakens the N-N bond) and K (which orients the Fe atoms) can be used to create a low-energy pathway for N2 reactions.
The reaction of soluble pan class="Chemical">iron-pan class="Chemical">oxygen-potassium assemblies with N2 gives insight into the mechanisms of multimetallic N2 coordination. We report a series of very electron-rich three-coordinate, β-diketiminate-supported iron(I) phenoxide complexes, which are metastable but have been characterized under Ar by both crystallography and solution methods. Both monomeric and dimeric Fe-OPh-K compounds have been characterized, and their iron environments are very similar in the solid and solution states. In the dimer, potassium ions hold together the phenoxideoxygens and aryl rings of the two halves, to give a flexible diiron core. The reactions of the monomeric and dimeric iron(I) compounds with N2 are surprisingly different: the mononuclear iron(I) complexes give no reaction with N2, but the dimeric Fe2K2 complex reacts rapidly to give a diiron-N2 product. Computational studies show that the key to the rapid N2 reaction of the dimer is the preorganization of the two iron atoms. Thus, cooperation between Fe (which weakens the N-N bond) and K (which orients the Fe atoms) can be used to create a low-energy pathway for N2 reactions.
Authors: Oliver Einsle; F Akif Tezcan; Susana L A Andrade; Benedikt Schmid; Mika Yoshida; James B Howard; Douglas C Rees Journal: Science Date: 2002-09-06 Impact factor: 47.728
Authors: Bettina Horn; Christian Limberg; Christian Herwig; Michael Feist; Stefan Mebs Journal: Chem Commun (Camb) Date: 2012-07-12 Impact factor: 6.222
Authors: Brett M Barney; Robert Y Igarashi; Patricia C Dos Santos; Dennis R Dean; Lance C Seefeldt Journal: J Biol Chem Date: 2004-10-01 Impact factor: 5.157
Authors: Jennifer Scott; Indu Vidyaratne; Ilia Korobkov; Sandro Gambarotta; Peter H M Budzelaar Journal: Inorg Chem Date: 2008-01-04 Impact factor: 5.165
Authors: John S Anderson; George E Cutsail; Jonathan Rittle; Bridget A Connor; William A Gunderson; Limei Zhang; Brian M Hoffman; Jonas C Peters Journal: J Am Chem Soc Date: 2015-06-10 Impact factor: 15.419
Authors: Megan E Reesbeck; Katarzyna Grubel; Daniel Kim; William W Brennessel; Brandon Q Mercado; Patrick L Holland Journal: Inorg Chem Date: 2017-01-09 Impact factor: 5.165