How Does Tunneling Contribute to Counterintuitive H-Abstraction Reactivity of Nonheme Fe(IV)O Oxidants with Alkanes?

• Published in: Journal of the American Chemical Society Vol. 137; no. 2; pp. 722 - 733
• Main Authors: Mandal, Debasish, Ramanan, Rajeev, Usharani, Dandamudi, Janardanan, Deepa, Wang, Binju, Shaik, Sason
• Format: Journal Article
• Language: English
• Published: United States American Chemical Society 21.01.2015
• Subjects: alkanes; Alkanes - chemistry; ambient temperature; chemical bonding; Hydrogen - chemistry; iron; Iron - chemistry; Kinetics; ligands; Models, Molecular; Molecular Conformation; Oxidants; Oxygen - chemistry; phosphine; prediction; Quantum Theory
• ISSN: 0002-7863; 1520-5126; 1520-5126
• DOI: 10.1021/ja509465w

This article addresses the intriguing hydrogen-abstraction (H-abstraction) and oxygen-transfer (O-transfer) reactivity of a series of nonheme [FeIV(O)(TMC)(Lax)]z+ complexes, with a tetramethyl cyclam ligand and a variable axial ligand (Lax), toward three substrates: 1,4-cyclohexadiene, 9,10-dihydroanthracene, and triphenyl phosphine. Experimentally, O-transfer-reactivity follows the relative electrophilicity of the complexes, whereas the corresponding H-abstraction-reactivity generally increases as the axial ligand becomes a better electron donor, hence exhibiting an antielectrophilic trend. Our theoretical results show that the antielectrophilic trend in H-abstraction is affected by tunneling contributions. Room-temperature tunneling increases with increase of the electron donation power of the axial-ligand, and this reverses the natural electrophilic trend, as revealed through calculations without tunneling, and leads to the observed antielectrophilic trend. By contrast, O-transfer-reactivity, not being subject to tunneling, retains an electrophilic-dependent reactivity trend, as revealed experimentally and computationally. Tunneling-corrected kinetic-isotope effect (KIE) calculations matched the experimental KIE values only if all of the H-abstraction reactions proceeded on the quintet state (S = 2) surface. As such, the present results corroborate the initially predicted two-state reactivity (TSR) scenario for these reactions. The increase of tunneling with the electron-releasing power of the axial ligand, and the reversal of the “natural” reactivity pattern, support the “tunneling control” hypothesis (Schreiner et al., ref ). Should these predictions be corroborated, the entire field of C–H bond activation in bioinorganic chemistry would lay open to reinvestigation.