Pattanayak Santanu, Chowdhury Debarati Roy, Garai Bikash, Singh Kundan K, Paul Amit, Dhar Basab B, Gupta Sayam Sen
Chemical Engineering and Process Development Division, CSIR-National Chemical Laboratory, Dr. HomiBhabha Road, Pune, 411008, India.
Department of Chemistry, Indian Institute of Science Education and Research (IISER), Bhopal, MP, 462066, India.
Chemistry. 2017 Mar 8;23(14):3414-3424. doi: 10.1002/chem.201605061. Epub 2017 Feb 14.
A detailed electrochemical investigation of a series of iron complexes (biuret-modified tetraamido iron macrocycles Fe -bTAML), including the first electrochemical generation of Fe (O), and demonstration of their efficacy as homogeneous catalysts for electrochemical water oxidation (WO) in aqueous medium are reported. Spectroelectrochemical and mass spectral studies indicated Fe (O) as the active oxidant, formed due to two redox transitions, which were assigned as Fe (O)/Fe (OH ) and Fe (O)/Fe (O). The spectral properties of both of these high-valent iron oxo species perfectly match those of their chemically synthesised versions, which were thoroughly characterised by several spectroscopic techniques. The O-O bond-formation step occurs by nucleophilic attack of H O on Fe (O). A kinetic isotope effect of 3.2 indicates an atom-proton transfer (APT) mechanism. The reaction of chemically synthesised Fe (O) in CH CN and water was directly probed by electrochemistry and was found to be first-order in water. The pK value of the buffer base plays a critical role in the rate-determining step by increasing the reaction rate several-fold. The electronic effect on redox potential, WO rates, and onset overpotential was studied by employing a series of iron complexes. The catalytic activity was enhanced by the presence of electron-withdrawing groups on the bTAML framework. Changing the substituents from OMe to NO resulted in an eightfold increase in reaction rate, while the overpotential increased threefold.
报道了对一系列铁配合物(缩二脲修饰的四酰胺基铁大环Fe-bTAML)进行的详细电化学研究,包括首次电化学生成Fe(O),并证明了它们在水性介质中作为电化学水氧化(WO)均相催化剂的功效。光谱电化学和质谱研究表明Fe(O)是活性氧化剂,由两个氧化还原转变形成,这两个转变被指定为Fe(O)/Fe(OH)和Fe(O)/Fe(O)。这两种高价铁氧物种的光谱性质与它们化学合成版本的光谱性质完全匹配,化学合成版本已通过多种光谱技术进行了全面表征。O-O键形成步骤是通过H₂O对Fe(O)的亲核攻击发生的。3.2的动力学同位素效应表明存在原子-质子转移(APT)机制。通过电化学直接探测了化学合成的Fe(O)在CH₃CN和水中的反应,发现该反应对水为一级反应。缓冲碱的pK值在速率决定步骤中起着关键作用,它使反应速率提高了几倍。通过使用一系列铁配合物研究了电子对氧化还原电位、WO速率和起始过电位的影响。bTAML骨架上吸电子基团的存在增强了催化活性。将取代基从OMe改为NO₂导致反应速率提高了八倍,而过电位增加了三倍。
