Erdivan Beyzanur, Calikyilmaz Eylul, Bilgin Suay, Erdali Ayse Dilay, Gul Damla Nur, Ercan Kerem Emre, Türkmen Yunus Emre, Ozensoy Emrah
Department of Chemistry, Faculty of Science, Bilkent University, 06800 Ankara, Türkiye.
Roketsan Inc., Elmadag, 06780 Ankara, Türkiye.
ACS Appl Mater Interfaces. 2024 Nov 6;16(44):60151-60165. doi: 10.1021/acsami.4c11070. Epub 2024 Oct 25.
A precious metal-free bimetallic FeMn(OH) hydroxide catalyst was developed that is capable of catalyzing aerobic C-H oxidation reactions at low temperatures, without the need for an initiator, relying sustainably on molecular oxygen. Through a systematic synthetic effort, we scanned a wide nanoparticle synthesis parameter space to lay out a detailed set of catalyst design principles unraveling how the Fe/Mn cation ratio, NaOH(aq) concentration used in the synthesis, catalyst washing procedures, extent of residual Na promoters on the catalyst surface, reaction temperature, and catalyst loading influence catalytic C-H activation performance as a function of the electronic, surface chemical, and crystal structure of FeMn(OH) bimetallic hydroxide nanostructures. Our comprehensive XRD, XPS, BET, ICP-MS, H NMR, and XANES structural/product characterization results as well as mechanistic kinetic isotope effect (KIE) studies provided the following valuable insights into the molecular level origins of the catalytic performance of the bimetallic FeMn(OH) hydroxide nanostructures: (i) catalytic reactivity is due to the coexistence and synergistic operation of Fe and Mn cationic sites (with minor contributions from Fe and Mn sites) on the catalyst surface, where in the absence of one of these synergistic sites (i.e., in the presence of monometallic hydroxides), catalytic activity almost entirely vanishes, (ii) residual Na species on the catalyst surface act as efficient electronic promoters by increasing the electron density on the Fe and Mn cationic sites, which in turn, presumably enhance the electrophilic adsorption of organic reactants and strengthen the interaction between molecular oxygen and the catalyst surface, (iii) in the fluorene oxidation reaction the step dictating the reaction rate likely involved the breaking of a C-H bond ( = 2.4), (iv) reactivity patterns of a variety of alkylarene substrates indicate that the C-H bond cleavage follows a stepwise PT-ET (proton transfer-electron transfer) pathway.
开发了一种无贵金属的双金属氢氧化铁锰(FeMn(OH))催化剂,该催化剂能够在低温下催化需氧C-H氧化反应,无需引发剂,可持续地依赖分子氧。通过系统的合成工作,我们扫描了广泛的纳米颗粒合成参数空间,以制定一套详细的催化剂设计原则,揭示Fe/Mn阳离子比、合成中使用的NaOH(aq)浓度、催化剂洗涤程序、催化剂表面残留Na促进剂的程度、反应温度和催化剂负载量如何影响作为FeMn(OH)双金属氢氧化物纳米结构的电子、表面化学和晶体结构函数的催化C-H活化性能。我们全面的XRD、XPS、BET、ICP-MS、H NMR和XANES结构/产物表征结果以及机理动力学同位素效应(KIE)研究为双金属氢氧化铁锰纳米结构催化性能的分子水平起源提供了以下有价值的见解:(i)催化反应性归因于催化剂表面上Fe和Mn阳离子位点(以及Fe和Mn位点的次要贡献)的共存和协同作用,其中在不存在这些协同位点之一的情况下(即存在单金属氢氧化物时),催化活性几乎完全消失,(ii)催化剂表面上的残留Na物种通过增加Fe和Mn阳离子位点上的电子密度而充当有效的电子促进剂,这反过来可能增强有机反应物的亲电吸附并加强分子氧与催化剂表面之间的相互作用,(iii)在芴氧化反应中,决定反应速率的步骤可能涉及C-H键的断裂( = 2.4),(iv)各种烷基芳烃底物的反应性模式表明C-H键裂解遵循逐步的PT-ET(质子转移-电子转移)途径。
