Direct and remote control of electronic structures and redox potentials in μ-oxo diferric complexes†

IF 3.5 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR Dalton Transactions Pub Date : 2023-11-03 DOI:10.1039/D3DT02734A

Sebastian Finke, Anja Stammler, Jan Oldengott, Stephan Walleck and Thorsten Glaser

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Abstract

Non-heme diiron enzymes activate O₂ for the oxidation of substrates in the form of peroxo Fe^III₂ or high-valent Fe^IV₂ intermediates. We have developed a dinucleating bis(tetradentate) ligand system that stabilizes peroxo and hydroperoxo Fe^III₂ complexes with terminal 6-methylpyridine donors, while the peroxo Fe^III₂ intermediate is reactive with terminal pyridine donors presumably via conversion to a fluent high-valent Fe^IV₂ intermediate. We present here a derivative with electron-donating methoxy substituents at the pyridine donors and its diferric complexes with an {Fe^IIIX(μ-O)Fe^IIIX} (X⁻ = Cl⁻, OAc⁻, and OH⁻) or an {Fe^III(μ-O)(μ-OAc)Fe^III} core. The complex-induced oxidation of EtOH with H₂O₂ provides μ-OAc⁻, and in acetone, the complex with mixed OH⁻/OAc⁻ exogenous donors is obtained. Both reactivities indicate a reactive fluent peroxo Fe^III₂ intermediate. The coupling constant J and the LMCT transitions are insensitive to the nature of the directly bound ligands X⁻ and reflect mainly the electronic structure of the central {Fe^III(μ-O)Fe^III} core, while Mössbauer spectroscopy and d–d transitions probe the local Fe^III sites. The remote methoxy substituents decrease the potential for the oxidation to Fe^IV by ∼100 mV, while directly bound OH⁻ in {Fe^III(OH)(μ-O)Fe^III(OH)} with a short 1.91 Å Fe^III–O^OH bond decreases the potential by 590 mV compared to {Fe^III(OAc)(μ-O)Fe^III(OAc)} with a 2.01 Å Fe^III–O^OAc bond. Interestingly, this Fe^III–OH bond is even shorter (1.87 Å) in the mixed OH⁻/OAc⁻ complex but the potential is the mean value of the potentials of the OH⁻/OH⁻ and OAc⁻/OAc⁻ complexes, thus reflecting the electron density of the central {Fe^III(μ-O)Fe^III} core and not of the local Fe^III–OH unit.

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μ-氧二铁配合物电子结构和氧化还原电位的直接和远程控制

非血红素二铁酶激活O2以过氧FeIII2或高价FeIV2中间体的形式氧化底物。我们已经开发了一种双核双（四齿）配体系统，该系统稳定具有末端6-甲基吡啶供体的过氧和氢过氧FeIII2复合物，而过氧FeIII3中间体可能通过转化为流畅的高价FeIV2中间体与末端吡啶供体反应。我们在此提出了在吡啶供体上具有给电子甲氧基取代基的衍生物，以及它与{FeIIIX（μ-O）FeIIIX}（X=Cl-、OAc-和OH-）或{FeIII（μ-O）（μ-OAc）FeIII}核的二铁络合物。配合物诱导EtOH与H2O2的氧化提供了μ-OAc-，并在丙酮中获得了具有混合OH-/OAc-外源供体的配合物。两种反应性都表明存在反应性流动的过氧FeIII2中间体。耦合常数J和LMCT跃迁对直接结合配体X-的性质不敏感，主要反映中心{FeIII（μ-O）FeIII}核的电子结构，而穆斯堡尔谱和d-d跃迁探测局部FeIII位点。远端甲氧基取代基将氧化成FeIV的电位降低约100 mV，而与具有2.01ÅFeIII OOAc键的{FeIII（OAc）（μ-O）FeIII（OAc）}相比，具有短1.91ÅFe III OOH键的｛FeIII（OH）（μ.O）FeIII（OH）｝中直接结合的OH-将电位降低590 mV。有趣的是，在混合OH-/OAc-复合物中，这种FeIII-OH键甚至更短（1.87Å），但电势是OH-/OH-和OAc-/OAc-复合物电势的平均值，因此反映了中心{FeIII（μ-O）FeIII}核的电子密度，而不是局部FeIII-OH-单元的电子密度。

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来源期刊

Dalton Transactions 化学-无机化学与核化学

CiteScore

6.60

自引率

7.50%

发文量

1832

审稿时长

1.5 months

期刊介绍： Dalton Transactions is a journal for all areas of inorganic chemistry, which encompasses the organometallic, bioinorganic and materials chemistry of the elements, with applications including synthesis, catalysis, energy conversion/storage, electrical devices and medicine. Dalton Transactions welcomes high-quality, original submissions in all of these areas and more, where the advancement of knowledge in inorganic chemistry is significant.