Structural and Spectroscopic Evidence for a Side-on Fe(III)–Superoxo Complex Featuring Discrete O–O Bond Distances

Pan, Hung Ruei; Chen, Hsin-Jou; Zong‐Han, WU; Ge, Pu; Ye, Shengfa; Lee, Gene‐Hsiang; Hsu, Hua-Fen

doi:10.1021/jacsau.1c00184

Cited by 14 publications

(8 citation statements)

References 93 publications

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“…As a result, this induces a notable stretching of the O−O bond from 1.21 Å for O 2 molecule 55 to 1.46−1.48 Å (Figures 5b and S18b), suggesting a probability of forming ROS (i.e., 1.33 Å for • O 2 H and 1.49 Å for • O 2 ). 55,56 Key ROS Identification and Underlying Mechanisms for Enhanced As(III) Oxidation. It is documented that the surface-bound Fe(II) can directly activate O 2 through a singleelectron transferring process.…”

Section: Gt_cu(x) Improving Electron Efficiency Of Fe(ii) For As(iii)...mentioning

confidence: 99%

Incorporation of Cu into Goethite Stimulates Oxygen Activation by Surface-Bound Fe(II) for Enhanced As(III) Oxidative Transformation

Hong

Shi

et al. 2023

Environ. Sci. Technol.

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The dark production of reactive oxygen species (ROS) coupled to biogeochemical cycling of iron (Fe) plays a pivotal role in controlling arsenic transformation and detoxification. However, the effect of secondary atom incorporation into Fe(III) oxyhydroxides on this process is poorly understood. Here, we show that the presence of oxygen vacancy (OV) as a result of Cu incorporation in goethite substantially enhances the As(III) oxidation by Fe(II) under oxic conditions. Electrochemical and density functional theory (DFT) evidence reveals that the electron transfer (ET) rate constant is enhanced from 0.023 to 0.197 s–1, improving the electron efficiency of the surface-bound Fe(II) on OV defective surfaces. The cascade charge transfer from the surface-bound Fe(II) to O2 mediated by Fe(III) oxyhydroxides leads to the O–O bond of O2 stretching to 1.46–1.48 Å equivalent to that of superoxide (•O2 –), and •O2 – is the predominant ROS responsible for As(III) oxidation. Our findings highlight the significant role of atom incorporation in changing the ET process on Fe(III) oxyhydroxides for ROS production. Thus, such an effect must be considered when evaluating Fe mineral reactivity toward changing their surface chemistry, such as those noted here for Cu incorporation, which likely determines the fates of arsenic and other redox sensitive pollutants in the environments with oscillating redox conditions.

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Section: Gt_cu(x) Improving Electron Efficiency Of Fe(ii) For As(iii)...mentioning

confidence: 99%

Incorporation of Cu into Goethite Stimulates Oxygen Activation by Surface-Bound Fe(II) for Enhanced As(III) Oxidative Transformation

Hong

Shi

et al. 2023

Environ. Sci. Technol.

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“…Aldehyde deformylations are chemical reactions taking place in organisms during metabolism and biosynthesis. , These biochemical reactions are catalyzed by metalloenzymes such as cytochrome P450 and aldehyde decarbonylase (ADO). − By binding to molecular oxygen, the metal cofactors of the metalloenzymes form metal–dioxygen active cores that perform these reactions. − Inspired by these biological processes, much effort has been devoted to the study of small-molecule transition-metal–dioxygen complexes (denoted TM–O 2 complexes hereafter). − On the one hand, TM–O 2 complexes serve as biomimetic models to deeply understand the relevant biological processes like deformylations; on the other hand, studying the chemistry of TM–O 2 complexes could lead to the discovery of aerobic catalytic transformations. − The use of abundant molecular O 2 as an oxidant offers a green and sustainable approach to produce valuable chemical products.…”

Section: Introductionmentioning

confidence: 99%

DFT Mechanistic Insights into Aldehyde Deformylations with Biomimetic Metal–Dioxygen Complexes: Distinct Mechanisms and Reaction Rules

Zhao

Zhang

Liu

et al. 2022

JACS Au

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Aldehyde deformylations occurring in organisms are catalyzed by metalloenzymes through metal–dioxygen active cores, attracting great interest to study small-molecule metal–dioxygen complexes for understanding relevant biological processes and developing biomimetic catalysts for aerobic transformations. As the known deformylation mechanisms, including nucleophilic attack, aldehyde α-H-atom abstraction, and aldehyde hydrogen atom abstraction, undergo outer-sphere pathways, we herein report a distinct inner-sphere mechanism based on density functional theory (DFT) mechanistic studies of aldehyde deformylations with a copper (II)–superoxo complex. The inner-sphere mechanism proceeds via a sequence mainly including aldehyde end-on coordination, homolytic aldehyde C–C bond cleavage, and dioxygen O–O bond cleavage, among which the C–C bond cleavage is the rate-determining step with a barrier substantially lower than those of outer-sphere pathways. The aldehyde C–C bond cleavage, enabled through the activation of the dioxygen ligand radical in a second-order nucleophilic substitution (SN2)-like fashion, leads to an alkyl radical and facilitates the subsequent dioxygen O–O bond cleavage. Furthermore, we deduced the rules for the reactions of metal–dioxygen complexes with aldehydes and nitriles via the inner-sphere mechanism. Expectedly, our proposed inner-sphere mechanisms and the reaction rules offer another perspective to understand relevant biological processes involving metal–dioxygen cores and to discover metal–dioxygen catalysts for aerobic transformations.

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“…However, the complexity of the surrounding protein superstructure restricts access to the metalloporphyrin active sites, resulting in the big challenge in studying the intermediates in O 2 activation by metalloenzymes. To deal with this big challenge, the last several decades have seen numerous researchers turn towards the development of molecular model complexes with heme and nonheme ligands that mimic the local coordination environment of the active site in enzymes [ 31 , 32 , 33 , 34 , 35 , 36 , 37 ]. Due to the simplicity of molecular model complexes, the metal–dioxygen intermediates can be stabilized and directly characterized using current techniques.…”

Section: Introductionmentioning

confidence: 99%

Isolating Fe-O2 Intermediates in Dioxygen Activation by Iron Porphyrin Complexes

2022

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Dioxygen (O2) is an environmentally benign and abundant oxidant whose utilization is of great interest in the design of bioinspired synthetic catalytic oxidation systems to reduce energy consumption. However, it is unfortunate that utilization of O2 is a significant challenge because of the thermodynamic stability of O2 in its triplet ground state. Nevertheless, nature is able to overcome the spin state barrier using enzymes, which contain transition metals with unpaired d-electrons facilitating the activation of O2 by metal coordination. This inspires bioinorganic chemists to synthesize biomimetic small-molecule iron porphyrin complexes to carry out the O2 activation, wherein Fe-O2 species have been implicated as the key reactive intermediates. In recent years, a number of Fe-O2 intermediates have been synthesized by activating O2 at iron centers supported on porphyrin ligands. In this review, we focus on a few examples of these advances with emphasis in each case on the particular design of iron porphyrin complexes and particular reaction environments to stabilize and isolate metal-O2 intermediates in dioxygen activation, which will provide clues to elucidate structures of reactive intermediates and mechanistic insights in biological processes.

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Structural and Spectroscopic Evidence for a Side-on Fe(III)–Superoxo Complex Featuring Discrete O–O Bond Distances

Cited by 14 publications

References 93 publications

Incorporation of Cu into Goethite Stimulates Oxygen Activation by Surface-Bound Fe(II) for Enhanced As(III) Oxidative Transformation

Incorporation of Cu into Goethite Stimulates Oxygen Activation by Surface-Bound Fe(II) for Enhanced As(III) Oxidative Transformation

DFT Mechanistic Insights into Aldehyde Deformylations with Biomimetic Metal–Dioxygen Complexes: Distinct Mechanisms and Reaction Rules

Isolating Fe-O2 Intermediates in Dioxygen Activation by Iron Porphyrin Complexes

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