Experiment and Theory Reveal the Fundamental Difference between Two‐State and Single‐State Reactivity Patterns in Nonheme Fe<sup>IV</sup>O versus Ru<sup>IV</sup>O Oxidants

Dhuri, Sunder N.; Seo, Mi Sook; Lee, Yong Min; Hirao, Hajime; Wang, Yong; Nam, Wonwoo; Shaik, Sason

doi:10.1002/anie.200705880

Cited by 73 publications

(56 citation statements)

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“…The TSR concepts showed that the involvement of the quintet state in the reaction is the root cause of these unusual reactivity patterns. Further validation of the TSR model was obtained from a more recent study on the corresponding [Ru IV (O)TMC(X)] z+ oxidants, where the quintet state is too high to be able to participate in the reaction;[11] this study revealed that the two reaction series exhibit precisely the same trends, indicative of the sole involvement of the triplet state.…”

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confidence: 89%

A Two‐State Reactivity Model Explains Unusual Kinetic Isotope Effect Patterns in CH Bond Cleavage by Nonheme Oxoiron(IV) Complexes

et al. 2009

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It's in the bond: The cleavage of CH bonds by two related oxoiron(IV) complexes shows a range of kinetic isotope effect (KIE) values that exhibit an unusual dependence on the CH bond strength. Large nonclassical KIEs are observed for bond strengths below 93 kcal mol−1, while semiclassical values are found above this value (see graph, DHA=9,10‐dihydroanthracene). This nonintuitive behavior can be rationalized by invoking a two‐state reactivity model.

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confidence: 89%

A Two‐State Reactivity Model Explains Unusual Kinetic Isotope Effect Patterns in CH Bond Cleavage by Nonheme Oxoiron(IV) Complexes

et al. 2009

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“…Theoretical studies of such biomimetic models may not only identify the key elements that determine their chemical reactivities, but may also provide insight into intermediates and reactivities of parent enzymes (Shaik et al, 2007a; de Visser et al, 2013). To date, DFT calculations have been applied extensively to various types of non-heme iron species (Scheme 1) (Bassan et al, 2002, 2005a,b; Roelfes et al, 2003; Decker and Solomon, 2005; Kumar et al, 2005; Quinonero et al, 2005; Berry et al, 2006; Bernasconi et al, 2007, 2011; de Visser, 2006, 2010; Hirao et al, 2006a, 2008a,b, 2011; Rohde et al, 2006; Decker et al, 2007; de Visser et al, 2007, 2011; Johansson et al, 2007; Noack and Siegbahn, 2007; Sastri et al, 2007; Sicking et al, 2007; Bernasconi and Baerends, 2008, 2013; Comba et al, 2008; Dhuri et al, 2008; Fiedler and Que, 2009; Klinker et al, 2009; Wang et al, 2009a, 2013b; Cho et al, 2010, 2012a, 2013; Geng et al, 2010; Chen et al, 2011; Chung et al, 2011b; Seo et al, 2011; Shaik et al, 2011; Vardhaman et al, 2011; Wong et al, 2011; Ye and Neese, 2011; Gonzalez-Ovalle et al, 2012; Gopakumar et al, 2012; Latifi et al, 2012; Mas-Ballesté et al, 2012; McDonald et al, 2012; Van Heuvelen et al, 2012; Ansari et al, 2013; Kim et al, 2013; Lee et al, 2013; Sahu et al, 2013; Tang et al, 2013; Ye et al, 2013; Hong et al, 2014; Sun et al, 2014). The intriguing reactivity patterns of these complexes are the result of active involvement of electrons in d-type MOs, which gives rise to multi-state scenarios (Shaik et al, 1998; Schröder et al, 2000; Schwarz, 2011).…”

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confidence: 99%

Applications of density functional theory to iron-containing molecules of bioinorganic interest

2014

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The past decades have seen an explosive growth in the application of density functional theory (DFT) methods to molecular systems that are of interest in a variety of scientific fields. Owing to its balanced accuracy and efficiency, DFT plays particularly useful roles in the theoretical investigation of large molecules. Even for biological molecules such as proteins, DFT finds application in the form of, e.g., hybrid quantum mechanics and molecular mechanics (QM/MM), in which DFT may be used as a QM method to describe a higher prioritized region in the system, while a MM force field may be used to describe remaining atoms. Iron-containing molecules are particularly important targets of DFT calculations. From the viewpoint of chemistry, this is mainly because iron is abundant on earth, iron plays powerful (and often enigmatic) roles in enzyme catalysis, and iron thus has the great potential for biomimetic catalysis of chemically difficult transformations. In this paper, we present a brief overview of several recent applications of DFT to iron-containing non-heme synthetic complexes, heme-type cytochrome P450 enzymes, and non-heme iron enzymes, all of which are of particular interest in the field of bioinorganic chemistry. Emphasis will be placed on our own work.

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“…This mode of binding mimics that of the obligate tetradentate tetramethylated cyclam (N-Me 4 cyclam). [20][21][22][23][24] Indeed, the structural, spectroscopic, and electrochemical properties of the Cu II and Ni Although demetalation of any hexadentate sar-type complex should proceed through such partially (e.g., tetradentate) coordinated forms of the ligand, identification of these intermediates is difficult given the harsh conditions required to remove the metal from the cage. Complete removal of Co from sar-derived cages can only be achieved after reduction to the less stable and more labile Co II form, followed by either complexation with cyanide or protonation of the free ligand.…”

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confidence: 99%

Copper(II) Complexes of a Hexadentate Mixed‐Donor N₃S₃ Macrobicyclic Cage: Facile Rearrangements and Interconversions

Bell

Bernhardt

Gahan

et al. 2010

Chemistry A European J

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The potentially hexadentate mixed-donor cage ligand 1-methyl-8-amino-3,13,16-trithia-6,10,19-triazabicyclo[6.6.6]eicosane (AMME-N(3)S(3)sar; sar=sarcophagine) displays variable coordination modes in a complex with copper(II). In the absence of coordinating anions, the ligand adopts a conventional hexadentate N(3)S(3) binding mode in the complex [Cu(AMME-N(3)S(3)sar)](ClO(4))(2) that is typical of cage ligands. This structure was determined by X-ray crystallography and solution spectroscopy (EPR and NIR UV/Vis). However, in the presence of bromide ions in DMSO, clean conversion to a five-coordinate bromido complex [Cu(AMME-N(3)S(3)sar)Br](+) is observed that features a novel tetradentate (N(2)S(2))-coordinated form of the cage ligand. This copper(II) complex has also been characterized by X-ray crystallography and solution spectroscopy. The mechanism of the reversible interconversion between the six- and five-coordinated copper(II) complexes has been studied and the reaction has been resolved into two steps; the rate of the first is linearly dependent on bromide ion concentration and the second is bromide independent. Electrochemistry of both [Cu(AMME-N(3)S(3)sar)](2+) and [Cu(AMME-N(3)S(3)sar)Br](+) in DMSO shows that upon reduction to the monovalent state, they share a common five-coordinated form in which the ligand is bound to copper in a tetradentate form exclusively, regardless of whether a six- or five-coordinated copper(II) complex is the precursor.

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Experiment and Theory Reveal the Fundamental Difference between Two‐State and Single‐State Reactivity Patterns in Nonheme Fe^IVO versus Ru^IVO Oxidants

Cited by 73 publications

References 34 publications

A Two‐State Reactivity Model Explains Unusual Kinetic Isotope Effect Patterns in CH Bond Cleavage by Nonheme Oxoiron(IV) Complexes

A Two‐State Reactivity Model Explains Unusual Kinetic Isotope Effect Patterns in CH Bond Cleavage by Nonheme Oxoiron(IV) Complexes

Applications of density functional theory to iron-containing molecules of bioinorganic interest

Copper(II) Complexes of a Hexadentate Mixed‐Donor N₃S₃ Macrobicyclic Cage: Facile Rearrangements and Interconversions

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Experiment and Theory Reveal the Fundamental Difference between Two‐State and Single‐State Reactivity Patterns in Nonheme FeIVO versus RuIVO Oxidants

Cited by 73 publications

References 34 publications

A Two‐State Reactivity Model Explains Unusual Kinetic Isotope Effect Patterns in CH Bond Cleavage by Nonheme Oxoiron(IV) Complexes

A Two‐State Reactivity Model Explains Unusual Kinetic Isotope Effect Patterns in CH Bond Cleavage by Nonheme Oxoiron(IV) Complexes

Applications of density functional theory to iron-containing molecules of bioinorganic interest

Copper(II) Complexes of a Hexadentate Mixed‐Donor N3S3 Macrobicyclic Cage: Facile Rearrangements and Interconversions

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Experiment and Theory Reveal the Fundamental Difference between Two‐State and Single‐State Reactivity Patterns in Nonheme Fe^IVO versus Ru^IVO Oxidants

Copper(II) Complexes of a Hexadentate Mixed‐Donor N₃S₃ Macrobicyclic Cage: Facile Rearrangements and Interconversions