Computational Study of Methane C–H Activation by Diiminopyridine Nitride/Nitridyl Complexes of 3d Transition Metals and Main-Group Elements

Sun, Zhicheng; Hull, Olivia A.; Cundari, Thomas R.

doi:10.1021/acs.inorgchem.7b03212

Cited by 22 publications

(23 citation statements)

References 62 publications

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“…Furthermore, among the divalent metals studied, Be complexes also had the lowest calculated reaction free energies with a range of ΔG = −8.8 to +5.7 kcal/mol for the 1,2-addition reaction with methane. It is further notable that these reactions are not inordinately exergonic, which is often computed for more traditional d-block metal–2p element active sites [ 28 ]. Such a thermodynamic situation should facilitate subsequent functionalization and catalyst regeneration steps within a catalytic cycle for alkane functionalization.…”

Section: Discussionmentioning

confidence: 99%

Computational Study of Methane C–H Activation by Main Group and Mixed Main Group–Transition Metal Complexes

Carter

Cundari

2020

Molecules

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In the present density functional theory (DFT) research, nine different molecules, each with different combinations of A (triel) and E (divalent metal) elements, were reacted to effect methane C–H activation. The compounds modeled herein incorporated the triels A = B, Al, or Ga and the divalent metals E = Be, Mg, or Zn. The results show that changes in the divalent metal have a much bigger impact on the thermodynamics and methane activation barriers than changes in the triels. The activating molecules that contained beryllium were most likely to have the potential for activating methane, as their free energies of reaction and free energy barriers were close to reasonable experimental values (i.e., ΔG close to thermoneutral, ΔG‡ ~30 kcal/mol). In contrast, the molecules that contained larger elements such as Zn and Ga had much higher ΔG‡. The addition of various substituents to the A–E complexes did not seem to affect thermodynamics but had some effect on the kinetics when substituted closer to the active site.

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Section: Discussionmentioning

confidence: 99%

Computational Study of Methane C–H Activation by Main Group and Mixed Main Group–Transition Metal Complexes

Carter

Cundari

2020

Molecules

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“…Computational and experimental studies were performed to outline a possible reaction pathway for this transformation and implicated a transient nickel–nitride intermediate. There is evidence of the formation of iron–nitride complexes with nonpincer supporting ligands in the literature. , Transient nitride–nitridyl intermediatespotentially containing a triple-, double-, or single-bonded terminal nitrogen ligand depending on the metal ion’s d-electron countare relevant for their catalytic properties as electrophilic or nucleophilic reagents and are capable of intramolecular and intermolecular activation of C–H bonds by fostering reactions such as alkyl migration, insertion into alkane C–H bonds, radical rebound, and/or C–C recombination reactions . These properties are, in part, a consequence of a perturbation of its electronic structure, derived from both steric and electronic distortions, from a square planar geometry to a disphenoidal geometry (Figure ).…”

Section: Introductionmentioning

confidence: 99%

DFT and TDDFT Study of the Reaction Pathway for Double Intramolecular C–H Activation and Functionalization by Iron, Cobalt, and Nickel–Nitridyl Complexes

Alamo

Cundari

2021

Inorg. Chem.

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Previous work was successful in synthesizing a nickel amine, [Cz tBu (Pyr iPr )(NH 2 −Pyr iPr )], by double C−H activation and functionalization via irradiating a disphenoidal Ni(II) azido complex, [Cz tBu (Pyr iPr ) 2 NiN 3 ]. The present work seeks to expand upon the earlier research and to substitute the metal with iron or cobalt. Density functional theory (DFT)B3LYP/6-31+G(d′) and APFD/Def2TZVPwas used to simulate the generation of an intermediate with significant nitridyl radical character after the loss of N 2 from the starting azido complex. DFT and time-dependent density functional theory (TDDFT) were also used to propose a detailed pathway comprised of intermediates of low, intermediate, or high spin multiplicity and photogenerated excited states for the reaction of the azido complex, [Cz tBu (Pyr iPr ) 2 MN 3 ], to form the amine complex [Cz tBu (Pyr iPr )M(NH 2 −Pyr iPr )], M = Co, Ni, or Fe.

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“…In this way, the major challenge facing the chemical industry is how to activate methane in an economical and clean way, causing less damage to the environment . In this context, several works have been accomplished aiming at more effective catalysts of transition metals that could activate the C−H bond in an efficient and selective way, thus making possible its large‐scale application . The efficiency of the transformation reaction concerning the conversion of methane to methanol and the branching ratio of methanol are significantly based on the transition metals …”

Section: Introductionmentioning

confidence: 99%

Methane Activation by (n=0, 1, 2; m= 1, 2): Reactivity Parameters, Electronic Properties and Binding Energy Analysis

et al. 2019

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The need for renewal and more efficient energy resources has led to a great interest in carrying out studies aiming to find novel sources of energy, which are able to supply the growing global demand, and providing an eco‐friendly usage of natural resources. In this context, the usage of methane stands out as a promising energetic alternative, mostly due to vast reserves, low cost and less polluting fuel. Theoretical studies with B3LYP, CCSD (t) and ZORA−B3LYP methods were used to look into the catalytic properties of (normalCnormalonormalOnormalmnormaln+ n= 0, 1, 2 and m=1, 2) in the methane C−H bond activation. According to the EDA results, the studied species presented two stabilizing factors for the global interaction energy, being the electrostatic ΔEelstat and orbital ΔEorb interactions. The HOMO and LUMO orbitals were also evaluated based on the molecular orbital diagrams for the monoxides and dioxides series. Regarding the oxidative insertion mechanism, the results demonstrate that the initial interaction between oxide and methane is of great relevance in its activation process, in which EBonding is benefited by the increasingly charge on the central metal. The high electron density regarding the oxides is meaningful for the reaction kinetics and the oxo ligands influence the thermodynamics of the reaction, becoming the DHA mechanism exergonic. Regarding the OHM mechanism, better kinetic conditions are found for CoO2++ and better thermodynamics for doubly charged cobalt monoxides and dioxides.

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Computational Study of Methane C–H Activation by Diiminopyridine Nitride/Nitridyl Complexes of 3d Transition Metals and Main-Group Elements

Cited by 22 publications

References 62 publications

Computational Study of Methane C–H Activation by Main Group and Mixed Main Group–Transition Metal Complexes

Computational Study of Methane C–H Activation by Main Group and Mixed Main Group–Transition Metal Complexes

DFT and TDDFT Study of the Reaction Pathway for Double Intramolecular C–H Activation and Functionalization by Iron, Cobalt, and Nickel–Nitridyl Complexes

Methane Activation by (n=0, 1, 2; m= 1, 2): Reactivity Parameters, Electronic Properties and Binding Energy Analysis

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