A two‐step reaction scheme leading to singlet carbene species that can be detected under matrix conditions for the reaction of Zr(3F) with either CH3F or CH3CN

Torres, Ana E.; Castro, Guadalupe; Pablo-Pedro, Ricardo; Colmenares, Fernando

doi:10.1002/jcc.23564

Cited by 9 publications

(11 citation statements)

References 46 publications

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“…117 CASSCF-MRMP2 calculations were carried out to determine the mechanism of formation of (CH 3 )MF in the case of M = Zr. 118 With later metals of the Periodic Table, is energetically facile and exoergic. 120 Migration of H from the methyl group to Pt has a very low energy barrier and the subsequent reverse F migration from the metal to the ligand has an accessible transition state and is energetically favorable.…”

Section: Survey Of Stoichiometric Reactionsmentioning

confidence: 99%

Selectivity of C–H Activation and Competition between C–H and C–F Bond Activation at Fluorocarbons

2017

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Partially fluorinated alkanes, arenes, and alkenes can be transformed by a variety of transition metal and lanthanide systems. Although the C-H bond is weaker than the C-F bond regardless of the hybridization of the carbon, the reaction of the C-F bond at the metal is usually more exothermic than the corresponding reaction of the C-H bonds. Both bonds are activated by the metal systems, but the preference for activating these bonds depends on the nature of the hydrocarbon and of the metal system, so that the reaction can be directed exclusively toward C-H or C-F bonds or yield a mixture of products. Additionally, the presence of fluorine differentiates between C-H bonds at different positions resulting in regioselective C-H bond activation; paradoxically, the strongest C-H bond reacts preferentially. The purpose of this review is to describe the field of reactions of partially fluorinated substrates with transition metal atoms, ions, and molecular complexes. The controlling physical properties (thermodynamics and kinetics) are described first, followed by a description of stoichiometric reactions, with the competition between the C-H and C-F activations as focus. A few representative catalytic systems are discussed. The review also highlights the benefit of combining experimental and theoretical studies.

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Section: Survey Of Stoichiometric Reactionsmentioning

confidence: 99%

Selectivity of C–H Activation and Competition between C–H and C–F Bond Activation at Fluorocarbons

2017

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“…The proposed two‐reaction scheme implicitly takes into account, at least partially, the effect of the confinement medium. It was also been used successfully to explain for the singlet complexes determined under matrix conditions for the reactions of Zr( 3 F) with CH 3 F and CH 3 CN ,. The results obtained from these studies suggest that other confined interactions involving transition metal atoms could be described in terms of two sequential reactions involving radical species, instead of spin‐flip models arising from unlikely interactions between electronic states of different spin multiplicity.…”

Section: Introductionmentioning

confidence: 99%

Rationalizing the Low‐Spin Products Observed for the Reactions M+CH₃CN (M=V, Nb,Ta) Through a Non‐Spin Flip Scheme.

2017

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Results emerging from a CASSCF‐MRMP2 study are used to explain the products observed under matrix isolation conditions for the interactions M + CH3CN (M=V(4F), Nb(6D), Ta(4F)). A two‐reaction scheme is proposed to rationalize the low‐spin inserted species detected for the niobium and tantalum interactions, mainly the quadruplet CH3‐Nb‐NC and the doublet CH2=Ta‐(H)NC compounds, respectively. According to this scheme, the radicals CH3 + M‐NC are formed in each case from the ground state of the reactants. As these radical fragments remain trapped in the matrix they can recombine themselves in a second reaction, which evolves to the low‐spin observed products. The absence of inserted products for the vanadium reaction is also explained in terms of this scheme. The picture attained for the investigated reactions fits better with the available experimental data than previous descriptions based on spin‐flip models.

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“…A similar two-step radical reaction scheme has been used in previous contributions to explain for the observed products in other reactions. [33][34][35][36][37][38] Although mass-spectrometry determinations on these reactions have inspired the present study, this investigation is mainly focused on the analysis of the factors that could be relevant in determining the role of the metal-ligand interactions on the NH 3 activation by the ammine complexes yielded by sequential addition of NH 3 ligands to the metallic center. However, even when our reaction models do not consider the experimental conditions of the spectroscopic determinations, there is a good agreement between the results presented herein and those obtained by mass spectrometry for the investigated interactions.…”

mentioning

confidence: 99%

“…A similar two-step reaction scheme has been used to rationalize the shift in the spin multiplicity between the reactants and the observed products for other interactions. [33][34][35][36][37][38] In Figure 4 are shown the potential energy plots for these recombination reactions. As it is seen in Figure 5, the product Ru(NH 3 ) 3 (H)NH 2 + evolving from the doublet pathway is more stable than that corresponding to the quadruplet one by 38.7 kcal/mol (for both multiplicity-channels a NH 3 ligand is expelled out when the NH 2 group is been attached to the metallic center).…”

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confidence: 99%

Low‐Energy Pathways Found for the NH₃ Activation and H₂ Elimination by the Werner‐Type Complexes M(NH₃)₄⁺ (M=Fe, Ru and Os).

2020

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The interactions of NH3 with the transition metal complexes M(NH3)n+ (M=Fe, Ru, Os; n=0−4) were investigated theoretically with the aim of analyzing the factors that determine their reactivity patterns and product distributions. The reactions of ammonia with the low‐coordination complexes of the three metallic ions (n=1−3) lead only to the addition product M(NH3)n+1+. However, once the highest‐coordinated complex M(NH3)4+ is reached, each of the reactions evolves to metal‐inserted species through low energy channels. For osmium, the hydrogen abstraction from an additional NH3 molecule by the inserted intermediate H−Os(NH3)4‐NH2+ leads to H2 elimination products along a favorable pathway. The facile breaking of the strong N−H bond of ammonia by these Werner‐type complexes is by far the most striking finding emerging from this study. Hopefully, this could inspire future contributions in the areas of chemical and bioinorganic catalysis.

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A two‐step reaction scheme leading to singlet carbene species that can be detected under matrix conditions for the reaction of Zr(³F) with either CH₃F or CH₃CN

Cited by 9 publications

References 46 publications

Selectivity of C–H Activation and Competition between C–H and C–F Bond Activation at Fluorocarbons

Selectivity of C–H Activation and Competition between C–H and C–F Bond Activation at Fluorocarbons

Rationalizing the Low‐Spin Products Observed for the Reactions M+CH₃CN (M=V, Nb,Ta) Through a Non‐Spin Flip Scheme.

Low‐Energy Pathways Found for the NH₃ Activation and H₂ Elimination by the Werner‐Type Complexes M(NH₃)₄⁺ (M=Fe, Ru and Os).

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A two‐step reaction scheme leading to singlet carbene species that can be detected under matrix conditions for the reaction of Zr(3F) with either CH3F or CH3CN

Cited by 9 publications

References 46 publications

Selectivity of C–H Activation and Competition between C–H and C–F Bond Activation at Fluorocarbons

Selectivity of C–H Activation and Competition between C–H and C–F Bond Activation at Fluorocarbons

Rationalizing the Low‐Spin Products Observed for the Reactions M+CH3CN (M=V, Nb,Ta) Through a Non‐Spin Flip Scheme.

Low‐Energy Pathways Found for the NH3 Activation and H2 Elimination by the Werner‐Type Complexes M(NH3)4+ (M=Fe, Ru and Os).

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A two‐step reaction scheme leading to singlet carbene species that can be detected under matrix conditions for the reaction of Zr(³F) with either CH₃F or CH₃CN

Rationalizing the Low‐Spin Products Observed for the Reactions M+CH₃CN (M=V, Nb,Ta) Through a Non‐Spin Flip Scheme.

Low‐Energy Pathways Found for the NH₃ Activation and H₂ Elimination by the Werner‐Type Complexes M(NH₃)₄⁺ (M=Fe, Ru and Os).