Computational Insight into the Carbenic Character of Nitrilimines from a Reactivity Perspective

Muchall, Heidi M.

doi:10.1021/jp208510d

Cited by 11 publications

(15 citation statements)

References 57 publications

(125 reference statements)

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“…This is particularly noticeable by the CNN antisymmetric stretching IR absorption of the nitrile imine moiety appearing over a wide range of frequencies (2000-2250 cm -1 ). [20,29,30] For instance, Bégué and Wentrup have theo-retically investigated different amino-, hydroxy-, and fluorosubstituted nitrile imines (R-CNN-H, H-CNN-R, and R-CNN-R; R = NH 2 , OH, and F) and predicted that some of the studied molecules should exhibit carbenic character. [17] In addition, theoretical studies have indicated that substituents bearing a lone-electron pair should increase the importance of the carbenic resonance structure of nitrile imines.…”

Section: Introductionmentioning

confidence: 99%

“…[17] In addition, theoretical studies have indicated that substituents bearing a lone-electron pair should increase the importance of the carbenic resonance structure of nitrile imines. [20,29,30] For instance, Bégué and Wentrup have theo-retically investigated different amino-, hydroxy-, and fluorosubstituted nitrile imines (R-CNN-H, H-CNN-R, and R-CNN-R; R = NH 2 , OH, and F) and predicted that some of the studied molecules should exhibit carbenic character. [30] These postulated carbenic nitrile imines were predicted to lack the intense IR absorption in the 2000-2250 cm -1 region that characterizes other nitrile imines.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

The Quest for Carbenic Nitrile Imines: Experimental and Computational Characterization of C‐Amino Nitrile Imine

et al. 2015

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C‐Amino nitrile imine has been generated as primary photoproduct (λ = 220 nm) of 5‐amino‐2H‐tetrazole isolated in an argon matrix at 15 K. Subsequent photochemical experiments (λ = 330 nm) demonstrated that C‐amino nitrile imine isomerizes to the corresponding three‐membered‐ring 1H‐diazirine and decomposes to methylenimine. The experimentally observed νas(CNN) absorption at 1998 cm–1 and a carbenic resonance structure contribution of around 20 %, predicted by natural resonance theory calculations, demonstrate that the protoproduced C‐amino nitrile imine has significant carbenic character. These results pave the way to the discovery of carbenic nitrile imines.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Quest for Carbenic Nitrile Imines: Experimental and Computational Characterization of C‐Amino Nitrile Imine

et al. 2015

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“…Although some computational studies have already been undertaken on nitrile imines, [14] not much attention has been paid to the tetrazole activation step, [15] which in our opinion is crucial to understand their reactivity.H erein, density functional theory (DFT) calculationso ft he three tetrazoles, Tet, Py-Tet and Biph-Tet,w ere carriedo ut. First, an examination of the transitions of the ground state of the selected tetrazoles was carried out.…”

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confidence: 99%

Understanding Reactivity Patterns in Light‐Induced Nitrile Imine Mediated Tetrazole–Ene Cycloadditions

et al. 2017

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A rationale for predicting photochemical tetrazole activation in the popular nitrile imine mediated tetrazole–ene cycloaddition (NITEC) reaction, based on a combined theoretical and experimental study, is reported. DFT calculations of three tetrazole derivatives reveal that the efficiency of intersystem crossing is determined by the chromophore moiety. This species is critical in dictating the reactivity of the tetrazoles towards nitrile imine formation, yet mere inspection of the chromophore moiety's absorptivity is insufficient for predicting the tetrazole's photochemical reactivity.

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“…In the case of a maximally depleted charge, it is possible to report which sites are able to stabilize an overload uptake of electronic charge and that they are especially reactive toward electron‐rich reactants (nucleophiles) . Additionally, studies dealing with chemical reactivity relationships and QTAIM have shown that the Laplacian can be reliably used to predict reactive sites, such as the positions of sites for electrophilic or nucleophilic attack in aromatic systems, N‐heterocyclic carbenes, α‐ and β‐halonaphthalenes, non‐steroidal anti‐inflammatory drugs, and other chemical systems …”

Section: Introductionmentioning

confidence: 99%

“…[3,4] Additionally, studies dealing with chemical reactivity relationships and QTAIM have shown that the Laplacian can be reliably used to predict reactive sites, such as the positions of sites for electrophilic or nucleophilic attack in aromatic systems, [5] N-heterocyclic carbenes, [6] αand β-halonaphthalenes, [7] non-steroidal anti-inflammatory drugs, [8] and other chemical systems. [9][10][11] Theoretical studies about reaction mechanisms are usually limited to the determination of the energetic paths that connect reactants, transition states, and products and their structures. In a previous work, we showed that the most important topological feature in the ethene protonation reaction over acidic zeolite is the electron charge density redistribution.…”

Section: Introductionmentioning

confidence: 99%

Laplacian of the electron density: a hole–lump interaction as a tool to study stereoelectronic control of chemical reactions

Zalazar

Peruchena

2013

J of Physical Organic Chem

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a In this work, we applied the theory of Atoms in Molecules to the study of carbocationic transition states involved in two different reaction mechanisms, using the proposed mechanism of ethylene dimerization over Brønsted-acid site of zeolite catalyst as a study case. We report the main results of the analysis of the Laplacian of electron density distribution and Bader's atomic charges to increase our understanding of stereoelectronic aspects of these chemical reactions. At B3LYP/6-31++G(d,p)//B3LYP/6-3G(d,p) level, our results show that the envelopes of Laplacian distribution provide valuable information about the relative orientation of the species involved in the reaction, their interaction with the catalyst surface, and its stability. The stabilization and formation of these transition states depend on the availability of electrons in the environment. Such availability plays a key role to stabilize the positive charge on the carbocationic center and, thus, to stabilize the formed carbocation. The analysis of envelopes of Laplacian could be used to study different organic and inorganic chemical reactions and provide new insights to increase our understanding of these chemical reactions.

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Computational Insight into the Carbenic Character of Nitrilimines from a Reactivity Perspective

Cited by 11 publications

References 57 publications

The Quest for Carbenic Nitrile Imines: Experimental and Computational Characterization of C‐Amino Nitrile Imine

The Quest for Carbenic Nitrile Imines: Experimental and Computational Characterization of C‐Amino Nitrile Imine

Understanding Reactivity Patterns in Light‐Induced Nitrile Imine Mediated Tetrazole–Ene Cycloadditions

Laplacian of the electron density: a hole–lump interaction as a tool to study stereoelectronic control of chemical reactions

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