New Insights into Factors Influencing BN Bonding in X:BH3−nFnand X:BH3−nClnfor X=N2, HCN, LiCN, H2CNH, NF3, NH3andn=0–3: The Importance of Deformation

Alkorta, Ibón; Elguero, José; Bene, Janet E. Del; Mó, Otília; Yáñez, Manuel

doi:10.1002/chem.201001254

Cited by 38 publications

(39 citation statements)

References 39 publications

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“…[10][11][12][13][14][15] The important point we want to emphasize here is that the deformation plays a crucial role when these complexes are formed, so that the strength of the interaction actually can only be correctly rationalized by taking into account the effects that the deformation has on the donor and the acceptor properties of the interacting systems. [16,17] Only when these effects are accounted for is it then possible to explain, for instance, why BH 2 F and BHF 2 are weaker Lewis acids than BH 3 , whereas boron trifluoride is a stronger acid than borane. [16] Abstract: The gas-phase acidity of a series of amine-borane complexes has been investigated through the use of electrospray mass spectrometry (ESI-MS), with the application of the extended Cooks kinetic method, and high-level G4 ab initio calculations.…”

Section: Introductionmentioning

confidence: 99%

Can an Amine Be a Stronger Acid than a Carboxylic Acid? The Surprisingly High Acidity of Amine–Borane Complexes

Martín-Sómer

Lamsabhi

Yáñez

et al. 2012

Chemistry A European J

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The gas-phase acidity of a series of amine-borane complexes has been investigated through the use of electrospray mass spectrometry (ESI-MS), with the application of the extended Cooks kinetic method, and high-level G4 ab initio calculations. The most significant finding is that typical nitrogen bases, such as aniline, react with BH(3) to give amine-borane complexes, which, in the gas phase, have acidities as high as those of either phosphoric, oxalic, or salicylic acid; their acidity is higher than many carboxylic acids, such as formic, acetic, and propanoic acid. Indeed the complexation of different amines with BH(3) leads to a substantial increase (from 167 to 195 kJ mol(-1)) in the intrinsic acidity of the system; in terms of ionization constants, this increase implies an increase as large as fifteen orders of magnitude. Interestingly, this increase in acidity is almost twice as large as that observed for the corresponding phosphine-borane analogues. The agreement between the experimental and the G4-based calculated values is excellent. The analysis of the electron-density rearrangements of the amine and the borane moieties indicates that the dative bond is significantly stronger in the N-deprotonated anion than in the corresponding neutral amine-borane complex, because the deprotonated amine is a much better electron donor than the neutral amine. On the top of that, the newly created lone pair on the nitrogen atom in the deprotonated species, conjugates with the BN bonding pair. The dispersion of the extra electron density into the BH(3) group also contributes to the increased stability of the deprotonated species.

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Section: Introductionmentioning

confidence: 99%

Can an Amine Be a Stronger Acid than a Carboxylic Acid? The Surprisingly High Acidity of Amine–Borane Complexes

Martín-Sómer

Lamsabhi

Yáñez

et al. 2012

Chemistry A European J

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“…17 This actually explains why the dissociation energy of BH 3 complexes is greater than that of BF 3 complexes, even though BF 3 should be a stronger acid than BH 3 .…”

Section: 23mentioning

confidence: 99%

“…Indeed, the energy of the LUMO increases practically linearly with the increase in the number of fluorine substituents as shown in Figure 1a. However, high-level ab initio calculations 17 show the variation of the dissociation energy of NH 3 :BH 3-n F n complexes into NH 3 + BH 3-n F n is far from being linear, since, as shown in Figure 1b, BH 2 F, BHF 2 and BF 3 are found to be weaker Lewis acids than borane, so that the curve presents a minimum for BHF 2 .…”

Section: 23mentioning

confidence: 99%

“…16 Nevertheless, recently it was proved that to account for the relative stabilities of the complexes formed through these interactions is not enough to include the deformation energy but to take into account the changes produced in the intrinsic reactivity of the monomers, as a consequence of the aforementioned deformations. 17,18 Depending on the magnitude of the polarization from the Lewis base to the Lewis acid, the intrinsic reactivity of both moieties can dramatically change.…”

Section: Introductionmentioning

confidence: 99%

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Some Interesting Features of Non-Covalent Interactions

Martín-Sómer¹,

Montero‐Campillo²,

Mó³

et al. 2014

Croat. Chem. Acta

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Abstract. Interactions between closed-shell systems exhibit some common features, four of which are particularly strong for beryllium bonds: geometrical distortion, cooperativity, changes in intrinsic reactivity and changes in the magnetic properties of the interacting subunits, which reflect the perturbations of their electron densities through polarization effects. Structural changes lead to interaction energies that can only be adequately accounted for when the effects of the distortion on the intrinsic reactivity of the system, and not only its deformation energy, are taken into consideration. Self-assembling of ditopic systems may lead to n-mers stabilized by strong cooperative effects. Chemical shifts and coupling constants also reflect the perturbations of the electron density and accordingly cooperative effects. These four features are common to any interaction involving two closed-shell systems, one acting as Lewis acid and the other as Lewis base, and the only difference between the nature of the interactions is quantitative.

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“…With this goal in mind, we related it with the ability of BeH 2 to form stable complexes with N 2 9 . As a reference, we chose the 1,3-dipolar cycloaddition between dimethyl nitrile imine and dimethyl acetylene, a reaction that proceeds smoothly in the case of diphenyl nitrile imine 3,5,10 .…”

Section: Introductionmentioning

confidence: 99%

Activation of Dinitrogen as A Dipolarophile in 1,3-Dipolar Cycloadditions: A Theoretical Study Using Nitrile Imines as “Octet” 1,3-Dipoles

Montero‐Campillo

Alkorta

Elguero

2017

Sci Rep

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Theoretical calculations at the G4MP2 level of theory demonstrate that it is possible to activate dinitrogen to make it react in dipolar cycloadditions using neutral beryllium derivatives and other neutral metallic compounds. For the particular case of beryllium, the barrier decreases more than 40 kJ·mol–1 with respect to the non-catalysed reaction. The activation achieved is lower than using diazonium salts (models of protonated N2), but still in a range that can be experimentally attainable.

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New Insights into Factors Influencing BN Bonding in X:BH_3−nF_nand X:BH_3−nCl_nfor X=N₂, HCN, LiCN, H₂CNH, NF₃, NH₃andn=0–3: The Importance of Deformation

Cited by 38 publications

References 39 publications

Can an Amine Be a Stronger Acid than a Carboxylic Acid? The Surprisingly High Acidity of Amine–Borane Complexes

Can an Amine Be a Stronger Acid than a Carboxylic Acid? The Surprisingly High Acidity of Amine–Borane Complexes

Some Interesting Features of Non-Covalent Interactions

Activation of Dinitrogen as A Dipolarophile in 1,3-Dipolar Cycloadditions: A Theoretical Study Using Nitrile Imines as “Octet” 1,3-Dipoles

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