Acidity Trends in α,β‐Unsaturated Sulfur, Selenium, and Tellurium Derivatives: Comparison with C‐, Si‐, Ge‐, Sn‐, N‐, P‐, As‐, and Sb‐Containing Analogues

Guillemin, Jean‐Claude; Riague, El Hassan; Gal, Jean‐François; Maria, Pierre‐Charles; Mó, Otília; Yáñez, Manuel

doi:10.1002/chem.200400989

Cited by 28 publications

(33 citation statements)

References 51 publications

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“…This seems to be however, a quite general phenomenon and similar gas-phase acidity enhancements have been reported for a large set of , -unsaturated amines, phosphines [73], arsines [74], silanes, germanes, stannanes [75], thiols, selenols and tellurols [76], both from the experimental Fourier transform-ICR mass spectrometry and the theoretical viewpoints. Conversely, the enhanced acidity of the ethynyl derivatives with respect to the vinyl compounds is due to two concomitant effects, the stabilization of the anion and the destabilization of the neutral [76]. The origin of the acidity increase on going from saturated to unsaturated compounds is associated with the enhancement of the -delocalization in the anions with respect to neutrals when the heteroatoms belong to groups 14, 15 and 16.…”

Section: Unexpected Enhanced Acidity Of Saturated and -Unsaturated supporting

confidence: 77%

“…The first evidence of this interesting phenomenon was the dramatic acidity enhancement of ethynol with respect to its saturated counterpart ethanol, theoretically predicted by Radom and coworkers in 1989 [72]. Besides, theoretical calculations also predicted unsaturated stibines to exhibit the same behavior [76]. Besides, theoretical calculations also predicted unsaturated stibines to exhibit the same behavior [76].…”

Section: Unexpected Enhanced Acidity Of Saturated and -Unsaturated mentioning

confidence: 87%

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Unexpected Gas-Phase Ion Chemistry Results Unraveled by Computational Chemistry

Gámez¹,

Corral²,

Mó³

et al. 2010

COC

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An overview of recent studies, which show the important role played by computational chemistry in explaining and predicting the behavior of a great variety of systems is presented. The first example illustrates the useful interplay experiment-theory which allowed to unambiguously characterize the X2(CH3)7 + (X = Si, Ge, Sn, Pb) cations as paradigmatic examples of molecular systems involving pentacovalently bound carbon atoms. Also, the possibility of deeply analyzing the bonding in molecular systems, led to a rationalization of the quite different behavior of acetylene and iminoborane derivatives, in spite of being isoelectronic species. Similarly, the analysis of the bonding perturbations usually associated with ion-molecule interactions in the gas phase, or with protonation and deprotonation processes, has made possible the characterization of non-conventional complexes as the key structures in the interactions of unsaturated and aromatic Si and Ge containing compounds with transition metal ions or to explain the dramatic enhanced acidity of alkylboranes and ,unsaturated borane derivatives.

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Section: Unexpected Enhanced Acidity Of Saturated and -Unsaturated supporting

confidence: 77%

Section: Unexpected Enhanced Acidity Of Saturated and -Unsaturated mentioning

confidence: 87%

Unexpected Gas-Phase Ion Chemistry Results Unraveled by Computational Chemistry

Gámez¹,

Corral²,

Mó³

et al. 2010

COC

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“…As a consequence, a great deal of effort was concentrated on determining intrinsic reactivities, in particular intrinsic basicities and acidities. [2][3][4][5] The gas-phase acidity of phosphines has been reported [6,7] and the role played by the substituent on the acidity of the molecule clearly evidenced. In particular the presence of an a,b-unsaturated substituent [6] with or without an electronwithdrawing group [5,7] led to a huge increase in acidity.…”

Section: Introductionmentioning

confidence: 96%

The Ever‐Surprising Chemistry of Boron: Enhanced Acidity of Phosphine⋅Boranes

Hurtado

Yáñez

Herrero

et al. 2009

Chemistry A European J

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The acidity-enhancing effect of BH(3) in gas-phase phosphineboranes compared to the corresponding free phosphines is enormous, between 13 and 18 orders of magnitude in terms of ionization constants. Thus, the enhancement of the acidity of protic acids by Lewis acids usually observed in solution is also observed in the gas phase. For example, the gas-phase acidities (GA) of MePH(2) and MePH(2)BH(3) differ by about 118 kJ mol(-1) (see picture).The gas-phase acidity of a series of phosphines and their corresponding phosphineborane derivatives was measured by FT-ICR techniques. BH(3) attachment leads to a substantial increase of the intrinsic acidity of the system (from 80 to 110 kJ mol(-1)). This acidity-enhancing effect of BH(3) is enormous, between 13 and 18 orders of magnitude in terms of ionization constants. This indicates that the enhancement of the acidity of protic acids by Lewis acids usually observed in solution also occurs in the gas phase. High-level DFT calculations reveal that this acidity enhancement is essentially due to stronger stabilization of the anion with respect to the neutral species on BH(3) association, due to a stronger electron donor ability of P in the anion and better dispersion of the negative charge in the system when the BH(3) group is present. Our study also shows that deprotonation of ClCH(2)PH(2) and ClCH(2)PH(2)BH(3) is followed by chloride departure. For the latter compound deprotonation at the BH(3) group is found to be more favorable than PH(2) deprotonation, and the subsequent loss of Cl(-) is kinetically favored with respect to loss of Cl(-) in a typical S(N)2 process. Hence, ClCH(2)PH(2)BH(3) is the only phosphineborane adduct included in this study which behaves as a boron acid rather than as a phosphorus acid.

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“…In addition, for derivatives that contain heteroatoms from groups 14-16, this acidity enhancement depends mainly on the nature of the unsaturated moiety and on the heteroatom, which is mirrored in the existence of good linear correlations between the gas-phase acidities of homologous compounds of these three groups. [32] However, primary saturated and a,b-unsaturated boranes, alanes, and galanes, in which the heteroatoms belong to a group to the left of carbon, were predicted to have quite peAbstract: The gas-phase acidity of R À XH (R = H, CH 3 , CH 2 CH 3 , CH= CH 2 , C CH; X = Be, Mg, Ca) alkalineearth-metal derivatives has been investigated through the use of high-level CCSD(T) calculations by using a 6-311 + GA C H T U N G T R E N N U N G (3df,2p) basis set. BeH 2 is a stronger acid than BH 3 and CH 4 for two concomitant reasons: 1) the dissociation energy of the Be À H bond is smaller than the dissociation energies of the B À H and C À H bonds, and 2) the electron affinity of BeHC is larger in absolute value than those of BH 2 C and CH 3 C. The acidity also increases on going from BeH 2 to MgH 2 due to these two same factors.…”

Section: Introductionmentioning

confidence: 97%

“…In our group, we have devoted some effort to establishing and analyzing the acidity trends of heterocompounds. The main conclusions of these studies were that a,b-unsaturated amines, phosphines, [30] arsines, [31] stibines, [32] silanes, germanes, stannanes, [33] thiols, selenols, and tellurols [32] exhibit enhanced acidity compared with the corresponding saturated derivatives. In addition, for derivatives that contain heteroatoms from groups 14-16, this acidity enhancement depends mainly on the nature of the unsaturated moiety and on the heteroatom, which is mirrored in the existence of good linear correlations between the gas-phase acidities of homologous compounds of these three groups.…”

Section: Introductionmentioning

confidence: 98%

α,β‐Unsaturated and Saturated Derivatives of Be, Mg, and Ca: Are They Carbon or Metal Acids in the Gas Phase?

Eizaguirre¹,

Mó²,

Yáñez³

et al. 2008

Chemistry A European J

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The gas-phase acidity of R--XH (R=H, CH(3), CH(2)CH(3), CH==CH(2), C[triple chemical bond]CH; X=Be, Mg, Ca) alkaline-earth-metal derivatives has been investigated through the use of high-level CCSD(T) calculations by using a 6-311+G(3df,2p) basis set. BeH(2) is a stronger acid than BH(3) and CH(4) for two concomitant reasons: 1) the dissociation energy of the Be--H bond is smaller than the dissociation energies of the B--H and C--H bonds, and 2) the electron affinity of BeH(.) is larger in absolute value than those of BH(2) (.) and CH(3) (.). The acidity also increases on going from BeH(2) to MgH(2) due to these two same factors. Quite importantly, despite the fact that the X--H bonds in the R--XH (X=Mg, Ca) derivatives exhibit the expected X(delta+)--H(delta-) polarity, they behave as metal acids in the gas phase and only Be derivatives behave as carbon acids in the gas phase. The ethylberyllium hydride exhibits an unexpected high acidity compared with the methyl derivative because deprotonation of the system is accompanied by a cyclization that stabilizes the anion. Similarly to that found for derivatives that contain heteroatoms from groups 14, 15, and 16, the unsaturated compounds are stronger acids than the saturated counterparts, with the only exception of the Ca-vinyl derivative. Most importantly, among ethyl, vinyl, and ethynyl derivatives containing a heteroatom of the main group of the Periodic Table, those containing Be, Mg, and Ca are among the strongest gas-phase acids.

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Acidity Trends in α,β‐Unsaturated Sulfur, Selenium, and Tellurium Derivatives: Comparison with C‐, Si‐, Ge‐, Sn‐, N‐, P‐, As‐, and Sb‐Containing Analogues

Cited by 28 publications

References 51 publications

Unexpected Gas-Phase Ion Chemistry Results Unraveled by Computational Chemistry

Unexpected Gas-Phase Ion Chemistry Results Unraveled by Computational Chemistry

The Ever‐Surprising Chemistry of Boron: Enhanced Acidity of Phosphine⋅Boranes

α,β‐Unsaturated and Saturated Derivatives of Be, Mg, and Ca: Are They Carbon or Metal Acids in the Gas Phase?

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