IR Spectrum of the H5O2+ Cation in the Context of Proton Disolvates L−H+−L

Stoyanov, Evgenii S.; Reed, Christopher A.

doi:10.1021/jp062879w

Cited by 61 publications

(127 citation statements)

References 57 publications

Supporting

Mentioning

116

Contrasting

Unclassified

Order By: Relevance

“…[35][36][37] The present contribution is related to the previously published work. 12,14,21,[38][39][40][41] The one-dimensional anharmonic vibrational O-H stretching frequency of MPANO, calculated to 1699 cm -1 , is notably lower than the value of 2129 cm -1 obtained in the same way for an unsubstituted analog (picolinic acid N-oxide, PANO). This indicates that the hydrogen bonding of MPANO is stronger than that of PANO, a fact that is reflected in the infrared and NMR experimental findings.…”

Section: D Pes and The Expectation Valuesmentioning

confidence: 61%

Infrared Spectrum of 4-Methoxypicolinic Acid N-Oxide: Computation of Asymmetric O−H Stretching Band

Balazic

Stare

Mavri

2007

J. Chem. Inf. Model.

View full text Add to dashboard Cite

In this article we studied the strong intramolecularly hydrogen-bonded system 4-methoxypicolinic acid N-oxide. The potential energy surface V = V(rOH,rOO) and the corresponding dipole moment function were calculated using the DFT B3LYP/6-31+G(d,p) level of approximation. The time-independent vibrational Schrödinger equation was solved using a rectangular grid basis set and shifted Gaussian basis set. The vibrational spectrum and metric parameters were also calculated. Effects of deuteration were considered. The calculated vibrational spectra were compared with the experimental spectra. The vibrational transition corresponding to asymmetric O-H stretching that occurs at about 1400 cm-1 compares well with the experimentally assigned O-H asymmetric stretching band centered at 1380 cm-1. The corresponding asymmetric O-D stretching band was predicted to be at 1154 cm-1, while the experimental O-D band was not assigned due to its very low intensity. Several overtones and hot transitions of significant intensities were located in the vicinity of the fundamental O-H stretching frequency, effectively broadening the infrared absorption attributed to the O-H stretching mode. This is in a good agreement with the observed broad protonic absorptions found in the infrared spectra of the title compound and its analogs. We have shown that the Gaussian basis set is the method of choice for a two-dimensional vibrational problem that requires several hundreds of vibrational basis functions and when high accuracy of the eigenvalues is required or when extending the calculations to more vibrational degrees of freedom. We have also demonstrated that for a large number of basis functions the Gramm-Schmidt orthogonalization procedure outperforms symmetric and canonical orthogonalization schemes.

show abstract

Section: D Pes and The Expectation Valuesmentioning

confidence: 61%

Infrared Spectrum of 4-Methoxypicolinic Acid N-Oxide: Computation of Asymmetric O−H Stretching Band

Balazic

Stare

Mavri

2007

J. Chem. Inf. Model.

View full text Add to dashboard Cite

show abstract

“…In analogy with 1 H NMR, carbon 1 has the largest relative shift but the difference to 2 + 6 is much more pronounced and cannot be interpreted as a mere effect of the change of relative directions of the aromatic rings. Bearing in mind the theoretical predictions of relatively strong interactions of the hydroxonium ion or its hydrate with aromatic π systems, [23,24] we propose that the large relative shift of signal 1 both in 1 H and 13 C NMR spectra is partly due to additional hydrogen bonds of the ion to the π electrons at the corresponding carbon atoms. The spectroscopic evidence thus leads to the idea of H 3 O + being bound to the two Ar-O-CH 2 oxygen atoms of one of the opposite moieties of 1 and to the carbons 1 of the opposite moiety.…”

Section: Nmr Spectramentioning

confidence: 88%

“…The optimal O-O distance in the complexed H 5 O 2 + is predicted to be 2.41´Å, which is the usual distance observed. [24] The structure of the complex has almost C 4h symmetry, which would explain the simplicity of NMR spectra. However, there are several other experimental observations, which do not quite agree with this possibility: (i) our infrared spectra do not indicate that H 5 O 2 + is the main proton hydrate in our systems; (ii) the complex could exchange H 5 O 2 + by an intermolecular mechanism, which would give the corresponding part of the dynamics observed by NMR, but apparently there is no reason for any intramolecular dynamics in this case; (iii) in this optimized arrangement, the outer protons of H 5 O 2 + form strong hydrogen bonds with the phenoxy-oxygen atoms but none with the aromatic systems.…”

Section: Quantum Mechanical Calculationsmentioning

confidence: 99%

“…In the case of proton lower hydrates, such possibility appears to be warranted by the general tendency of cations to bind to suitably oriented π -systems, [22] even more so considering the experimentally proven π -interaction of H 3 O + and H 5 O 2 + with benzene. [23,24] There is another interesting problem connected with a cation binding to a 1,3-alternate calix [4]arene. As binding of two cations to one molecule is highly improbable on grounds of energy, an asymmetric complex with one coordination site occupied and one vacant should be formed if the ion is H 3 O + .…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Cooperative interaction of H₃O⁺ with 1,3‐alternate tetrapropoxycalix[4]arene: NMR and theoretical study

Křı́ž

Dybal

Makrlík

et al. 2008

Magnetic Reson in Chemistry

View full text Add to dashboard Cite

Interaction of H3O+ or H5O2+ with 1,3-alternate tetrapropoxycalix[4]arene (1) was studied in nitrobenzene and dichloromethane using 1H and 13C NMR including transverse and rotating-frame relaxations and density functional level of theory (DFT) quantum calculations. According to NMR, the ion forms an equimolecular complex with 1 with the equilibrium constant K being 3.97 x 10(3) L.mol(-1) at 296 K. The ions are bound by strong hydrogen bonds to the phenoxy-oxygen atoms of one half of 1 and by a medium-strong hydrogen bond to the pi system of the aromatic rings of the other half. The complex appears to have C(4h) symmetry in NMR even when cooling its solution down to 213 K, which could be due either to a genuine symmetry of the complex (if the ion is H5O2+) or to fast structure averaging by ion exchange processes (if the ion is H3O+). Therefore, the dynamics of the system was studied. Using two independent NMR methods (transverse and rotating-frame relaxation), two different exchange processes were discerned with correlation times 25 x 10(-6) and 5 x 10(-6) s, the first being clearly intermolecular and the other being apparently intramolecular. The energetic aspects of the possible exchange processes were examined by DFT quantum calculations. Rotation of H3O+ ion within one binding site with the energy barrier 8.13 kcal/mol is easily possible. Intermolecular exchange by freeing the ion from the complex has too high a barrier but cooperative interaction of the ion with additional water molecules makes it viable. The intramolecular exchange (or hopping) of the H3O+ ion between the two sites of the molecule is not viable in the classical manner, the barrier being 25.6 kcal/mol. Quantum tunneling of the ion is highly improbable, too. Alternative mechanisms including concerted two-ion intermolecular exchange and cooperative interaction with another bound water molecule including complexation with proton dihydrate H5O2+ are discussed.

show abstract

“…This is easily accomplished by replacing the exterior hydrogen atoms with methyl groups [46,47], since the PA of the isolated molecules incrementally increases from 691 to 754 to 792 kJ/mol in going from water to methanol to dimethyl ether, respectively [48]. Consequently, by studying the various proton-bound, binary complexes of water, methanol, and dimethyl ether, we can systematically follow how the difference in proton affinities between the two molecules affects the value of m sp .…”

Section: Substitution Of Exterior Oh Sites With Methyl Groups: Rationmentioning

confidence: 99%

Tuning the intermolecular proton bond in the H5O2+ ‘Zundel ion’ scaffold

Olesen

Guasco

Roscioli

et al. 2011

Chemical Physics Letters

View full text Add to dashboard Cite

IR Spectrum of the H₅O₂⁺ Cation in the Context of Proton Disolvates L−H⁺−L

Cited by 61 publications

References 57 publications

Infrared Spectrum of 4-Methoxypicolinic Acid N-Oxide: Computation of Asymmetric O−H Stretching Band

Infrared Spectrum of 4-Methoxypicolinic Acid N-Oxide: Computation of Asymmetric O−H Stretching Band

Cooperative interaction of H₃O⁺ with 1,3‐alternate tetrapropoxycalix[4]arene: NMR and theoretical study

Tuning the intermolecular proton bond in the H5O2+ ‘Zundel ion’ scaffold

Contact Info

Product

Resources

About

IR Spectrum of the H5O2+ Cation in the Context of Proton Disolvates L−H+−L

Cited by 61 publications

References 57 publications

Infrared Spectrum of 4-Methoxypicolinic Acid N-Oxide: Computation of Asymmetric O−H Stretching Band

Infrared Spectrum of 4-Methoxypicolinic Acid N-Oxide: Computation of Asymmetric O−H Stretching Band

Cooperative interaction of H3O+ with 1,3‐alternate tetrapropoxycalix[4]arene: NMR and theoretical study

Tuning the intermolecular proton bond in the H5O2+ ‘Zundel ion’ scaffold

Contact Info

Product

Resources

About

IR Spectrum of the H₅O₂⁺ Cation in the Context of Proton Disolvates L−H⁺−L

Cooperative interaction of H₃O⁺ with 1,3‐alternate tetrapropoxycalix[4]arene: NMR and theoretical study