Hydrogen Bond Lifetimes and Energetics for Solute/Solvent Complexes Studied with 2D-IR Vibrational Echo Spectroscopy

Zheng, Junrong; Fayer, M. D.

doi:10.1021/ja067760f

Cited by 85 publications

(174 citation statements)

References 27 publications

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“…[17][18][19]21 The exchange kinetics can be extracted from analyzing the time dependent peak volumes. 17,21,22 If spectral diffusion is fast compared to the chemical exchange rate, the peak intensities can be used to obtain the chemical exchange dynamics. 17,21 The 2D IR signal is affected by four dynamic processes: chemical exchange, vibrational relaxation of the OD stretch excitation, orientational relaxation of the species, and the spectral diffusion.…”

Section: Resultsmentioning

confidence: 99%

“…4 Recently nonlinear IR techniques especially 2D IR methods [5][6][7][8][9][10][11][12][13] have overcome the difficulties. [14][15][16][17][18][19][20][21] The techniques have an intrinsic fast temporal resolution that can be <100 fs. In addition, perturbations of the dynamics using 2D-IR methods have been shown to be negligible, 17 and there are well defined internal tests to determine if the true equilibrium dynamics are in fact being observed.…”

Section: Introductionmentioning

confidence: 99%

“…20 We found that there is a clear correlation between the enthalpies of formation of the complexes and the dissociation time constants (inverse of the dissociation rate constants), and the correlation can be described by an equation similar to the Arrhenius equation. 20,21 It was determined that the solute-solvent complex dissociation time constant is linearly related to exp(-∆H 0 /RT) where ∆H 0 is the complex enthalpy of formation, R is the gas constant, and T is the absolute temperature. This observation is interesting and important.…”

Section: Introductionmentioning

confidence: 99%

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Solute−Solvent Complex Kinetics and Thermodynamics Probed by 2D-IR Vibrational Echo Chemical Exchange Spectroscopy

Zheng

Fayer

2008

J. Phys. Chem. B

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The formation and dissociation kinetics of a series of triethylsilanol/solvent weakly hydrogen bonding complexes with enthalpies of formation ranging from -1.4 to -3.3 kcal/mol are measured with ultrafast two-dimensional infrared (2D IR) chemical exchange spectroscopy in liquid solutions at room temperature. The correlation between the complex enthalpies of formation and dissociation rate constants can be expressed with an equation similar to the Arrhenius equation. The experimental results are in accord with previous observations on eight phenol/solvent complexes with enthalpies of formation from -0.6 to -2.5 kcal/mol. It was found that the inverse of the solute-solvent complex dissociation rate constant is linearly related to exp(-∆H 0 /RT) where ∆H 0 is the complex enthalpy of formation. It is shown here, that the triethylsilanol-solvent complexes obey the same relationship with the identical proportionality constant, that is, all 13 points, five silanol complexes and eight phenol complexes, fall on the same line. In addition, features of 2D IR chemical exchange spectra at long reaction times (spectral diffusion complete) are explicated using the triethylsilanol systems. It is shown that the off-diagonal chemical exchange peaks have shapes that are a combination (outer product) of the absorption line shapes of the species that give rise to the diagonal peaks.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Solute−Solvent Complex Kinetics and Thermodynamics Probed by 2D-IR Vibrational Echo Chemical Exchange Spectroscopy

Zheng

Fayer

2008

J. Phys. Chem. B

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“…The experimentally determined electrostatic interaction energy compared well with the theoretically derived from DFT computations. Vibrational echo spectroscopy study on the same interaction revealed that the time constant of the complex was only 8 picoseconds [28,29]. In a previous work, we presented results from an IR spectroscopic and theoretical investigation for a series of 20 π-hydrogen-bonded complexes of monosubstituted phenols and benzene [16].…”

Section: Introductionmentioning

confidence: 89%

“…This method has also been instrumental in studies of π-hydrogen bonds [6][7][8]. The advances of computational quantum chemistry have opened possibilities for gaining deeper insights into the nature of this type of noncovalent interactions that are of key importance in biology, chemistry, and materials science [9][10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Theoretical vs. Experimental Ir Frequency Shifts Upon Π- Hydrogen Bonding: Complexes of Substituted Phenols With Hexamethylbenzene

Nikolova¹,

Galabov²

2017

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The quality of theoretical prediction of O-H stretching frequency shifts upon π-hydrogen bonding is analyzed for series of ten complexes between monosubstituted phenols and hexamethylbenzene. Computed O-H frequencies from density functional theory computations at B3LYP/6-311++G(2df,2p) were compared with literature spectroscopic data. The results reveal that the applied theoretical method predicts with an excellent accuracy the O-H frequency shifts [Δν(OH)] upon π-hydrogen bond formation. Comparisons with analogous theoretical and experimental data for benzene complexes with substituted phenols reveal the magnitude of the methyl groups' hyperconjugative effects on interaction energies and frequency shifts. The induced by phenol substituents variations in bonding energies and Δν(OH) are rationalized using theoretically evaluated and experimental parameters.

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Glucose Epimerization‐Modulated Phytochemicals Constructing Carrier‐Free Hydrogel for Regulation of Macrophage Phenotype to Promote Wound Healing

Lu,

Zhao,

Wang

et al. 2024

Adv Funct Materials

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The self‐assembly of phytochemicals with multiple chiral centers is receiving significant attention for its potential in biomedical applications. However, the impact of single chiral center epimerization on molecular self‐assembly remains unexplored. Herein, the self‐assembly behavior and bioactivities of 1,2,3,4,6‐penta‐O‐galloyl‐α‐D‐glucose (α‐D‐PGG) and 1,2,3,4,6‐penta‐O‐galloyl‐β‐D‐glucose (β‐D‐PGG) is examined, a pair of natural ellagitannins abundant in plants. Interestingly, β‐D‐PGG formed a hydrogel without modification, while α‐D‐PGG does not. This occurred due to the balanced distribution of aromatic rings and phenolic hydroxyl groups in β‐D‐PGG, facilitating self‐assembly via hydrogen bonding and π–π stacking into nanofibers. In contrast, α‐D‐PGG's self‐assembly is inhibited by steric hindrance. Notably, β‐D‐PGG hydrogel demonstrated exceptional antibacterial activity and by regulating macrophage polarization toward the M2 phenotype, thereby reducing inflammation. This study not only reveals the distinct self‐assembly behaviors of glucose derivatives but also offers new insights into their potential in biomedical applications, such as wound healing.

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Hydrogen Bond Lifetimes and Energetics for Solute/Solvent Complexes Studied with 2D-IR Vibrational Echo Spectroscopy

Cited by 85 publications

References 27 publications

Solute−Solvent Complex Kinetics and Thermodynamics Probed by 2D-IR Vibrational Echo Chemical Exchange Spectroscopy

Solute−Solvent Complex Kinetics and Thermodynamics Probed by 2D-IR Vibrational Echo Chemical Exchange Spectroscopy

Theoretical vs. Experimental Ir Frequency Shifts Upon Π- Hydrogen Bonding: Complexes of Substituted Phenols With Hexamethylbenzene

Glucose Epimerization‐Modulated Phytochemicals Constructing Carrier‐Free Hydrogel for Regulation of Macrophage Phenotype to Promote Wound Healing

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