Chemical exchange 2D IR of hydrogen-bond making and breaking

AUTOR(ES)

Kim, Yung Sam

FONTE

National Academy of Sciences

RESUMO

The involvement of chemical exchange in 2D IR heterodyne echo spectroscopy is characterized through the hydrogen-bond exchange between CH3OH and the CN of CH3CN. The exchange dynamics on the hydrogen-bond potential surfaces associated with different quantum states of the high-frequency CN stretching mode contributes to strong cross peaks between CN groups in two different chemical configurations and provides firm evidence of the hydrogen exchange between them. In analogy with NMR, the chemical exchange is seen in both slow and dynamic regimes. The relative magnitudes of the cross peaks at various population periods measure the picosecond regime time constants for H-bond transfer, whereas the temperature dependences indicate that the activation energy for the exchange from the H-bonded state to the free state is ≈6.2 kJ·mol–1. The results suggest that the hydrogen-bond dynamics is very similar in both vibrational quantum states of CN, suggesting that this stretching mode is not strongly coupled to the H-bond breaking reaction coordinate. The likely manifestations of chemical exchange in 2D IR experiments are discussed.

Documentos Relacionados

• Unified description of temperature-dependent hydrogen-bond rearrangements in liquid water
• Identification of slow correlated motions in proteins using residual dipolar and hydrogen-bond scalar couplings
• Solvent hydrogen-bond network in protein self-assembly: solvation of collagen triple helices in nonaqueous solvents.
• Specific collapse followed by slow hydrogen-bond formation of β-sheet in the folding of single-chain monellin
• Dual-frequency 2D-IR spectroscopy heterodyned photon echo of the peptide bond