Pressure-Induced Aggregation of Associating Liquids as a Driving Force Enhancing Hydrogen Bond Cooperativity.
Barbara HachułaPatryk WłodarczykKarolina JurkiewiczJoanna GrelskaDemetrio SceltaSamuele FanettiMarian PaluchSebastian PawlusKamil KaminskiPublished in: The journal of physical chemistry letters (2023)
The behavior of hydrogen bonds under extreme pressure is still not well understood. Until now, the shift of the stretching vibration band of the X-H group (X = the donor atom) in infrared spectra has been attributed to the variation in the length of the covalent X-H bond. Herein, we combined infrared spectroscopy and X-ray diffraction experimental studies of two H-bonded liquid hexane derivatives, i.e., 2-ethyl-1-hexanol and 2-ethyl-1-hexylamine, in diamond anvil cells at pressures up to the GPa level, with molecular dynamics simulations covering similar thermodynamic conditions. Our findings revealed that the observed changes in the X-H stretching vibration bands under compression are not primarily due to H-bond shortening resulting from increased density but mainly due to cooperative enhancement of H-bonds caused by intensified molecular clustering. This sheds new light on the nature of H-bond interactions and the structure of liquid molecular systems under compression.
Keyphrases
- molecular dynamics simulations
- ionic liquid
- transition metal
- single molecule
- induced apoptosis
- high frequency
- single cell
- electron transfer
- molecular docking
- high resolution
- cell cycle arrest
- high glucose
- diabetic rats
- climate change
- drug induced
- cell death
- signaling pathway
- endothelial cells
- crystal structure
- pi k akt
- structure activity relationship