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Wrapping Up Hydrophobic Hydration: Locality Matters.

V Conti Nibali1, S Pezzotti1,2, F Sebastiani1

  • 1Department of Physical Chemistry II, Ruhr University Bochum, 44780 Bochum, Germany.

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|May 28, 2020
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Summary
This summary is machine-generated.

Molecular dynamics simulations reveal two water populations around tert-butanol: "HB-wrap" and "HB-hydration2bulk". These distinct hydration states explain the temperature-dependent solvation entropy and its crossover from entropy to enthalpy dominance.

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Area of Science:

  • Physical Chemistry
  • Computational Chemistry
  • Biophysics

Background:

  • Water's role as a universal solvent is critical in biomolecular processes like folding and recognition.
  • Understanding hydrophobic hydration is key to deciphering free energy differences that govern molecular function.
  • Solvation entropy's temperature dependence is a crucial factor in molecular interactions.

Purpose of the Study:

  • To elucidate the molecular mechanisms behind hydrophobic hydration using computational simulations.
  • To differentiate and characterize distinct water populations in the hydration shell of tert-butanol.
  • To correlate these water populations with experimentally observed spectral features and thermodynamic properties.

Main Methods:

  • Employed ab initio and classical molecular dynamics simulations to model tert-butanol solvation.
  • Analyzed hydration water populations, identifying 'HB-wrap' and 'HB-hydration2bulk' states.
  • Correlated simulation results with experimental hydration water spectra (164 cm⁻¹ and 195 cm⁻¹ bands).

Main Results:

  • Identified two distinct water populations ('HB-wrap' and 'HB-hydration2bulk') in tert-butanol's hydration shell.
  • Attributed experimental spectral bands at 164 cm⁻¹ and 195 cm⁻¹ to these specific water populations.
  • Established a quantitative link between water coordination motifs and temperature-dependent solvation entropy.

Conclusions:

  • The distinct thermodynamic signatures of 'HB-wrap' and 'HB-hydration2bulk' populations explain solvation entropy changes.
  • These findings rationalize the observed crossover from entropy to enthalpy dominance in solvation at higher temperatures.
  • Provides a molecular basis for understanding hydrophobic hydration effects in biological and chemical systems.