A single-bond approach to orientation-dependent interactions and its implications for liquid water
10.1063/1.479540
Crossref journal-article
AIP Publishing
The Journal of Chemical Physics (317)
Abstract

A simple model of an associating fluid is proposed that accounts for the fact that hydrogen bonds are highly directional and favor the formation of locally open structures. The resulting analytical equation of state reproduces the distinguishing thermodynamic features of liquid water. In contrast to previous models in which the relationship between bonding and bulk density is assumed a priori, the extent of hydrogen bonding is derived in the present work from a simple microscopic model. Furthermore, by altering the parameters which control the geometric constraints on bonding, the model is able to exhibit the two thermodynamically consistent scenarios that can explain the observed behavior of supercooled liquid water, namely the two-critical-point and singularity-free scenarios. This suggests that the two scenarios are closely related through subtle features of the hydrogen-bond geometry.

Authors 4
  1. Thomas M. Truskett (first)
  2. Pablo G. Debenedetti (additional)
  3. Srikanth Sastry (additional)
  4. Salvatore Torquato (additional)
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Dates
Type When
Created 23 years ago (July 26, 2002, 8:17 a.m.)
Deposited 1 year, 6 months ago (Feb. 5, 2024, 12:01 p.m.)
Indexed 3 weeks, 1 day ago (Aug. 2, 2025, 12:54 a.m.)
Issued 26 years ago (Aug. 8, 1999)
Published 26 years ago (Aug. 8, 1999)
Published Print 26 years ago (Aug. 8, 1999)
Funders 0

None

@article{Truskett_1999, title={A single-bond approach to orientation-dependent interactions and its implications for liquid water}, volume={111}, ISSN={1089-7690}, url={http://dx.doi.org/10.1063/1.479540}, DOI={10.1063/1.479540}, number={6}, journal={The Journal of Chemical Physics}, publisher={AIP Publishing}, author={Truskett, Thomas M. and Debenedetti, Pablo G. and Sastry, Srikanth and Torquato, Salvatore}, year={1999}, month=aug, pages={2647–2656} }