| ID | 34140 |
| FullText URL | |
| Author | |
| Abstract | Molecular dynamics simulations demonstrate that there are at least two classes of quasi-two-dimensional solid water into which liquid water confined between hydrophobic surfaces freezes spontaneously and whose hydrogen-bond networks are as fully connected as those of bulk ice. One of them is the monolayer ice and the other is the bilayer solid which takes either a crystalline or an amorphous form. Here we present the phase transformations among liquid, bilayer amorphous (or crystalline) ice, and monolayer ice phases at various thermodynamic conditions, then determine curves of melting, freezing, and solid-solid structural change on the isostress planes where temperature and intersurface distance are variable, and finally we propose a phase diagram of the confined water in the temperature-pressure-distance space.
|
| Keywords | MOLECULAR-DYNAMICS SIMULATION
CONFINED WATER
LIQUID WATER
SOLVATION FORCES; CARBON NANOTUBES
BILAYER ICE
EQUILIBRIA
TRANSITION
WALLS
INTERFACE
|
| Note | Digital Object Identifer:10.1063/1.1861879
Published with permission from the copyright holder. This is the institute's copy, as published in Journal of Chemical Physics, Mar 2005, Volume 122, Issue 10. Publisher URL:http://dx.doi.org/10.1063/1.1861879 Direct access to Thomson Web of Science record Copyright © 2005 American Institute of Physics |
| Published Date | 2005-03-08
|
| Publication Title |
Journal of Chemical Physics
|
| Volume | volume122
|
| Issue | issue10
|
| Publisher | American Institute of Physics
|
| Content Type |
Journal Article
|
| language |
English
|
| Copyright Holders | American Institute of Physics
|
| File Version | publisher
|
| Refereed |
True
|
| DOI | |
| PubMed ID | |
| Web of Science KeyUT | |
| Submission Path | physics_general/26
|
