publication . Preprint . 2005

Phase transitions in liquids with directed intermolecular bonding

Son, L.; Ryltcev, R.;
Open Access English
  • Published: 10 Oct 2005
Liquids with quasi - chemical bonding between molecules are described in terms of vertex model. It is shown that this bonding results in liquid - liquid phase transition, which occurs between phases with different mean density of intermolecular bonds. The transition may be suggested to be a universal phenomena for those liquids.
arXiv: Condensed Matter::Soft Condensed MatterQuantitative Biology::BiomoleculesPhysics::Fluid Dynamics
Medical Subject Headings: digestive, oral, and skin physiology
free text keywords: Condensed Matter - Statistical Mechanics
Related Organizations
Download from
25 references, page 1 of 2

[1] P. H. Poole, F. Sciortino, U. Essman, and H. E. Stanley, Nature (London) 360, 324 (1992).

[2] E.G.Ponyatovskii, V.V.Sinitsyn, T.A.Pozdnyakova. JETP Lett., 60, 360 (1994).

[3] G.G.Malenkov. Computer simulation of supercooled water and amorphous ice. Proceedings of the NATO Advances Research Workshop, Volga River, on New Kinds of Phase Transitions: Transformations in Disordered Substances, edited by V. V. Brazhkin, S. V. Buldyrev, V. N. Ryzhov, and H. E. Stanley. Kluwer Academic Publishers, Dordrecht, 2002.

[4] C.M. Davis and J. Jarzynski, Mixture Models of Water, ch.10 in Water and Aqueous Solutions. Structure, Thermodynamics, and Transport Processes, R.A. Horne, ed., WileyInterscience, New York (1972).

[5] G.Franzese, M.I.Marques, H.E.Stanley. Intramolecular coupling as a mechanism for a liquid - liquid phase transition. Phys. Rev. E67 (2003) 011103, cond-mat/0112341. [OpenAIRE]

[6] G.Franzese and H.E.Stanley. Liquid - liquid critical point in a Hamiltonian model for water: analytic solution. J.Phys. Cond. Matter 14 (2002) 2201. [OpenAIRE]

[7] E. W. Fischer, Physica A201 (1993) 183, and references therein.

[8] S.A. Kivelson, X. Zao, D. Kivelson T. M. Fisher and C. Knobler. J. Chem. Phys. 101 (1994) 2391.

[9] N.B.Rozhdestvenskaya and L.V. Smirnova, JETP Lett. 44 (1986) 1166.

[10] F. J. Bermejo, M. Garcia-Hernandez, W. S. Howells, R. Burriel, F. J. Mompea´n, D. Martin, Phys. Rev. E48 (1993) 2766.

[11] D. Jalabert, J. B. Robert, H. Roux-Buisson, J. P. Kintzinger, J. M. Lehn, R. Zinzius, D. Canet and P. Tekely, Europhys. Lett. 115 (1991) 435; J. B. Robert, J. C. Boubel and D. Canet, Molecular Physics 90 (1997) 399; L. Gauthier, J. B. Robert, and D. Canet, Journal of Molecular Liquids 85 (2000) 77.

[12] N. B. Rozhdestvenskaya and L. V. Smirnova, J. Chem. Phys. 195 (1991) 1223 .

[13] L. Letamendia, M. Belkadi, O. Eloutassi, G. Nouchi, C. Vaucamps, S. Iakovlev, N. Rozhdestvenskaya, L V. Smirnova, M. Runova, Phys. Rev. E48 (1993) 3572.

[14] L.Letamendia, M.Belkadi, O. Eloutassi, E.Pru-Lestret, G. Nouchi, J. Rouch, D. Blaudez, F.Mallamace, N.Micali, C.Vasi, Phys. Rev. E54 (1996) 5327.

[15] I.Prigogine. The molecular theory of solutions. North - Holland and Interscience, Amsterdam - New York, 1957.

25 references, page 1 of 2
Powered by OpenAIRE Research Graph
Any information missing or wrong?Report an Issue