• Corpus ID: 232075741

What is Liquid ? [in two dimensions]

@inproceedings{Travis2021WhatIL,
  title={What is Liquid ? [in two dimensions]},
  author={Karl P Travis and William Graham Hoover and Carol Griswold Hoover and Amanda Bailey Hass},
  year={2021}
}
We consider the practicalities of defining, simulating, and characterizing “Liquids” from a pedagogical standpoint based on atomistic computer simulations. For simplicity and clarity we study two-dimensional systems throughout. In addition to the infinite-ranged Lennard-Jones 12/6 potential we consider two shorter-ranged families of pair potentials. At zero pressure one of them includes just nearest neighbors. The other longer-ranged family includes twelve additional neighbors. We find that… 
View PDF on arXiv

References

SHOWING 1-10 OF 22 REFERENCES
Time-Symmetry Breaking in Hamiltonian Mechanics. III. A Memoir for Douglas James Henderson [1934-2020].
Following Berni Alder [1] and Francis Ree [2], Douglas Henderson was the third of Bill's California coworkers from the 1960s to die in 2020. Motivated by Doug's death we undertook better to
Supercritical Fluid Gaseous and Liquid States: A Review of Experimental Results
TLDR
It is concluded that the body of extensive scientific experimental evidence has never supported the Andrews–van der Waals theory of continuity of liquid and gas, or the existence of a singular critical point with universal scaling properties.
John Adair Barker 1925-1995
Atomistic computer simulations of shock waves
I present a brief history, from my own personal perspective, of molecular dynamics (MD) computer simulations of shock waves without chemical reaction. Beginning with radiation-damage cascades in the
EXACT SOLUTION OF THE PERCUS-YEVICK INTEGRAL EQUATION FOR HARD SPHERES
ABS>The equation of state and the pair distribution for the Percus- Yevick integral equation for the radiai distribution function of a classical fluid are obtained in closed form for the prototype of
Phase diagram of the two-dimensional Lennard-Jones system; Evidence for first-order transitions
Analysis of Classical Statistical Mechanics by Means of Collective Coordinates
The three-dimensional classical many-body system is approximated by the use of collective coordinates, through the assumed knowledge of two-body correlation functions. The resulting approximate
Dynamics of phase separation in two-dimensional fluids: Spinodal decomposition
Preliminary Results from a Recalculation of the Monte Carlo Equation of State of Hard Spheres
Triple-point coexistence properties of the lennard-jones system
...
...