Your search keyword '"Razo J"' showing total 5 results

1. Separating the effects of repulsive and attractive forces on the phase diagram, interfacial, and critical properties of simple fluids.

Author

Fuentes-Herrera, M., Moreno-Razo, J. A., Guzmán, O., López-Lemus, J., and Ibarra-Tandi, B.

Subjects

*PHASE diagrams, *INTERFACIAL bonding, *FLUID dynamics, *MOLECULAR interactions, *VAPORIZATION

Abstract

Molecular simulations in the canonical and isothermal-isobaric ensembles were performed to study the effect of varying the shape of the intermolecular potential on the phase diagram, critical, and interfacial properties of model fluids. The molecular interactions were modeled by the Approximate Non-Conformal (ANC) theory potentials. Unlike the Lennard-Jones or Morse potentials, the ANC interactions incorporate parameters (called softnesses) that modulate the steepness of the potential in their repulsive and attractive parts independently. This feature allowed us to separate unambiguously the role of each region of the potential on setting the thermophysical properties. In particular, we found positive linear correlation between all critical coordinates and the attractive and repulsive softness, except for the critical density and the attractive softness which are negatively correlated. Moreover, we found that the physical properties related to phase coexistence (such as span of the liquid phase between the critical and triple points, variations in the P-T vaporization curve, interface width, and surface tension) are more sensitive to changes in the attractive softness than to the repulsive one. Understanding the different roles of attractive and repulsive forces on phase coexistence may contribute to developing more accurate models of liquids and their mixtures. [ABSTRACT FROM AUTHOR]

Published

2016

2. Isotropic-nematic phase transition in the Lebwohl-Lasher model from density of states simulations.

Author

Shekhar, Raj, Whitmer, Jonathan K., Malshe, Rohit, Moreno-Razo, J. A., Roberts, Tyler F., and de Pablo, Juan J.

Subjects

PHASE transitions, MATHEMATICAL models, COMPUTER simulation, EXTRAPOLATION, SPINODAL decomposition (Chemistry), LIQUID crystals, TEMPERATURE effect

Abstract

Density of states Monte Carlo simulations have been performed to study the isotropic-nematic (IN) transition of the Lebwohl-Lasher model for liquid crystals. The IN transition temperature was calculated as a function of system size using expanded ensemble density of states simulations with histogram reweighting. The IN temperature for infinite system size was obtained by extrapolation of three independent measures. A subsequent analysis of the kinetics in the model showed that the transition occurs via spinodal decomposition through aggregation of clusters of liquid crystal molecules. [ABSTRACT FROM AUTHOR]

Published

2012

3. Anomalous dynamic arrest of non-interacting spheres (“polymer”) diluted in a hard-sphere (“colloid”) liquid.

Author

Lázaro-Lázaro, E., Moreno-Razo, J. A., and Medina-Noyola, M.

Subjects

*LIQUIDS spectra, *MOLECULAR dynamics, *ADIABATIC compression, *PACKING fractions, *CHEMICAL kinetics

Abstract

Upon compression, the equilibrium hard-sphere liquid [pair potential uHS(r)] freezes at a packing fraction ϕf = 0.494 or, if crystallization is prevented, becomes metastable up to its glass transition at ϕg ≈ 0.58. Throughout the fluid regime (ϕ < ϕg), we are, thus, certain that this model liquid does not exhibit any form of kinetic arrest. If, however, a small portion of these spheres (packing fraction ϕ2 ≪ ϕ) happen to ignore each other [u22(r) = 0] but do not ignore the remaining “normal” hard spheres [u12(r) = u21(r) = u11(r) = uHS(r)], whose packing fraction is thus ϕ1 = ϕ − ϕ2, they run the risk of becoming dynamically arrested before they demix from the “normal” particles. This unexpected and counterintuitive scenario was first theoretically predicted and then confirmed by simulations. [ABSTRACT FROM AUTHOR]

Published

2018

4. Thermodynamic scaling and corresponding states for the self-diffusion coefficient of non-conformal soft-sphere fluids.

Author

Rodríguez-López, Tonalli, Moreno-Razo, J. Antonio, and del Río, Fernando

Subjects

*THERMODYNAMICS, *SCALING laws (Statistical physics), *SELF-diffusion (Solid state physics), *COEFFICIENTS (Statistics), *FLUIDS, *COLLISIONS (Physics), *POTENTIAL theory (Physics), *STATISTICAL mechanics

Abstract

In this work, we explore transport properties of a special type of repulsive spheres that exhibit remarkable scaling of their thermodynamic properties. In order to accomplish that we propose a new way to derive and express effective hard-sphere diameters for transport properties of simple fluids. The procedure relies on mapping the system's transport properties, in the low density limit, to the hard-sphere fluid. We have chosen a set of soft-sphere systems characterised by a well-defined variation of their softness. These systems represent an extension of the repulsive Lennard-Jones potential widely used in statistical mechanics of fluids and are an accurate representation of the effective repulsive potentials of real systems. The self-diffusion coefficient of the soft-sphere fluids is obtained by equilibrium molecular dynamics. The soft-sphere collision integrals of different systems are shown to follow quite simple relationships between each other. These collision integrals are incorporated, through the definition of the effective hard-sphere diameter, in the resulting equation for the self-diffusion coefficient. The approach followed exhibits a density rescaling that leads to a single master curve for all systems and temperatures. The scaling is carried through to the level of the mean-squared displacement. [ABSTRACT FROM AUTHOR]

Published

2013

5. Modeling flows of confined nematic liquid crystals.

Author

Hernández-Ortiz JP, Gettelfinger BT, Moreno-Razo J, and de Pablo JJ

Abstract

The flow of nematic liquid crystals in tightly confined systems was simulated using a molecular theory and an unsymmetric radial basis function collocation approach. When a nematic liquid crystal is subjected to a cavity flow, we find that moderate flows facilitate the relaxation of the system to the stable defect configuration observed in the absence of flow. Under more extreme flow conditions, e.g., an Ericksen number Er=20, flows can alter the steady-state defect structure observed in the cavity. The proposed numerical method was also used to examine defect annihilation in a thin liquid crystal film. The flows that arise from shear stresses within the system result in a higher velocity for s = +1∕2 defect than for the defect of opposing charge. This higher velocity can be attributed to reactive stresses within the deformed liquid crystal, which result in a net flow that favors the motion of one defect. These two examples serve to illustrate the usefulness of radial basis functions methods in the context of liquid crystal dynamics both at and beyond equilibrium.

Published

2011