Leticia Lopez-FloresNorthwestern University | NU · McCormick School of Engineering and Applied Science
Leticia Lopez-Flores
Doctor of Philosophy (Apply Physics)
About
19
Publications
1,733
Reads
How we measure 'reads'
A 'read' is counted each time someone views a publication summary (such as the title, abstract, and list of authors), clicks on a figure, or views or downloads the full-text. Learn more
287
Citations
Introduction
Leticia Lopez-Flores currently works at Northwestern University. Leticia does research in Condensed Matter Physics. Their current project is 'Study equivalence and non-equilibrium process'.
Publications
Publications (19)
We propose a first-principles theoretical approach for the description of the aging of the linear viscoelastic properties of a colloidal liquid after a sudden quench into a dynamically arrested (glass or gel) state. Specifically, we couple a general expression for the time-evolving shear-stress relaxation function η(τ;t) (whose τ-integral is the in...
Acid–base equilibria directly influence the functionality and behavior of particles in a system. Due to the ionizing effects of acid–base functional groups, particles will undergo charge exchange. The degree of ionization and their intermolecular and electrostatic interactions are controlled by varying the pH and salt concentration of the solution...
Amorphous solids, such as glasses and gels, arise as the asymptotic limit of non-equilibrium and irreversible relaxation aging processes. These amorphous solids form when the system is suddenly and deeply quenched in the dynamic arrest region. We use the non-equilibrium self-consistent generalized Langevin equation (NE-SCGLE) theory to investigate...
Colloidal clusters and gels are ubiquitous in science and technology. Particle softness has a strong effect on interparticle interactions; however, our understanding of the role of this factor in the formation of colloidal clusters and gels is only beginning to evolve. Here, we report the results of experimental and simulation studies of the impact...
The interplay of liquid-liquid phase separation (LLPS) and dynamical arrest can lead to the formation of gels and glasses, which is relevant for such diverse fields as condensed matter physics, materials science, food engineering and pharmaceutical industry. In this context, protein solutions exhibit remarkable equilibrium and non-equilibrium behav...
The interplay of phase separation and dynamical arrest can lead to the formation of gels and glasses, which is relevant for such diverse fields as hard and soft condensed matter physics, materials science, food engineering and pharmaceutical industry. Here, the non-equilibrium states as well as the interactions of globular proteins are analyzed. Ly...
The fundamental understanding of the dynamic and transport properties of liquids is crucial for the better processing of most materials. The usefulness of this understanding increases when it involves general scaling rules, such as the concept of the hard-sphere dynamic universality class, which provides a unifying scaling of the dynamics of soft-s...
Recent experiments and computer simulations have revealed intriguing phenomenological fingerprints of the interference between the ordinary equilibrium gas-liquid phase transition and the non-equilibrium glass and gel transitions. We thus now know, for example, that the liquid-gas spinodal line and the glass transition loci intersect at a finite te...
The non-equilibrium self-consistent generalized Langevin equation (NE-SCGLE) theory of irreversible processes in liquids has been proposed as a theoretical framework capable of predicting the age- and preparation-dependent properties of highly ubiquitous non-equilibrium amorphous solids, such as like glasses and gels. By this formalism, we discuss...
A major stumbling block for statistical physics and materials science has been the lack of a universal principle that allows us to understand and predict elementary structural, morphological, and dynamical properties of nonequilibrium amorphous states of matter. The recently developed nonequilibrium self-consistent generalized Langevin equation the...
A major stumbling block for statistical physics and materials science has been the lack of a uni- versal principle that allows us to understand and predict elementary structural, morphological, and dynamical properties of non-equilibrium amorphous states of matter. The recently-developed non- equilibrium self-consistent generalized Langevin equatio...
The Ornstein-Uhlenbeck stochastic process is an exact mathematical model providing accurate representations of many real dynamic processes in systems in a stationary state. When applied to the description of random motion of particles such as that of Brownian particles, it provides exact predictions coinciding with those of the Langevin equation bu...
The non-equilibrium self-consistent generalized Langevin equation theory of irreversible relaxation [P. E. Ramŕez-González and M. Medina-Noyola, Phys. Rev. E 82, 061503 (2010); 82, 061504 (2010)] is applied to the description of the non-equilibrium processes involved in the spinodal decomposition of suddenly and deeply quenched simple liquids. For...
We perform systematic simulation experiments on model systems with soft-sphere repulsive interactions to test the predicted dynamic equivalence between soft-sphere liquids with similar static structure. For this we compare the simulated dynamics (mean squared displacement, intermediate scattering function, α-relaxation time, etc.) of different soft...
We perform systematic simulation experiments on model systems with
soft-sphere repulsive interactions to test the predicted dynamic equivalence
between soft-sphere liquids with similar static structure. For this we compare
the simulated dynamics (mean squared displacement, intermediate scattering
function, {\alpha}-relaxation time, etc.) of differe...
Using the generalized Langevin equation formalism and the process of
contraction of the description we derive a general memory function equation for
the thermal fluctuations of the local density of a simple atomic liquid. From
the analysis of the long-time limit of this equation, a striking equivalence is
suggested between the long-time dynamics of...
We derive the time-evolution equation that describes the Brownian motion of
labeled individual tracer particles in a simple model atomic liquid (i.e., a
system of $N$ particles whose motion is governed by Newton's second law, and
interacting through spherically symmetric pairwise potentials). We base our
derivation on the generalized Langevin equat...
We employ the principle of dynamic equivalence between soft-sphere and hard-sphere fluids [Phys. Rev. E 68, 011405 (2003)] to describe the interplay of the effects of varying the density n, the temperature T, and the softness (characterized by a softness parameter ν(-1)) on the dynamics of glass-forming soft-sphere liquids in terms of simple scalin...
We show that the kinetic-theoretical self-diffusion coefficient of an atomic
fluid plays the same role as the short-time self-diffusion coefficient D_S in a
colloidal liquid, in the sense that the dynamic properties of the former, at
times much longer than the mean free time, and properly scaled with D_S, will
indistinguishable from those of a coll...