Your search keyword '"de Pablo, J. J."' showing total 4 results

1. Liquid-crystal-mediated self-assembly at nanodroplet interfaces.

Author

Moreno-Razo JA, Sambriski EJ, Abbott NL, Hernández-Ortiz JP, and de Pablo JJ

Subjects

Surface-Active Agents chemistry, Temperature, Liquid Crystals chemistry, Nanostructures chemistry

Abstract

Technological applications of liquid crystals have generally relied on control of molecular orientation at a surface or an interface. Such control has been achieved through topography, chemistry and the adsorption of monolayers or surfactants. The role of the substrate or interface has been to impart order over visible length scales and to confine the liquid crystal in a device. Here, we report results from a computational study of a liquid-crystal-based system in which the opposite is true: the liquid crystal is used to impart order on the interfacial arrangement of a surfactant. Recent experiments on macroscopic interfaces have hinted that an interfacial coupling between bulk liquid crystal and surfactant can lead to a two-dimensional phase separation of the surfactant at the interface, but have not had the resolution to measure the structure of the resulting phases. To enhance that coupling, we consider the limit of nanodroplets, the interfaces of which are decorated with surfactant molecules that promote local perpendicular orientation of mesogens within the droplet. In the absence of surfactant, mesogens at the interface are all parallel to that interface. As the droplet is cooled, the mesogens undergo a transition from a disordered (isotropic) to an ordered (nematic or smectic) liquid-crystal phase. As this happens, mesogens within the droplet cause a transition of the surfactant at the interface, which forms new ordered nanophases with morphologies dependent on surfactant concentration. Such nanophases are reminiscent of those encountered in block copolymers, and include circular, striped and worm-like patterns.

Published

2012

2. Quenched disorder in a liquid-crystal biosensor: adsorbed nanoparticles at confining walls.

Author

Guzmán O, Abbott NL, and de Pablo JJ

Subjects

Adsorption, Anisotropy, Crystallization, Kinetics, Models, Statistical, Models, Theoretical, Nanostructures chemistry, Software, Time Factors, Biosensing Techniques, Chemistry, Physical methods, Liquid Crystals, Nanoparticles chemistry

Abstract

We analyze the response of a nematic liquid-crystal film, confined between parallel walls, to the presence of nanoscopic particles adsorbed at the walls. This is done for a variety of patterns of adsorption (random and periodic) and operational conditions of the system that can be controlled in experimental liquid-crystal-based devices. We compute simulated optical textures and the total optical output of the sensor between crossed polars, as well as the correlation function for the liquid-crystal tensor order parameter; we use these observables to discuss the gradual destruction of the original uniform orientation. For large concentrations of particles adsorbed in random patterns, the liquid crystal at the center of the sensor adopts a multidomain state, characterized by a small correlation length of the tensor order parameter, and also by a loss of optical anisotropy under observation through crossed polars. In contrast, for particles adsorbed in periodic patterns, the nematic at the center of the cell can remain in a monodomain orientation state, provided the patterns in opposite walls are synchronized.

Published

2005

3. Slow dynamics of thin nematic films in the presence of adsorbed nanoparticles.

Author

Grollau, S., Guzmán, O., Abbott, N. L., and de Pablo, J. J.

Subjects

NANOPARTICLES, LIQUID crystals, BIOMOLECULES, MOLECULAR biology, MOLECULES, PARTICLES

Abstract

Recent experiments indicate that liquid crystals can be used to optically report the presence of biomolecules adsorbed at solid surfaces. In this work, numerical simulations are used to investigate the effects of biological molecules, modeled as spherical particles, on the structure and dynamics of nematic ordering. In the absence of adsorbed particles, a nematic in contact with a substrate adopts a uniform orientational order, imposed by the boundary conditions at this surface. It is found that the relaxation to this uniform state is slowed down by the presence of a small number of adsorbed particles. However, beyond a critical concentration of adsorbed particles, the liquid crystal ceases to exhibit uniform orientational order at long times. At this concentration, the domain growth is characterized by a first regime where the average nematic domain size LD obeys the scaling law LD(t)∼t1/2; at long times, a slow dynamics regime is attained for which LD tends to a finite value corresponding to a metastable state with a disordered texture. The results of simulations are consistent with experimental observations.© 2005 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2005

4. Monte Carlo simulations and dynamic field theory for suspended particles in liquid crystalline systems.

Author

Grollau, S., Kim, E. B., Guzmán, O., Abbott, N. L., and de Pablo, J. J.

Subjects

MONTE Carlo method, FIELD theory (Physics), PARTICLES (Nuclear physics), LIQUID crystals

Abstract

Monte Carlo simulations and dynamic field theory are used to study spherical particles suspended in a nematic liquid crystal. Within these two approaches, we investigate the binding of the defects to the particles, the adsorption of a particle at a solid surface, and two particles interacting with each other. Quantitative comparisons indicate good agreement between the two approaches. A Monte Carlo method based on the combination of canonical expanded ensemble simulations with a density-of-state formalism is used to determine the potential of mean force between one particle and a hard wall. On the other hand, the potential of mean force is evaluated using a dynamic field theory, where the time-dependent evolution of the second rank tensor includes two major aspects of liquid crystalline materials, namely the excluded volume and the long-range order elasticity. The results indicate an effective repulsive force that acts between the particle and the wall. Layer formation at the surface of the hard wall gives rise to local minima in the potential of mean force. The director profile for a particle at contact with a solid surface is characterized by a disclination line distorted and attracted towards the wall. The structure of the nematic for two particles at short distances is also investigated. Our results indicate a structure where the two particles are separated by a circular disclination line. The potential of mean force associated with this configuration indicates an effective attractive interaction between the two particles. [ABSTRACT FROM AUTHOR]

Published

2003