Your search keyword '"Noe Atzin"' showing total 3 results

1. Programming Solitons in Liquid Crystals Using Surface Chemistry

Author

Soumik Das, Sangchul Roh, Noe Atzin, Ali Mozaffari, Xingzhou Tang, Juan J. de Pablo, and Nicholas L. Abbott

Subjects

Electrochemistry, General Materials Science, Surfaces and Interfaces, Condensed Matter Physics, Spectroscopy

Abstract

AC electric fields cause three-dimensional orientational fluctuations (solitons) to form and rapidly propagate in confined films of liquid crystals (LCs), offering the basis of a new class of active soft matter (e.g., for accelerating mixing and transport processes in microscale chemical systems). How surface chemistry impacts the formation and trajectories of solitons, however, is not understood. Here, we show that self-assembled monolayers (SAMs) formed from alkanethiols on gold, which permit precise control over surface chemistry, are electrochemically stable over voltage and frequency windows (100 V; 1 kHz) that lead to soliton formation in achiral nematic films of 4'-butyl-4-heptyl-bicyclohexyl-4-carbonitrile (CCN-47). By comparing soliton formation in LC films confined by SAMs formed from hexadecanethiol (C

Published

2022

2. Defect Spirograph: Dynamical Behavior of Defects in Spatially Patterned Active Nematics

Author

Juan J. de Pablo, Rui Zhang, Ali Mozaffari, and Noe Atzin

Subjects

Materials science, Condensed matter physics, Continuum (design consultancy), FOS: Physical sciences, General Physics and Astronomy, Condensed Matter - Soft Condensed Matter, Rotation, 01 natural sciences, Topological defect, Liquid crystal, 0103 physical sciences, Soft Condensed Matter (cond-mat.soft), 010306 general physics, Phase diagram

Abstract

Topological defects in active liquid crystals can be confined by introducing gradients of activity. Here, we examine the dynamical behavior of two defects confined by a sharp gradient of activity that separates an active circular region and a surrounding passive nematic material. Continuum simulations are used to explain how the interplay among energy injection into the system, hydrodynamic interactions, and frictional forces governs the dynamics of topologically required self-propelling $+1/2$ defects. Our findings are rationalized in terms of a phase diagram for the dynamical response of defects in terms of activity and frictional damping strength. Different regions of the underlying phase diagram correspond to distinct dynamical modes, namely immobile defects (ID), steady rotation of defects (SR), bouncing defects (TB), bouncing-cruising defects (BC), dancing defects (DA), and multiple defects with irregular dynamics (MD). These dynamic states raise the prospect of generating synchronized defect arrays for microfluidic applications.

Published

2021

3. Direct Observation of Liquid Crystal Droplet Configurational Transitions using Optical Tweezers

Author

Linda Oster, Rui Zhang, Benjamin Strain, Ye Zhou, Ali Mozaffari, Jake Shechter, Juan J. de Pablo, Jennifer L. Ross, and Noe Atzin

Subjects

Liquid crystal droplet, Materials science, Direct observation, 02 engineering and technology, Surfaces and Interfaces, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Optical tweezers, Liquid crystal, Chemical physics, Electrochemistry, Molecule, General Materials Science, 0210 nano-technology, Spectroscopy

Abstract

Liquid crystals (LCs) are easily influenced by external interactions, particularly at interfaces. When rod-like LC molecules are confined to spherical droplets, they experience a competition between interfacial tension and elastic deformations. The configuration of LCs inside a droplet can be controlled using surfactants that influence the interfacial orientation of the LC molecules in the oil-phase of an oil in water emulsion. Here, we used the surfactant sodium dodecyl sulfate (SDS) to manipulate the orientation of 5CB molecules in a polydisperse emulsion and examined the configuration of the droplets as a function of SDS concentration. We triggered pronounced morphological transitions by altering the SDS concentration while observing an individual LC droplet held in place using an optical tweezer. We compared the experimental configuration changes to predictions from simulations. We observed a hysteresis in the SDS concentration that induced the morphological transition from radial to bipolar and back as well as a fluctuations in the configuration during the transition.

Published

2020