News Release

Penn researchers demonstrate how to control liquid crystal patterns

Peer-Reviewed Publication

University of Pennsylvania

Liquid Crystal Patterns

image: Research led by researchers at the University of Pennsylvania demonstrated that not only could patterns on liquid crystals be controlled at nanoscales, but the changes could be visible without microscopes. view more 

Credit: Lisa Tran

When Lisa Tran set out to investigate patterns in liquid crystals, she didn't know what to expect. When she first looked through the microscope, she saw dancing iridescent spheres with fingerprint-like patterns etched into them that spiraled and flattened as the solution they were floated in changed.

The sight was so beautiful that Tran, a graduate student in the Department of Physics and Astronomy in the University of Pennsylvania's School of Arts and Sciences, submitted a video of it to the Nikon Small World Competition and ended up winning fifth place. But the importance of the results stretch far beyond their aesthetic appeal, with possible applications in biosensing and energy harvesting.

Liquid crystals, fluids with aligned phases of constituent molecules, are used in everything from computer and television displays to mood rings. Since liquid crystals are made of rod-like molecules, they have special optical properties, such as changing color as they interact with electrical signals or light.

For this research, Tran confined the liquid crystals within droplets, creating shells floating in water. Tran and her advisor, Randall Kamien, the Vicki and William Abrams Professor in the Natural Sciences at Penn, described the droplets as "fancy bubbles." To create patterns, Tran then added surfactants, or soapy molecules, to the water.

"The way that soap usually works," Tran said, "is that you mix it with water and it forms small droplets with the oil to remove it from your hands or your plate."

Because liquid crystals are similar to oil, the surfactants were attracted to the liquid crystal shells, causing the molecules to order in different ways and create striking patterns. The more soap she added to the solution, the more the patterns changed. Adding water caused the patterns to reverse.

Being able to control the patterns that form on the liquid crystals could be useful in creating patchy colloids, microscopic particles suspended in water that are functionalized, meaning one can attach molecules to specific spots on the particle.

"If you think about a ping pong ball, it's completely uninteresting," Kamien said. "But then you think about a golf ball, which is similar in size, but there are dimples on it. So the thing about Lisa's work is that by controlling the patterns that you see optically, it physically textures the surface, which enables you to attach things to it at particular places."

The paper, published in Physical Review X, was led by Tran and Kamien in collaboration with Kathleen Stebe, the Richer & Elizabeth Goodwin Professor, and professor Daeyeon Lee, in the Department of Chemical and Biomolecular Engineering in the School of Engineering and Applied Science. They also collaborated with the group of Teresa López-León from the École Supérieure de Physique et de Chimie Industrielles de la Ville de Paris.

The research is a key component in one of the interdisciplinary research groups of Penn's recent $22.6 million NSF Materials Research Science and Engineering Center grant. The group is working to make assemblies of nanocrystals on hard templates and within soft materials that hold promise for applications in sensing, energy conversion and optical-signal processing.

Tran's experiment was inspired by previous research done by Maxim Lavrentovich, a Penn postdoctoral fellow at the time who is now an assistant professor at the University of Tennessee, Knoxville. Working with Kamien, Lavrentovich investigated how different patterns on pollen grains were specific to different species of plants, similar to butterfly wings.

Since liquid crystals are also known for forming different patterns, Tran investigated what would happen if the molecules were confined to a sphere and caused to form patterns. She was hoping to see how they would pack and if they would match some of the patterns they had seen for pollen grains.

Although initially the researchers used polarizing microscopy to investigate this, they found that they could see the droplets without a microscope by just holding the solution to the light. Since the liquid crystal responds to what's going on around it, looking at the patterns that the soap molecules induce on the shells can be used as a biosensor.

"If you can get them to change their color or texture just because there's some poison in the test tube with them," Kamien said, "then you can see it with your eyes, and you don't even need a microscope."

To follow on this research, Tran is interested in incorporating nanoparticles with different properties to create nanowires, which could be used as a way of making more energy-efficient harvesting devices that can be tuned to the light in their environment.

"If you had nanoparticles that were all metal," she said, "you could get them to follow along the line and, if you cross link them, such that they're rigid, and wash away the liquid crystal, then you end up with this sort of patterned nanowire which could then be used for further applications."

According to Kamien, one of the most interesting things they learned from this research is that they don't need fancy equipment to see how things organize themselves on the nanoscale.

"The idea," he said, "that we can manipulate things that are so small with big hands and look at them on large-length scales is amazing to me. By squirting something into the solution we can change what the patterns look like. We're not just deducing things about them; we're controlling them. We're getting them to dance for us. It's true that electronics are doing the same thing with electrons, but you can't see the electrons. This interplay between optics and structure is exciting."

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This research was supported by National Science Foundation MRSEC Grant DMR1120901, U.S. Department of Energy Grant DE-FG02-05ER46199 and a Simons Investigator grant from the Simons Foundation.


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