ASU student presents research at Texas Capitol

SAN ANGELO, Texas (Concho Valley Homepage) — Angelo State University senior and physics major YooJin Choi represented ASU by presenting her research project at the recent 2025 Texas Undergraduate Research Day at the Capitol event in Austin.
According to the university, 'Undergraduate Research Day is hosted by the Independent Colleges and Universities of Texas (ICUT) organization and the Council of Public University Presidents and Chancellors (CPUPC) to showcase exciting research from talented undergraduate students at public and private universities across the state.'
The event is only hosted in odd-numbered years during which the Texas Legislature is in session. Texan institutions of higher education may select one student each to present a research poster.
Choi presented research on her project, titled 'Capturing Cellular Dynamics: A Force Center Model Inspired by the Game of Life.' ASU stated that the project was 'which she completed under the mentorship of Dr. Michael C. Holcomb, assistant professor of physics.'
Holcomb was also invited to take part in the event through a panel presentation on 'The Inside Scoop on Academic Research.'
'I have had the pleasure of working with YooJin Choi throughout her undergraduate career, and I am so very proud that she was selected to represent Angelo State at this event,' Holcomb said. 'I have witnessed firsthand her relentless dedication to her academic and research pursuits, and I can confidently say that her accomplishments accurately reflect the immense amount of hard work she puts in to all that she does.'
ASU shared that Choi has received several other accolades. She has received two ASU Faculty Mentored Research Grants for various projects, has worked as a tutor in the Math Lab and served as a physics tutor in ASU's Supplemental Instruction peer-tutoring program. She has also held leadership positions in the Society of Physics Students, Women in Physics and STEM Nexus student organizations.
As part of the service missions of those organizations, she has participated in numerous community outreach activities, including STEM Nights at local elementary schools, Girl Scouts STEMfest and the annual Physics Road Show around West Texas. She has also been active as a percussionist in the ASU Ram Band, Drumline and Symphonic Band.
Additionally, Choi has made the ASU Dean's List every semester and has been inducted into the prestigious Alpha Chi national collegiate honor society and Sigma Pi Sigma national physics honor society.
Choi is scheduled to graduate with her Bachelor of Science degree in May. She has been offered a Distinguished Graduate Student Assistantship at Texas Tech University and will head to Texas Tech this fall to pursue her doctoral degree in physics.
Copyright 2025 Nexstar Media, Inc. All rights reserved. This material may not be published, broadcast, rewritten, or redistributed.

Try Our AI Features

Explore what Daily8 AI can do for you:

Learn with AIFact CheckingText to SpeechAI Summary

Related Articles

Yahoo

7 days ago

• Yahoo

Scientists create world's tiniest violin —and it's only visible with a microscope

British physicists claim they've created the 'world's smallest violin' — and, by the looks of it, they could take a bow for their masterpiece invention. The brainy bunch at Loughborough University used nanotechnology to build the teeny instrument, which is no bigger than a speck of dust and can only be seen with a microscope. Made of platinum, the mini-instrument measures 35 microns, one-millionth of a meter long, and 13 microns wide. Loughborough explained on its website that it's tiny enough to fit within the width of a human's hair. The scientists created the violin, which is just a microscopic image and isn't playable, as a test of the school's new nanolithography system, which allows them to build and study structures at the nanoscale. The project references the expression 'Can you hear the world's smallest violin playing just for you?' which pokes fun at people being overly dramatic. 'Though creating the world's smallest violin may seem like fun and games, a lot of what we've learned in the process has actually laid the groundwork for the research we're now undertaking,' Kelly Morrison, professor of experimental physics at the university, said on its website. 'Our nanolithography system allows us to design experiments that probe materials in different ways – using light, magnetism, or electricity – and observe their responses. Once we understand how materials behave, we can start applying that knowledge to develop new technologies.' The violin was made by a NanoFrazor, a nano-sculpting machine that uses a technique where a heated, needle-like tip writes patterns. First, a chip was coated with a gel-like material and then placed under the machine, effectively burning the violin pattern into the surface. After the pattern was etched, the underlayer of the gel dissolved, and a violin-shaped hole remained. A thin layer of platinum was then inserted into the chip, which was then rinsed with acetone to remove any remaining particles. The prototype took three hours to create. However, the team's final version took several months. 'Depending on how you engage with technology, there are people who are always looking to have something that runs faster, better, more efficient,' Morrison said in a YouTube video. 'That requires … finding a way to scale down.'

Yahoo

13-06-2025

• Yahoo

Bacteria will turn to murder if they get hungry enough

Bacteria operate by a pretty simple set of biological commands: survive and reproduce. But a recent study is highlighting that, in some cases, the microscopic organisms will follow those commands by any means necessary. Even if it entails killing and devouring their fellow bacteria. 'The punchline is: when things get tough, you eat your neighbors,' said Glen D'Souza, an Arizona State University molecular scientist and senior author of the paper published June 12 in the journal Science. D'Souza explained that while most bacteria absorb nutrients from the environment around them, it's 'textbook behavior' for certain species to kill each other. However, what he and colleagues observed was something different. In some instances, usually harmless bacteria will turn to violence if desperate. 'What we're seeing is that it's not just important that the bacteria have weapons to kill, but they are controlling when they use those weapons specifically for situations to eat others where they can't grow themselves,' D'Souza said. 'A microbial Jekyll and Hyde,' added Ferran Garcia-Pichel, ASU's director of Biodesign Center for Fundamental and Applied Microbiomics who was not involved in the study. D'Souza's team focused on a specific process inside bacteria called the Type VI Secretion System (T6SS). Similar to a tiny harpoon gun, T6SS enables bacteria to shoot a microscopic, needlelike weapon loaded with toxins into neighboring cells and organisms, causing them to fatally tear apart. Previously, microbiologists believed that bacteria mostly used their T6SS to eradicate rivals and make space for their own growth. But after utilizing timelapse imaging and other genetic analysis tools, the team recorded various bacteria using T6SS in a startling way. When nutrients were scarce, the organisms ambushed nearby bacteria and injected them with toxins. They then fed off of their targets as they essentially 'bled out.' 'By slowly releasing nutrients from their neighbors, they maximize their nutrient harvesting when every molecule counts,' said study first author Astrid Stubbusch. To prove that this behavior was, in fact, intentional, the team genetically switched off the T6SS in sample bacteria, and then placed them into a nutrient-starved setting. Those without the ability to use their mini-harpoons eventually died, but the unaltered bacteria began killing to survive.'This isn't just happening in the lab,' D'Souza clarified. 'It's present in many different environments and it's operational and happening in nature from the oceans to the human gut.' The ramifications go beyond microscopic horror stories. Understanding these systems allows researchers to gain a more complete picture of the microbial food chain and illustrate just how resourceful bacteria really are. It may also help pave the way for new antibiotics, or design drugs that harness T6SS to directly attack pathogens. The observations also have implications outside the human body. Many ocean bacteria are responsible for helping regulate Earth's carbon cycle. If some of them are using T6SS to devour bacteria that break down algae and recycle carbon, then ecologists can study how these influence planetary ecosystems. 'Watching these cells in action really drives home how resourceful bacteria can be,' added Stubbusch.

WIRED

13-06-2025

• WIRED

Are Those Viral ‘Cooling Blankets' for Real?

Jun 13, 2025 7:00 AM According to physics, any blanket can cool you—for a few minutes. But a real cooling blanket is possible with phase-change materials. Photograph:If you spend much time on the internet, you will see the same things pop up again and again. For me, it's these 'cooling blankets' that people talk about on social media. I mean, it sounds great for summer—just like a blanket that warms you up but in reverse. Sadly, these products don't do what they claim. They might be breathable so they don't make you as hot as an ordinary blanket would, but you'd still be cooler with no blanket at all. However, there is hope. Someone has created a real cooling blanket that's sort of awesome. Of course, there's a bunch of physics here, so let's get to it. Temperature vs. Energy Temperature is one of those words everyone uses and no one understands. In chemistry it's the average kinetic energy, or vibrational motion, of the molecules in a substance. The greater the commotion, the higher the temperature. But I like this more pragmatic definition: Temperature is the property two objects will have in common when they're in contact for a long time. So, if you take a hot block of metal and set it against a cold block of metal, eventually they will have the same temperature. Heat flows from the warmer thing to the cooler thing until they equalize. (Note: It doesn't work the other way around; you can't transfer 'coolness.') We also talk about objects having a certain amount of thermal energy , which you'd get by adding up the kinetic energy of all the particles inside it. It depends on three things: the mass of the object, its temperature, and the material it's made of. So for instance, focusing on mass, big potatoes have more thermal energy than small potatoes at the same temperature. Now, if you look at the type of material, every substance has a 'specific heat capacity,' which is the amount of heat required to raise the temperature of that substance by one degree. Try this at home. Find two objects that have been sitting in your room for a while, so they're both at room temperature. Here, I have a block of wood and a block of aluminum. Touch both objects. They're the same temperature, but the wood feels warmer, right? Why is that? It's not about temperature but thermal energy. When your hand touches an object, there is a heat conduction interaction. Energy is transferred from your warmer hand to the cooler object until the two are the same temperature. However, with the metal block it takes way more energy to reach the temperature of your hand. It feels cooler because it causes your hand to lose more energy. You'll notice the same thing when you go swimming. An air temperature of 75°F feels nice and comfortable, but wading into water of the same temperature feels really cold. That's because water has a much higher mass and specific heat capacity than air, which causes you to lose more thermal energy and feel colder. All Blankets Cool So, blankets, how do they work? A blanket is basically an insulator. That means it prevents energy transfer between objects at different temperatures. Wrapping yourself in a blanket on a cold day keeps you from losing body heat to the air around you, so you feel warmer. Similarly, if you put a blanket around a cold soda on a warm day, it will slow down the transfer of thermal energy from the air to the soda, keeping the soda cold longer. But what if you feel hot and you put on a blanket? In that case, two things can happen at once. It can still act as a thermal insulator and slow down the transfer of energy between you and the air. Unless the ambient air is above 98.5°F, this is going to make you hotter, not cooler. However, the blanket can also have a thermal interaction with your body. Suppose you have a 80°F blanket in contact with a 98°F person. This will raise the temperature of the blanket while reducing the thermal energy of your body. Yes, it will act as a cooling blanket—at least for a few minutes, until the temperatures are equalized. So, what makes one blanket cool more effectively than another? First, it should have a high mass, so that it takes a lot of energy to warm up. Second, the blanket needs to make good contact with your skin to increase the thermal interaction. So, one of those light fluffy blankets won't cool you off that much. Other than that, it's just a normal blanket. But I'm a sucker for trying these things, so I bought a cheap 'cooling blanket' online. (I know, someone will say it doesn't work unless you get an expensive one.) For those who say their cooling blanket was out in the sun and they measured a 75°F temperature, I don't believe you. Check this out. I have three blankets on my sofa. One of them is the cooling blanket and the others are normal. In back is the same picture taken with an infrared camera so that different colors represent different temperatures. Can you tell which one is the cooling blanket? Nope. You can't. There's almost no difference in the temperatures. They are all cooling blankets. They are also all normal blankets. A Real Cooling Blanket But what if I told you it's possible to have a thermal interaction between two objects but one of them doesn't change in temperature. Yes, this is a thing—it's called a phase transition. It happens whenever a material changes from solid to liquid or liquid to gas. Here's an interesting experiment. Imagine I take a beaker with frozen water (aka ice) that's colder than the freezing point (maybe –10°C). Then I put the beaker on a hot plate and add energy to it, measuring the temperature of the water as I go. Here is what that would look like: As you can see, the ice increases in temperature until it reaches the melting point, 0°C (32°F). At that point the temperature levels off, and it remains constant until all the ice melts—even though heat is still being added to the system. Why is that? It's because the energy is being used to break the molecular bonds and turn the solid into a liquid. Once it's entirely liquid, the temperature starts rising again, until it reaches the boiling point (100°C). Again, the temperature levels off until all the water turns to gas. (This is why it's nice to cook with boiling water—it stays the same temperature.) You can see how this would make for a better cooling blanket. Because of these temperature plateaus during a phase change, you can keep transferring thermal energy from your body to the blanket without the blanket getting warmer and becoming ineffective. Does this mean you could use an ice blanket, maybe with the water in a flexible lining, to cool yourself? Sure. But it would be excruciating and you might get frostbite. Also, once you melt the ice and heat up the water, you'd need to put your blanket back in the freezer before you could use it again. But how about a material that has a melting point closer to the temperature of the human body? In this video from the YouTube channel NighthawkInLight, Ben Cusick makes just such a phase-change material (PCM) from common salts (sodium sulfate and sodium chloride). Of course I had to try making some of this stuff myself. I'm not a chemist, but I think it turned out pretty well. It depends on your mixture and the type of salts used, but these kinds of materials have a melting point somewhere around 18°C (65°F). Why does that matter? Well, first, it's not so cold that it hurts. Second, you don't need a freezer; a cool place like a basement floor will make it refreeze. And best of all, the high melting point means it will melt slowly at room temperature, so the phase transition lasts a long time—hours instead of minutes—and it will cool you off during this whole time. Put this stuff in the lining of a blanket and voilà! Pretty cool, right?