Off

Two undergraduate students in the Paul M. Rady Department of Mechanical Engineering have solidified themselves amongst the future leaders of aerospace.

First-year mechanical engineering student and 2025 Patti Grace Smith Fellow Caleb Woldemichael at Lockheed Martin.

Third-year student  and first-year student  were selected as Patti Grace Smith Fellows. The prestigious program is designed to help accelerate the careers of high-achieving Black students across the nation–a population that statistically remains underrepresented throughout the aerospace industry.

This year’s class of fellows featured 176 top-rated students from twenty-four different universities. Recipients of the award receive networking opportunities across the industry, personalized mentorship, a valuable summer internship at one of America’s leading aerospace companies and their share of nearly $500,000 in total scholarships.

“I’m honored to be a Patti Grace Smith Fellow,” said Woldemichael. “Breaking into aerospace can feel impossible and I definitely know what it’s like to be the only person of color in a room full of STEM students. This fellowship gives us a chance to get technical, hands-on experience and connect with other successful fellows throughout the industry.”

The Patti Grace Fellowship selection process is often described as one of the most rigorous in the country. Multiple rounds of screening and interviews with the nation’s most sought after aerospace employers ensures the candidates exhibit extraordinary professional aptitude and proven leadership qualities. 

Third-year mechanical engineering student Asaiah Gifford during a Summer Program for Undergraduate Research (SPUR) presentation.

The program’s applicant pool nearly doubled this year, as well, creating an even more competitive landscape than ever before. But Gifford believes the difficulty is what made the process memorable and inspiring.

“During one of my interviews I spoke with one of the fellows from a past class,” she said. “I was able to ask her a few questions about the fellowship and the difference it can make in the industry. She explained the hardships of being a Black engineer and shared how the program helped her push forward. Hearing that really just excited me and helped me have fun with this whole process.”

In 1963, Patti Grace Smith was a plaintiff in a landmark Supreme Court case that integrated public schools in Alabama. She would later go on to have an illustrious aerospace career, leading the Federal Aviation Administration’s Office of Commercial Space Transportation and earning the General James E. Hill Lifetime Space Achievement Award, one of the highest honors awarded to aerospace professionals.

Her perseverance helped break barriers and usher in a new era of educational inclusivity, a legacy that today’s fellows are looking to uphold.

“There have been times where I’ve wondered if I’m good enough. I know what it’s like and I’m only a freshman, so I know I will face more difficulties,” said Woldemichael. “I hope future engineers can see this fellowship and push past this lack of representation, too.”

“This fellowship has taught me that being multifaceted is not a hindrance,” Gifford added. “A lot of people in engineering tend to prioritize only technical expertise, but the person matters, too. The Patti Grace Fellowship cares about how engineering impacts people, and I hope to expand on that going forward.”

Off

With rapid advancements in robotics and AI, the line between science fiction and reality continues to blur. At the heart of this innovation lies a breakthrough: drones designed to solve pressing global challenges, from pollinating crops to navigating wildfire zones.

This vision drives Assistant Professor Chahat Singh, leader of the  (Perception, Robotics, AI and Sensing) Lab in the Paul M. Rady Department of Mechanical Engineering. With an academic background spanning electronics, robotics, and computer science, Singh is dedicated to exploring the frontiers of bio-inspired robotics and AI in resource-constrained systems.

Assistant Professor Chahat Singh next to one of his compact and autonomous robotic designs.

Singh’s overarching research question is deceptively simple: What is the minimum amount of computational power, sensor capability, and resources required for small robots to achieve autonomy? This challenge is compounded by the scale of the robots he designs, which are constrained by limited computational capacity and lightweight requirements. They are two to three inches in length and orders of magnitude smaller in terms of physical size and computational power than traditional robots. “We’re working with systems that have 100 times less computing power than a Boston Dynamics’ Spot robot,” Singh explained. “The goal is to achieve autonomy with the bare minimum.”

One of Singh’s most notable projects focuses on autonomous drones for pollination, inspired by the overwhelming loss of honeybee colonies. “The question was whether today’s robotics and AI could fill this gap until we have a more sustainable biological solution,” Singh said. The answer lies in his innovative, lightweight drones that can navigate autonomously through forests and fields without relying on external communication or GPS, making them secure and efficient.

Singh’s current drone model incorporates multiple onboard cameras, which enables it to identify and align with flowers for pollination. The cameras use advanced neural depth-perception algorithms powered by AI-accelerated computers. Many creatures have developed different pupil shapes based on their habitats which allow variations in incoming light and amount of blur to help them determine the depth of objects. “The cameras are inspired by biological systems,” he explained.  

Singh showcasing the small scale of materials in his robot's design. His goal is to develop autonomous drones with less resources and power than traditional robots.

Singh’s drones are not just technologically advanced—they’re engineering marvels. Built from carbon fiber frames, these drones are lightweight yet robust, weighing around 250 grams. They use lithium ion batteries which are heavy and tend to die quickly, so he has started to look at ways to charge the batteries while the robots are outside. 

To overcome these limitations, Singh has developed a “mother drone” system. The larger drone carries smaller drones to the target area and acts as a mobile charging station. Once deployed, the smaller drones autonomously search for flowers and begin pollination. This approach not only extends operational time but also reduces the energy expenditure of individual drones. “It’s a highly efficient system that mirrors natural ecosystems,” Singh said.

While the pollination drones have gathered attention, Singh’s research has broader implications. His team is working on compressing advanced AI models, such as language and vision models, to operate on resource-constrained systems. “Imagine a robot navigating a forest during a wildfire,” Singh said. “It needs to make decisions on the spot, without internet access or pre-programmed instructions. That’s the next frontier—embedding foundational AI models into small, autonomous robots.”

Singh’s vision extends to deploying fleets of robots for tasks like firefighting, disaster response, and ecological monitoring. By creating swarms of cost-effective, autonomous robots, he aims to revolutionize industries that rely on expensive, large-scale systems. “Smaller robots are not just cool—they’re necessary,” he emphasized. “They offer safety, robustness, and cost-effectiveness.”

Despite the groundbreaking nature of his work, he is committed to open-source principles. “I believe in openness because this research is for the greater good,” he said. Singh has already shared software for drone operation and plans to release additional resources to empower other researchers and innovators.

When asked about his favorite part of the research, Singh highlighted the hope it brings for the future. “Whether it’s addressing ecological crises or enhancing technology, I want to create robot systems that are safe, innovative and sustainable,” he said. “This is about pushing the boundaries of what’s possible while respecting the natural world.”

Off

Off

Off

A team of engineers and material scientists in the Paul M. Rady Department of Mechanical Engineering at CU Boulder has developed a new technology to turn thermal radiation into electricity in a way that literally teases the basic law of thermal physics.

The breakthrough was discovered by the , led by Assistant Professor Longji Cui. Their work, in collaboration with researchers from the National Renewable Energy Laboratory (NREL) and the University of Wisconsin-Madison, was recently . 

The group says their research has the potential to revolutionize manufacturing industries by increasing power generation without the need for high temperature heat sources or expensive materials. They can store clean energy, lower carbon emissions and harvest heat from geothermal, nuclear and solar radiation plants across the globe.

In other words, Cui and his team have solved an age-old puzzle: how to do more with less.

“Heat is a renewable energy source that is often overlooked,” Cui said. “Two-thirds of all energy that we use is turned into heat. Think of energy storage and electricity generation that doesn’t involve fossil fuels. We can recover some of this wasted thermal energy and use it to make clean electricity.”

Breaking the physical limit in vacuum

High-temperature industrial processes and renewable energy harvesting techniques often utilize a thermal energy conversion method called thermophotovoltaics (TPV). This method harnesses thermal energy from high temperature heat sources to generate electricity. 

But existing TPV devices have one constraint: Planck’s thermal radiation law. 

PhD student Mohammad Habibi showcasing one of the group's TPV cells used for power generation. Habibi was the leader of both the theory and experimentation of this groundbreaking research.

“Planck’s law, one of most fundamental laws in thermal physics, puts a limit on the available thermal energy that can be harnessed from a high temperature source at any given temperature,” said Cui, also a faculty member affiliated with the Materials Science and Engineering Program and the Center for Experiments on Quantum Materials. “Researchers have tried to work closer or overcome this limit using many ideas, but current methods are overly complicated to manufacture the device, costly and unscalable.”

That’s where Cui’s group comes in. By designing a unique and compact TPV device that can fit in a human hand, the team was able to overcome the vacuum limit defined by Planck’s law and double the yielded power density previously achieved by conventional TPV designs. 

“When we were exploring this technology, we had theoretically predicted a high level of enhancement. But we weren’t sure what it would look like in a real world experiment,” said Mohammad Habibi, a PhD student in Cui’s lab and leader of both the theory and experiment of this research. “After performing the experiment and processing the data, we saw the enhancement ourselves and knew it was something great.”

The zero-vacuum gap solution using glass

The research emerged, in part, from the group’s desire to challenge the limits. But in order to succeed, they had to modify existing TPV designs and take a different approach.

“There are two major performance metrics when it comes to TPV devices: efficiency and power density,” said Cui. “Most people have focused on efficiency. However, our goal was to increase power.”

The zero-vacuum gap TPV device, designed by the Cui Research Group.

To do so, the team implemented what’s called a “zero-vacuum gap” solution into the design of their TPV device. Unlike other TPV models that feature a vacuum or gas-filled gap between the thermal source and the solar cell, their design features an insulated, high index and infrared-transparent spacer made out of just glass. 

This creates a high power density channel that allows thermal heat waves to travel through the device without losing strength, drastically improving power generation. The material is also very cheap, one of the device’s central calling cards.

“Previously, when people wanted to enhance the power density, they would have to increase temperature. Let’s say an increase from 1,500 C to 2,000 C. Sometimes even higher, which eventually becomes not tolerable and unsafe for the whole energy system,” Cui explained. “Now we can work in lower temperatures that are compatible with most industrial processes, all while still generating similar electrical power than before. Our device operates at 1,000 C and yields power equivalent to 1,400 C in existing gap-integrated TPV devices.”

The group also says their glass design is just the tip of the iceberg. Other materials could help the device produce even more power.

“This is the first demonstration of this new TPV concept,” explained Habibi. “But if we used another cheap material with the same properties, like amorphous silicon, there is a potential for an even higher, nearly 20 times more increase in power density. That’s what we are looking to explore next.”

The broader commercial impact

Assistant Professor Longji Cui (middle) and the Cui Research Group. 

Cui says their novel TPV devices would make its largest impact by enabling portable power generators and decarbonizing heavy emissions industries. Once optimized, they have the power to transform high-temperature industrial processes, such as the production of glass, steel and cement with cheaper and cleaner electricity.

“Our device uses commercial technology that already exists. It can scale up naturally to be implemented in these industries,” said Cui. “We can recover wasted heat and can provide the energy storage they need with this device at a low working temperature.

“We have a patent pending based on this technology and it is very exciting to push this renewable innovation forward within the field of power generation and heat recovery.” 

Off

Off

It’s been six years since the launch of startup company , co-founded by Professor Mark Rentschler of the Paul M. Rady Department of Mechanical Engineering. The company has seen great success, including the development of a medical device designed to enable more efficient procedures in the small bowel region.

Today, with the help of a $4.5 million award through the Anschutz Acceleration Initiative (AAI), Rentschler and his colleagues are working to bring two new products to the market that will transform these types of procedures even further.

“We brought our first product out on the market in 2024,” said Rentschler, also a faculty member in biomedical engineering (BME) and robotics. “We are planning to bring a second and third product to the market in 12-18 months, and we are extremely excited to get these devices in the hands of interventional endoscopists.”

Professor Mark Rentschler holding Aspero Medical's patented Ancora-SB balloon overtube.

In 2023, Aspero received clearance from the Food and Drug Administration (FDA) to market and sell the Ancora-SB device. The product is used during endoscopy procedures to diagnose and treat small bowel diseases.

According to Rentschler, operating within the small intestine can be time consuming and technically challenging. Equipped with a patented micro-textured balloon, the Ancora-SB overtube is designed to provide more traction and anchoring consistency than smooth latex or smooth silicone balloon overtube competitors.

“Balloon overtubes for small bowel procedures have been around for about a decade,” said Rentschler. “We’re not looking to change the small bowel enteroscopy procedure, but instead improve balloon anchoring performance during these procedures in the small bowel.”

Ancora-SB has allowed Aspero to prove their worth in hospitals. Their next products expand on this concept, of course, with additional features that can facilitate a less invasive interventional procedure than traditional open surgery.

The next generation balloon overtube will be used to remove cancerous lesions in the large bowel region. It features an extra working channel that allows for an additional tool to be utilized alongside the visualization scope. This offers physicians more control, access, and stabilization when maneuvering through the colon and performing advanced interventional procedures.

“Conceptually, these devices will enable triangulated surgery with two tools and centralized visualization so that physicians can more efficiently perform surgery from inside the lumen,” Rentschler said. “Instead of historically invasive procedures, where the patient is cut open, and the cancerous bowel region is removed, we’re assisting physicians as they remove the cancer from the inside of the lumen during an outpatient procedure.

“It's much less invasive, with potentially tremendous cost savings, and numerous benefits for the patient.”

Aspero’s third product will be another balloon overtube, this time with a working channel that enables minimally invasive cancer removal in the esophagus and stomach regions of the gastrointestinal tract. 

Rentschler showcasing all three of the medical devices in Aspero Medical's multi-product platform, including their two new highly anticipated devices.

Rentschler and his team say the two upcoming devices have the potential to replace a large, and growing, number of today’s conventional surgical procedures in the gastrointestinal region by enhancing safety and efficiency while reducing patient recovery time. Moving procedures from inpatient surgery to outpatient endoscopy can generate potential cost savings of up to 50 percent or more.

“Everyone knows this is the direction we need to go. Clinical outcomes from these types of procedures are incredibly strong, but the techniques and devices aren’t widely available yet,” said Rentschler. “We are creating products that help physicians and patients feel safe and comfortable without overcomplicating things. The paradigm is rapidly shifting, and we endeavor to push endoscopy forward.”

The company is currently finalizing the design of the second product. It’s about six months further along in development than the third product, but Rentschler says they are looking to have both devices FDA cleared by the end of 2026. 

When all three devices hit the market, Aspero will look to market a portfolio of products, rather than a single tool. But further innovation is on the horizon, this time incorporating the Ancora balloon technology with a robotic element.

“Ancora is a multi-product platform focusing on the small bowel, large bowel, stomach and esophageal regions,” Rentschler said. “Our next potential venture will be in flexible robots. We’ll continue with our balloon overtubes, but as anchoring platforms to be used with flexible robotic endoscopy systems.”

Until then, Rentschler and company are full steam ahead on these next products. The $4.5 million AAI grant is being offered over a four year span, but they anticipate spending that money much sooner so they can get the devices out on the market and begin positively impacting patients and physicians everywhere.

But that’s not their only goal. With a lot of Colorado involved in the company’s revolutionizing technology, Rentschler hopes to also tell another story.

“I started Aspero Medical with Dr. Steven Edmundowicz at CU Anschutz. We’ve received a number of grants from the state of Colorado and everyone involved is invested in our vision,” said Rentschler. “We believe that a rising tide raises all boats, and when we think of Aspero, we want it to be a successful Colorado story.”

Off

Research doesn’t always go as planned, and sometimes results can appear to be abnormal. Some professors, like Xiaoyun Ding, see this as an opportunity to achieve the next big discovery. 

Ding, an associate professor in the Paul M. Rady Department of Mechanical Engineering, leads the Biomedical Microfluidics Laboratory (BMMLab) at CU Boulder. His team stumbled across an interesting anomaly during a cell sensing project that used different forms of acoustic waves to measure cell mechanics.

Associate Professor Xiaoyun Ding (right) and his lab group during summer 2024.

When using a surface acoustic wave to rearrange DNA particles, Yu Gao, a research associate in Ding’s group, managed to assemble the particles in a diamond shape. This type of shape assembly has never been observed before in a microfluidic environment using acoustic waves. 

But what did it mean?

“Normally, acoustic wave patterns resemble a kind of circular-shaped aggregation of particles,” said Ding, also a faculty member in biomedical engineering. “After seeing this pattern, though, we had a feeling it could be a completely new wave mode that is contributing to this phenomenon.

“So we reached out to our collaborators Thomas Voglhuber-Brunnmaier and Bernhard Jakoby in Austria. They helped us model our experiment. Sure enough, their results matched our initial observation.”

According to Ding, the newly discovered wave mode has a few unique traits compared to the traditional acoustic wave modes used in acoustic tweezer research. First, it contains a horizontal polarization, allowing the wave to move sideways along the interface rather than oscillating across a vertical plane. 

The wave mode can also apply electric force to a particle or cell, instead of standard acoustic force. He says being able to configure the various wave modes and switch between them on demand can lead to even more major breakthroughs when studying cell mechanics or cell manipulation.

“I always tell my students: in both research and life, you will see something you don’t expect,” Ding said. “It’s not called failure. The result that you do not expect could be an opportunity.”

“Cells with different properties, like cancer cells, respond differently to electric force,” Ding said. “Manipulating the electric field will allow us to separate these cells with more sensitivity and accuracy. We’ll be able to detect more of their properties and study their mechanics more efficiently.

“Before this discovery, there was no intrinsic control over generating acoustic force or electric force. Now, we can selectively generate these different wave modes and apply different forces simply by changing the frequency.”

The research conducted by Ding and his colleagues, titled “,” has been published by Physical Review Letters. Professor Massimo Ruzzene is also a co-author of the paper.

Their work serves as another example of interdisciplinary collaboration, a common theme in the College of Engineering and Applied Science.

“Our group is actively working with people in the medical and biology fields. They tell us their problems, and we try to develop technology that can solve those problems,” said Ding. “We take on their issues, and we try to make their lives easier.”

But Ding says the BMMLab atmosphere isn’t only focusing on biomedical problem-solving. There are other lessons to be learned that go far beyond the laboratory. 

“I always tell my students: in both research and life, you will see something you don’t expect,” Ding said. “It’s not called failure. The result that you do not expect could be an opportunity.”

Off

Off