Nov. 13, 2025, 3:55 p.m.聽Jillian Gloria 鈥�22聽stands on a balcony at Blue Origin headquarters in Cape Canaveral, Florida, her eyes fixed on the horizon at Launch Complex 36 鈥� the very launchpad her grandfather helped construct as a NASA engineer in the 1960s.

Engines ignite. Gloria鈥檚 breath catches as she wills the rocket to climb. Then she hears those crucial words: 鈥淟iftoff detected. New Glenn has cleared the tower.鈥�

The Blue Origin rocket scientist has just witnessed the launch of her first NASA mission. It鈥檚 a goal the Orlando native has dreamed about since childhood; one marked by visions of the space shuttle soaring upward as she commuted to school and the roar of sonic booms when it returned to Earth鈥檚 atmosphere.

What makes this milestone even more rewarding is the determination, the hard work and the relentless tenacity it took her to get here.

鈥淵our dreams are possible,鈥� Gloria says. 鈥淎ll you need is passion and persistence. As long as you keep going, you can do anything in this world. You鈥檙e always going to end up where you鈥檙e meant to be.鈥�

鈥淵ou鈥檒l Never Graduate鈥�

Gloria鈥檚 college journey began outside of Florida despite the numerous space-related research and partnerships available in her backyard at 麻豆原创. Like many of her peers, she thought she had to branch out from her hometown to gain the most out of her college experience.

She realized quickly she had made a mistake.

Not long after arriving at the University in Texas at Arlington, an academic advisor told her she would never graduate with an engineering degree if she started her academic career in algebra. She would need an additional 1.5 years of math and science classes alone before she could set foot in an engineering class.

Rather than catch up on the mathematics education and credits she needed to pursue engineering, he advised she鈥檇 be better off going after 鈥渟omething more realistic for her current path like a business degree.鈥�

鈥淎s an impressionable 18-19 year old, you listen to your adviser, right?鈥� she says. 鈥淚 just remember dropping the business class a few weeks in because I thought, 鈥楾his is not what I want to do, and I don鈥檛 care how long it takes me, I鈥檓 going to do get an engineering degree.鈥� 鈥�

Opportunity Comes Calling

She course-corrected and enrolled in the program at Valencia College. Valencia provided her the academic resources and tutoring she needed to overcome her initial struggles in math and science.

In 2018 ahead of transferring to 麻豆原创, she applied to the Central Florida Physics Research Exchange Program, a former initiative for undergraduate students to participate in a 10-week funded research project over the summer with 鲍颁贵鈥檚 physics department.

She remembers doubting her chances of acceptance. After all, she was an aspiring aerospace engineer, not a true physics major. But the program came with the promise of $5,000, and for someone who was working her way through school, what did she have to lose?

As part of her application, she wrote a compelling letter to Professor of Physics William Kaden about his space weathering effects research for NASA and how much she鈥檇 love the chance to work in his lab.

The letter worked. Kaden would go on to become Gloria鈥檚 mentor throughout her 2.5 years at 麻豆原创 and kickstarted her hand in research that yielded projects on finding water on the moon, collaborations with the German Aerospace Center (DLR), work with 鲍颁贵鈥檚 and a co-authorship on a NASA-funded paper published in 2021 in the聽Journal of Vacuum Science and Technology.

鈥淭he world of research at 麻豆原创 really provided me the actual work experience and opportunities to turn me into an engineer and a candidate that these companies sought after.鈥� 鈥� Jillian Gloria 鈥�22, Blue Origin engineer

鈥淭he world of research at 麻豆原创 really provided me the actual work experience and opportunities to turn me into an engineer and a candidate that these companies sought after,鈥� says Gloria, who keeps her senior-year textbook Mechanics and Thermodynamics of Propulsion, Second Edition on her office desk. 鈥淚 worked with industry hardware, a vacuum chamber that鈥檚 worth hundreds of thousands of dollars at NASA, flew a payload on a Masten Space Systems Xodiac rocket to track rocket plumes during launch and landing on the moon. I was a published author before I graduated. It all was such an amazing opportunity. That was the first time when I felt like I was actually doing the work I had dreamed about. The things I was exposed to at 麻豆原创 really 聽just opened my eyes onto what鈥檚 available out there in terms of my career.鈥�

Building a Road to Space

Since graduating in 2022, Gloria launched over a dozen successful missions across three launch-vehicle programs (Atlas V, Delta Heavy, Vulcan Centaur) at United Launch Alliance as a propulsion systems test engineer.

In January 2025, she joined the Blue Origin team as an integrated vehicle test engineer, specializing in the integration, testing, refurbishment, and optimization of complex fluid and pneumatic systems for her fourth launch vehicle, New Glenn.

In other words, she validates the build of the rocket, ensuring its integrity and functionality through every build stage before launch.

She is energized every day by the opportunities available to her to grow and learn within the company, who in addition to their rocket program is also developing a lunar lander and space station.

鈥淭his work matters. It鈥檚 the future.鈥� 鈥� Jillian Gloria

鈥�We鈥檙e all working together for the benefit of Earth, and you feel it every day you go to work at Blue Origin,鈥� she says. 鈥淭his work matters. It鈥檚 the future, it鈥檚 the next generation launch vehicle, and it just plays a hand in Blue鈥檚 mission statement that we want to build a road to space.鈥�

Every milestone they hit 鈥� like the recent successful launch and first-time landing of the New Glenn rocket that ferried NASA鈥檚 twin ESCAPADE spacecraft to begin their journey to Mars 鈥� helps get them closer to that goal.

While current generations may not see it, she knows the work she is doing at Blue Origin is developing the infrastructure for future generations who will one day consistently travel to and live on other celestial bodies.

鈥淭he stars are the final frontier. It calls to us,鈥� Gloria says. 鈥淵ou can鈥檛 really explain it, but when you look up at the sky, it kind of touches your soul. It just makes me feel more connected to something that鈥檚 so far away and so beautiful. It鈥檚 everything.鈥�

When Alain Berinstain talks about space, he doesn鈥檛 just talk about rockets or research missions 鈥� he talks about people, partnerships and the power of doing things that haven鈥檛 been done before.

That daring mindset is exactly what he鈥檚 bringing to his new role as director of the (FSI) at 麻豆原创, which supports space research, development and education activities, along with the development of Florida鈥檚 space economy 鈥� civil, defense and commercial.

A business and research strategist, Berinstain brings more than 30 years of experience in the space industry, driving strategic growth and domestic and international partnerships. He officially stepped into the role in December of last year, ready to elevate FSI into a nationally recognized institute while strengthening 鲍颁贵鈥檚 research profile, supporting Florida鈥檚 rapidly growing space economy and driving even greater global impact.

鈥淏eing bold is having ideas and doing things that nobody has ever done before,鈥� Berinstain says. 鈥淚f you do that in a collaborative way, then 鈥� pardon the pun 鈥� the sky鈥檚 the limit.鈥�

A Career Built on Making Connections

Berinstain鈥檚 path to 麻豆原创 wasn鈥檛 a straight line 鈥� and that鈥檚 by design. Trained as a chemist, he earned a bachelor鈥檚 degree in honors chemistry from Concordia University, a master鈥檚 degree in space studies from the International Space University and a doctoral degree in chemistry from the University of Ottawa. Early in his career, he saw space as a powerful platform for science, but also one that demanded collaboration across disciplines, sectors and borders.

From 1997 to 2013, Berinstain held leadership roles at the Canadian Space Agency, including director of planetary exploration and space astronomy. There, he managed annual budgets exceeding $25 million and helped negotiate Canada鈥檚 participation in major NASA missions such as the James Webb Space Telescope, OSIRIS-REx and the Mars Phoenix Lander. He also co-authored the original Global Exploration Roadmap, aligning international partners around shared exploration goals.

“I aim to show people how FSI can help meet their goals … and, in the end, raise the research profile in space at 麻豆原创, in Florida and in the world.”

Berinstain later moved between public service and the private sector, advising companies such as Virgin Galactic and Sierra Nevada Corporation, leading global development at Moon Express Inc. and most recently serving as chief strategy officer at science-based solutions company CSS Inc. Along the way, he helped generate more than $10 million in revenue for in-space manufacturing of health and technology products and cultivated strategic partnerships with academia, government and industry stakeholders.

That cross-sector experience now shapes his vision for FSI 鈥� especially when it comes to funding. A key priority, he says, is diversifying funding beyond traditional government grants by expanding private and commercial partnerships.

鈥淪ince I’ve spent time in other sectors and made contacts, I look forward to mining those to help collaborate and redevelop those relationships,鈥� he says. 鈥淚 aim to show people how FSI can help meet their goals and come up with new opportunities that we can respond to, and, in the end, raise the research profile in space at 麻豆原创, in Florida and in the world.鈥�

Why 麻豆原创 鈥� and Why Now

Berinstain鈥檚 appointment will fuel the momentum of space exploration and research at SpaceU 鈥� the top provider of graduates in the nation to the aerospace and defense industry 鈥� and the new Florida Space Research Consortium.

鈥淎lain is a daring innovator internationally recognized for his leadership throughout space鈥檚 public and private sectors,鈥� says Winston Schoenfeld, vice president for research and innovation. 鈥淗is experience, bold vision and strategic pursuit of partnerships will elevate the impact of our research at America鈥檚 Space University and further strengthen Florida鈥檚 rapidly growing space economy.鈥�

FSI鈥檚 unique position within a deeply collaborative campus and a statewide network of space researchers is what Berinstain says drew him to 麻豆原创.

鈥淲e lead our own world-class science, but we also partner with researchers across colleges and departments … There’s real strength in numbers.”

鈥淲here FSI fits within the 麻豆原创 ecosystem is really interesting. We lead our own world-class science, but we also partner with researchers across colleges and departments,鈥� he says. 鈥淲hat also attracted me is the collaboration among state universities in Florida. With the new consortium for university space research, in which we’re in a leadership position, there鈥檚 real strength in numbers.鈥�

From the Earth鈥檚 upper atmosphere to the origins of the planets and the dynamics of asteroids, FSI鈥檚 research tackles some of the biggest questions in space science. Building on those strengths, Berinstain is setting his sights on what comes next: expanding into areas shaping the future of commercial space, including microgravity research, pharmaceuticals and defense.

鈥淚 plan to grow FSI in areas that are of national and economic importance. They all need help from strong research groups,鈥� he says. 鈥淚t’s not so much about what we want to do 鈥� it’s about what they need us for. And that creates all kinds of cool opportunities for us for amazing research and mutually beneficial collaboration.鈥�

Building on Momentum

Just weeks into the role, Berinstain says he鈥檚 already felt the energy that surrounds space at 麻豆原创.

鈥淚 participated in Space Week at 麻豆原创 鈥� and I came away [from that experience realizing] how pervasive and important space is to the culture of the institute,鈥� he says. “So it feels like I鈥檝e got to catch up to that momentum. It鈥檚 an honor. It’s a challenge. It’s wonderful to leverage that for FSI.鈥�

Ask Berinstain about his leadership style, and don鈥檛 be surprised if he starts with a pop culture reference.

鈥淒o you watch聽The Big Bang Theory?鈥� he says. 鈥淪heldon Cooper has that line: 鈥業鈥檓 not crazy. My mom got me tested.鈥� Well, I鈥檝e been tested for my leadership style.鈥�

According to that assessment, Berinstain falls into what鈥檚 known as a 鈥減arental鈥� leadership style 鈥� a label he鈥檚 quick to unpack.

鈥淚t sounds funny,鈥� he says, 鈥渂ut what it really means is guided leadership. I鈥檓 very team-oriented. I鈥檓 resilient. I deal with situations head-on.鈥�

At the core of that approach is trust 鈥� trusting people to do their best work when they feel supported and empowered.

鈥淭here are people here who’ve been doing amazing work for a long time. I want to build on that,鈥� he says.

A Bigger Picture of Impact

For Berinstain, success at FSI isn鈥檛 just about dollars raised 鈥� it鈥檚 about alignment and purpose.

鈥淚 prefer to think of research funding as impact,鈥� he says, 鈥渁s contributions to 麻豆原创, to Florida and to our country. Let’s meet our own priorities and help others meet theirs. That鈥檒l help in our growth.鈥�

With a strong space legacy, a collaborative spirit and a rapidly expanding frontier ahead, Berinstain sees FSI entering a new era of possibility as a leader in space research.

Simply put, 鈥渋t鈥檚 a dream job,鈥� he says.

Founded in 1963 with the mission to provide talent for Central Florida and the growing U.S. space program, the university鈥檚 extensive involvement in space research and education not only drives innovations in space technology but also prepares the next generation of leaders in the field.

With more than 40 active NASA projects totaling more than $67 million in funding, 麻豆原创 continues to push the frontiers of space research, and its contributions promise to help shape the future of humanity’s presence in the cosmos.

鲍颁贵鈥檚 cutting-edge areas of space expertise include:

Space Medicine

鲍颁贵鈥檚 College of Medicine is pioneering new frontiers in aerospace medicine, positioning itself as a leader in space health research and education. Spearheaded by initiatives to create an interdisciplinary curriculum, 麻豆原创 is integrating expertise from engineering, medicine and nursing to address the unique health challenges of space exploration.

The college is building on existing research in space health, including innovative studies on the effects of microgravity on bone health, which could lead to improved protection for astronauts. Collaborations across disciplines, such as testing therapeutics for radiation protection and developing antimicrobial solutions for space station environments, highlight 鲍颁贵鈥檚 commitment to advancing astronaut health and shaping the future of space medicine.

Space Propulsion and Power

麻豆原创 is advancing space propulsion with groundbreaking research that could make space travel more efficient and viable for future missions. Researchers are developing innovative hypersonic propulsion systems, such as rotating detonation rocket engines, which harness high-speed detonations to increase propulsion efficiency and reduce fuel consumption 鈥� an advancement that could significantly lower costs and emissions associated with space travel, creating new commercial opportunities in the industry. 麻豆原创 is taking its hypersonics research even further with its recently launched Center of Excellence in Hypersonic and Space Propulsion 鈥� the HyperSpace Center.

Additionally, 麻豆原创 teams are exploring novel power systems for spacecraft venturing far from the sun, where solar energy becomes impractical. With funding from NASA, researchers are creating storable chemical heat sources capable of providing essential heat and power in extreme environments, from the icy surfaces of distant moons to the intense heat of Venus.

Space Technology and Engineering

麻豆原创 is forging the future of space technology with innovations that push the boundaries of lunar and deep space exploration. Through advancements in lunar resource utilization, 麻豆原创 has developed methods to efficiently extract ice from lunar soil so that it can be transformed into vital resources like water and rocket fuel, while new techniques for processing lunar soil drastically reduce construction costs for infrastructure such as landing pads.

麻豆原创 researchers are also pioneering 3D-printed bricks made from lunar regolith that withstand extreme space conditions, setting the foundation for resilient off-world habitats. Lunar regolith is the loose dust, rocks and materials that cover the moon鈥檚 surface.

鲍颁贵鈥檚 Exolith Lab, part of the , continues to lead in space hardware testing, advancing resource extraction and lunar construction technologies. Meanwhile, FSI’s CubeSat program is opening new doors in space exploration with compact, affordable satellites that give students and researchers access to microgravity and beyond.

Space Commercialization

麻豆原创’s new space commercialization program 鈥� led by , College of Business professor of practice and associate provost for space commercialization and strategy 鈥� positions the university as a leader in space-related business education.

Autry will guide the college鈥檚 efforts to deliver Executive and MBA programs in space commercialization, driving curriculum development and establishing space-focused programs that equip students to lead in the growing commercial space industry.

In addition to the space commercialization聽program, Autry will be working with external stakeholders, including NASA, the U.S. Space Force and commercial firms like Blue Origin, SpaceX and Virgin Galactic, to develop opportunities to advance mutual interests in space.

This includes working with Kennedy Space Center to lead a State University System partnership with the state of Florida to develop the necessary talent to maintain and expand Florida鈥檚 leadership in space exploration and commercialization.

Autry will also be leading 鲍颁贵鈥檚 effort to develop and execute a roadmap for the university鈥檚 SpaceU brand through targeted investments in talent and facilities.

Space Domain Awareness

麻豆原创 is advancing space domain awareness research to protect critical assets in orbit by developing sophisticated algorithms for tracking and predicting the movement of objects such as satellites and asteroids, so they don鈥檛 collide with spacecraft. Under the guidance of aerospace engineering expert Tarek Elgohary, 麻豆原创 researchers are creating a computational framework to rapidly and accurately track space objects in real time. This initiative is backed by the U.S. Air Force Office of Scientific Research Dynamic Data and Information Process Program.

麻豆原创 is also addressing the growing issue of orbital debris through a NASA-funded study that includes researchers from 鲍颁贵鈥檚 FSI and . This project seeks to increase public awareness and support for managing space debris, a hazard to satellites and potential space tourism ventures.

Workforce Development

麻豆原创 is propelling students toward dynamic careers in the space industry with hands-on programs and sought-after internship opportunities. Through the new engineering graduate certificate in electronic parts engineering, developed in collaboration with NASA, students are gaining essential skills in testing and evaluating space-ready electronic components 鈥� a key advantage for aspiring space professionals.

Additionally, 麻豆原创 students can benefit from hands-on internships at Kennedy Space Center, where they gain real-world experience in various fields, from engineering to project management.

At the , students gain direct experience in microgravity research and robotics. The center embodies 鲍颁贵鈥檚 commitment to democratizing space access, offering pathways for students from all backgrounds to participate in and contribute to the growing space industry.

FSI鈥檚 CubeSat program further immerses students in satellite design and operation, offering direct involvement in active space missions.

Planetary Science

麻豆原创’s planetary science program is driving breakthroughs in space exploration with projects spanning the moon, Mars and beyond. The NASA-funded Lunar-VISE mission, led by 麻豆原创, will explore the Gruithuisen domes on the far side of the moon to understand their volcanic origins, potentially unlocking insights crucial for future space exploration.

Complementing this, 麻豆原创 researchers are contributing to NASA鈥檚 Lunar Trailblazer mission, which will map water ice deposits on the moon 鈥� an essential resource for sustained stays in space. On another front, 麻豆原创 scientists are studying dust behavior in microgravity through experiments that flew on Blue Origin鈥檚 New Shepard rocket, potentially leading to strategies for mitigating lunar dust, a challenge for electronics and equipment on future missions.

Expanding its reach beyond the moon, 鲍颁贵鈥檚 planetary science research involves asteroid studies, including the high-profile OSIRIS-REx mission to asteroid Bennu and examining seismic wave propagation in simulated asteroid materials to understand asteroid evolution and early planetary formation. 麻豆原创 is also home to the , a node of NASA鈥檚 Solar System Exploration Research Virtual Institute, which facilitates NASA鈥檚 exploration of deep space by focusing its goals at the intersection of surface science and surface exploration of rocky, atmosphereless bodies.

Additionally, 麻豆原创 researchers are studying trans-Neptunian objects and using the James Webb Space Telescope to explore the solar system’s outer reaches, analyzing ancient ices to uncover clues about the solar system’s history, while also investigating exoplanets to advance our understanding of other planets and to search for life beyond Earth.

In parallel, 麻豆原创 researchers are also advancing bold ideas for terraforming Mars through nanoparticle dispersion to create warming effect, making the Red Planet potentially more habitable.

麻豆原创 researchers have also contributed their expertise to multiple high-profile NASA missions, including Cassini, Mars Pathfinder, Mars Curiosity, and New Horizons.

Advancing Astrophotonics, History and Policy

鲍颁贵鈥檚 space research spans pioneering astrophotonics technology, studies in space history and critical analyses in space policy, each offering unique insights into the universe. The within CREOL, the College of Optics and Photonics, is pushing the boundaries of photonics and astronomy, using tools like photonic lanterns, fiber optics, and hyperspectral imaging to detect cosmic phenomena and address profound questions about dark energy.

Meanwhile, delves into space history, exploring the cultural and scientific impacts of milestones like the Apollo missions and the Space Shuttle program, helping illuminate humanity鈥檚 journey into space.

The contributes to this comprehensive approach with its broad studies of space policy, both domestically and internationally, including examining military space policy and rising space powers. The work involves studying space law, international agreements, and policy frameworks that guide space activities, which is essential for addressing the governance and strategic planning needed for space exploration and utilization.

Pioneering Tomorrow鈥檚 Space Exploration

麻豆原创 is pushing the frontiers of space research and education, tackling today鈥檚 challenges while preparing for the demands of future space missions. As the new space race continues, 鲍颁贵鈥檚 forward-thinking approach will continue to drive progress, inspire new possibilities and expand humanity鈥檚 reach into the universe.

麻豆原创 launched the Center of Excellence in Hypersonic and Space Propulsion 鈥� HyperSpace Center for short 鈥� on Wednesday alongside leaders of the U.S. Air Force Office of Scientific Research, one of the university鈥檚 main partners in hypersonic research.

The HyperSpace Center will advance the research and innovations of world-renowned faculty members like Kareem Ahmed, a professor of mechanical and aerospace engineering in the College of Engineering and Computer Science, whose team has received multiple U.S. Department of Defense (DoD) grants to develop hypersonic technology.

鈥淲hat we create here and across 麻豆原创 will define the aerospace and defense industries for generations.鈥� 鈥� Alexander N. Cartwright, 麻豆原创 president

麻豆原创 President Alexander N. Cartwright and Col. Janelle T.H. Jackson, deputy director of the Air Force Office of Scientific Research and detachment 14 commander, spoke at the launch ceremony at the new center in the Central Florida Research Park adjacent to the 麻豆原创 main campus. They were joined by U.S. Reps. Darren Soto and Daniel Webster and State Rep. Susan Plasencia.

鈥淲hat we create here and across 麻豆原创 will define the aerospace and defense industries for generations,鈥� Cartwright says. 鈥溌槎乖� has always been an institution for people who have dared to invent a better future. We are also an institution that recognizes no one builds the future alone.

It takes strong partnerships, shared vision, and a relentless commitment to be bold together. 麻豆原创 and the Air Force have an incredible history of collaboration, and I am excited about our dedication to continuing to build, innovate, and lead together.鈥�

Col. Jackson celebrated the significance of the HyperSpace Center bringing together the DOD, 麻豆原创 聽and cutting-edge technology.

鈥淭oday, the 麻豆原创 is not only opening a new, top-notch facility where leading-edge research in hypersonics and space propulsion will take place,鈥� Col. Jackson says. 鈥淵ou are also opening doors and opportunities to students from various backgrounds.鈥�

鈥淭hey are gaining the opportunity to realize their dreams, to work towards expanding the scientific frontier and disciplines that are of great importance to the Department of Defense and also to the larger DoD ecosystem. The hyperspace hub is a place where these students can become the thought leaders and problem solvers of tomorrow.鈥�

Ahmed鈥檚 research team includes 40 graduate students and 25 undergraduates. The team鈥檚 research will transition from other labs on campus into the new facility and will benefit from a unique and upgraded testing environment for hypersonic materials, aerodynamics and propulsion. The Air Force Office of Scientific Research has supported Ahmed鈥檚 team through multiple research grants.

Hypersonic propulsion allows for air travel at speeds of Mach 6 to 17, meaning six to 17 times the speed of sound, or more than 4,600 to 13,000 mph.

Advanced hypersonic propulsion systems are a national priority and are essential to maintaining U.S. national defense as global technological advancements continue to evolve. High-speed propulsion research requires hypersonic facilities that can generate the representative flight Mach numbers.

For space travel, hypersonic technology holds promise for opening up the boundaries of space exploration as it fuels flights through the Earth鈥檚 atmosphere at very high speeds and allows for safe and efficient entries and exits through planetary atmospheres.

On Earth, flying at hypersonic speeds means going from New York to London in less than 15 minutes 鈥� making it much more convenient to travel to close an important business deal, attend a best friend鈥檚 wedding or see a bucket-list sporting event.

Ahmed鈥檚 research holds promise in all of those areas 鈥� and also is preparing students on his team to be innovators and leaders in the field after they graduate, demonstrating why 麻豆原创 is both Florida鈥檚 premier engineering and technology university, and the nation鈥檚 No. 1 supplier of graduates to the aerospace and defense industry for six years in a row, according to Aviation Week Network.

鈥淚t鈥檚 important that 麻豆原创 lead this research, primarily because of the student talent that we have,鈥� Ahmed says. 鈥淚ndustry is interested in our top talent. Once they graduate, they are already hired by industry, pretrained on the topics they would explore and they become the next generation of leaders in this technology.鈥�

The DoD is providing more than $20 million in funding to support Ahmed鈥檚 research, including for developing the聽first hypersonic rotating detonation rocket engine and creating a morphing hypersonic engine.

鲍颁贵鈥檚 longstanding partnership with the U.S. Air Force extends beyond hypersonics.

鈥湵涔筲�檚 history, and our commitment to continue pushing the boundaries of what is possible, have helped to position us as Florida鈥檚 premier engineering and technology university.鈥� 鈥� Alexander N. Cartwright, 麻豆原创 president

麻豆原创 and Air Force ROTC Detachment 159 were recipients of the DoD ROTC and Educational Institution Partnership Excellence Award in 2021-22, when the 麻豆原创 Air Force ROTC program ranked first out of 145 nationwide.

The Air Force also has funded other 麻豆原创 research projects outside of hypersonics, including how to make semiconductors immune to radiation from the sun and other celestial bodies and also how to ensure reliability and design consistency in semiconductors.

鈥湵涔筲�檚 history, and our commitment to continue pushing the boundaries of what is possible, have helped to position us as Florida鈥檚 premier engineering and technology university,鈥� Cartwright says. 鈥淥ur geographic location 鈥� surrounded by industries eager to collaborate on research and workforce development 鈥� puts 麻豆原创 in a unique position to capitalize on emerging opportunities.

We are thinking beyond theory … we are establishing the foundation for revolutionary technology and innovation that will shape both the defense and civilian sectors.鈥�

Ten Knights were selected for the 2024 Department of Defense (DoD) Science, Mathematics and Research for Transformation (SMART) Scholarship, an educational and workforce opportunity available to undergraduate and graduate students pursuing STEM degrees. The program covers the cost of tuition and education related expenses, provides an annual stipend of at least $30,000 a year, provides a mentored internship experience during the summer and offers employment at a DoD facility upon degree completion. The goal of the program is to build a workforce of leaders in the STEM disciplines.

The recipients are:

• Brandon Allen
• Matthew Hadad
• Emily Kinkead
• Joseph Lee
• Thomas Nguyen
• Conner Parsay
• Jordyn Sitson
• Jeffery Smith
• Enilda Velazquez 鈥�20
• Louis Vest

Brandon Allen

Master鈥檚 in electrical engineering student

As a gifted math and science student, Allen says he always wanted to be an engineer, something his mom encouraged during his childhood. He chose electrical engineering for its novelty compared to other more well-known disciplines.

鈥淚 chose electrical engineering because it deals with concepts that are so unknown to most people, almost as if it were a form of magic,鈥� Allen says.

He was drawn to 麻豆原创 for two reasons: his family in close proximity, and for its optics programs, which are ranked in the top 30 worldwide according to U.S. News & World Report.

鈥淚 chose 麻豆原创 because of its optics program. In my line of work, I deal with infrared cameras and other electro-optical devices,鈥� Allen says. 鈥淎lso, I have family members in the area that will help make 麻豆原创 feel like a home away from home.鈥�

Allen adds that he applied to the SMART scholarship program for the financial opportunity to attend school full time.

鈥淚 plan on using my education to help foster innovation within the Air Force,鈥� he says. 鈥淎lso, I have hopes that an M.S. degree will help me obtain promotions and take on more of a leadership role.鈥�

Matthew Hadad

Bachelor鈥檚 in electrical engineering student

Electrical engineering major Hadad knew he had a penchant for electrical engineering from his interest in circuit math from a high school course, AP Physics I. His pursuit of the field is also an homage to his mom, who had planned on studying electrical engineering herself.

鈥淢y mother was going to be an electrical engineering major, but she could not finish because she had given birth to me, and I was a bigger priority for her than her major,鈥� Hadad says.

麻豆原创 wasn鈥檛 the school he dreamed of growing up, but a high school friend convinced him to become a Knight and he hasn鈥檛 looked back since. When he learned of the opportunity to pursue the SMART scholarship, its military ties were a natural fit for him. Hadad says he was always fascinated with naval history, particularly of navies during World War II.

鈥淚 am very grateful for the SMART Scholar program. After I receive my M.S. degree, I plan to work for the U.S. Department of Defense for as long as possible,鈥� Hadad says. 鈥淚t鈥檚 something I have wanted to do and could see myself doing in the future.鈥�

Emily Kinkead

Bachelor鈥檚 in photonics science and engineering student

As a transfer student, Kinkead has yet to step foot on the 麻豆原创 campus, but she鈥檚 already made quite the impact. The photonics science and engineering major spent the summer at the U.S. Army Combat Capabilities Development Command Armaments Center at the Picatinny Arsenal in New Jersey, where she鈥檚 already participated in several STEM outreach programs. She says she鈥檚 excited for the opportunity to intern there and looks forward to learning as much as she can from the experience.

鈥淭here is so much to learn and experience,鈥� Kinkead says. 鈥淗aving the ability to do so with the support of SMART means that I will be pushed and challenged as I pursue my degree, which I hope one day will make me an invaluable member of the DoD family.鈥�

Joseph Lee

Doctorate in chemistry student

After serving on the front line for the U.S. Army, Lee aims to make a difference in military labs to advance nuclear security research. As a chemist, his doctoral research, which is conducted under the guidance of Assistant Professor Vasileios Anagnostopoulos, focuses on understanding the interactions of radioactive elements, such as actinides, with molecules found in nature. Applications for this work can range from radioactive waste management 鈥� including response to events such as Fukushima nuclear accident in 2011 鈥� to efficient use of nuclear fuel and even recycling.

鈥淚 aspire to join the Airforce Technical Application Center (AFTAC) located on Patrick Space Force Base upon my graduation,鈥� Lee says. 鈥淭here I will have the opportunity to contribute to the nation鈥檚 mission related to nuclear security and global monitoring of nuclear activities under the DoD.鈥�

With the SMART Scholarship, Lee is on the right path to his dream career as he鈥檒l be interning at AFTAC each summer until he graduates.

鈥淭he DoD is offering opportunities for the next generation of subject matter experts in the field of nuclear science and technology,鈥� Lee says. 鈥淎long with this, 麻豆原创 is providing me the fundamental academic resources and training as a graduate student. These opportunities will provide me with a unique skillset in the future of scientific progression.鈥�

Thomas Nguyen

Doctorate in biomedical engineering student

Nguyen is no stranger to prestigious internships. The biomedical engineering doctoral student previously completed the Naval Research Enterprise Internship Program (NREIP), sponsored by the Office of Naval Research. Fittingly, Nguyen completed his DoD SMART internship with the Naval Air Warfare Center Training Systems Division (NAWCTSD). He says both his time at 麻豆原创 and his experience with NREIP have prepared him for this opportunity.

鈥淣otably, my involvement in projects like the T-45 Flight Simulator Development and the Dental Aerosol Reduction System (DARS) project during my NREIP internships has provided me with firsthand experience in applying engineering principles to defense-related simulations,鈥� Nguyen says. 鈥淭hese experiences have prepared me to excel in a dynamic and challenging environment, where innovation and technical expertise are paramount.鈥�

Nguyen will work under the mentorship of senior research and development engineer Rocco Portoghese, assisting with projects that leverage simulation technologies to enhance the effectiveness of military training. Through his work, Nguyen hopes to enhance his knowledge of simulation technologies, develop technical skills in electrical circuitry and 3D design, and emerge from the internship as a leader ready for a career with a defense organization.

鈥淭his opportunity represents a pivotal moment in my academic and professional journey, allowing me to contribute directly to defense technology while furthering my education,鈥� Nguyen says. 鈥淚 am eager to immerse myself in challenging projects and collaborate with experts in the field, ultimately making meaningful contributions to the defense industry.鈥�

Jordyn Sitson

Bachelor鈥檚 in information technology聽 student

After graduation, Jordyn Sitson plans to become a cyber analyst and researcher. Now in her senior year, she鈥檚 already lined up a job with the DoD.

鈥淢y favorite part of the cybersecurity field has always been finding the clues that lead up to a cyber-attack, and by pursuing a career as an analyst and researcher I鈥檒l be able to search for these traces firsthand and stay up to date on any trends that may be related to the cause of potential cyberattacks,鈥� Sitson says.

The computer science major heard about the SMART Scholarship through a speaker at the Women in Cybersecurity Club at 麻豆原创. 鈥淭he scholarship is still relatively unknown and easy to apply for,鈥� Sitson says. 鈥淚 encourage anyone in STEM that is looking for a chance to get a head start working and gaining experience at a DoD facility to apply for this scholarship.鈥�

This summer, Sitson gained experience as a cybersecurity intern at NAVFAC, the Naval Facilities Engineering Systems Command in Jacksonville, Florida. There she worked with four cybersecurity teams, which helped her decide to work with the Operational Technology team for the following summers.

鈥淟earning information and applying it are completely different so I hope that with this real-world experience I become a better cyber analyst that can help contribute to NAVFAC鈥檚 mission,鈥� Sitson says.

Jeffery Smith

Master鈥檚 in civil engineering student

鲍颁贵鈥檚 reputation for engineering education, its proximity to prominent engineering organizations and its partnerships with industry giants like the DoD persuaded Smith to become a Knight. That decision paid off for Smith, who will conveniently complete his internship at his current workplace, the Jacksonville District Office of the U.S. Army Corps of Engineers.

Smith works under the mentorship of civil engineer Tony Ledford, learning how to apply the concepts he鈥檚 learned in the classroom to the real world.

鈥淚 look forward to benefiting from Tony Ledford’s experience as a mentor and learning about creative engineering techniques, efficient project management techniques and problem-solving techniques,鈥� Smith says. 鈥淚n addition, I’m excited to expand my professional networks and ties inside the DoD, which will be very helpful for my future job.鈥�

Smith says the opportunity to work for the DoD, and to receive financial support for his graduate students, were just a few benefits that drew him to the SMART Scholar program.

鈥淕etting chosen as a SMART Scholar is a thrilling and incredibly fulfilling experience,鈥� Smith says. 鈥淜nowing that my efforts and commitment have been acknowledged in a fiercely competitive sector is a great source of pride and achievement.鈥�

Enilda Velazquez 鈥�20

Doctorate in human factors and cognitive psychology student, bachelor鈥檚 in psychology alum with minors in cognitive sciences, and international and national security

Inspired by her parents鈥� work in civilian defense through the U.S. Air Force and U.S. Navy, Velazquez aims to be a scientist contributing to U.S. national security. At 麻豆原创, Velazquez has engaged in several research experiences, including previous efforts with the Transportation Research Group Lab and current work with the Minds in Technology, Machines in Thought (MIT2) Lab.

鈥淢y research is on visual performance, but specifically multi-target search, [which is] how we look at multiple things of interest in a scene that has other things that are not of interest,鈥� she says. 鈥淭he biggest impact of my work is safety.鈥�

While Velazquez says she鈥檚 had some valuable research experiences at 麻豆原创, she鈥檚 looking forward to taking her work to the next level with optics work at the C5ISR Center, which is one of eight science and technology domains within the U.S. Army Combat Capabilities Development Command, known as DEVCOM. She also says she鈥檚 looking forward to serving as an apprentice to a mentor working in the field.

鈥淚’m very excited just be on hands-on projects and kind of learn by doing. I love learning by doing. I feel like that’s most of my career has been learning by doing,鈥� Velazquez says. 鈥淎nd so just to be on projects where I can see this kind of research be applied real time, I feel like that’s honestly the most invaluable part of this entire thing.”

Louis Vest

Doctorate in aerospace engineering student

Before Louis Vest decided a doctoral degree, he debated following in his father and grandfather鈥檚 steps to join the military. With the SMART Scholarship program, he鈥檚 able to serve his country in a different way.

鈥淢y father instilled in me a very serious work ethic and a dedication to take advantage of opportunities that he did not have, in this case, being able to go to school,鈥� Vest says. 鈥淚 think the biggest driving force for [why I applied to] SMART was 鈥� 聽having the opportunity to serve my country as a civilian contractor with the DoD.鈥�

Vest always knew he wanted to be an engineer, but his journey at 麻豆原创 solidified his career would be in the aerospace industry. The doctoral student鈥檚 research focuses on fundamental fuel chemistry, and he is mentored by Professor Subith Vasu, who studies clean energy and hypersonic travel advancement.

鈥淯pon connecting with [Dr. Vasu], he was the reason that I came out to 麻豆原创,鈥� Vest says. 鈥淚 had done a little bit of reading on research opportunities with Vasu that students were able to pave their way through, and it felt like a very natural fit. 鈥� The environment, and by extension the community, that 麻豆原创 fosters, particularly in the sciences, is unparalleled.鈥�

Next summer, he鈥檒l intern at the Naval Surface Warfare Center in Indian Head, Maryland, gaining hands-on experience and industry insights that would normally take years to achieve, he says.

鈥淚 hope to be a part of the next generation of researchers who find the most efficient fuels to be used in the aerospace and astronomical industries,鈥� Vest says, 鈥淎nd I’m hoping to gain the opportunity to work alongside other engineers and partners to effectively help pave the way for the next frontier, which I believe is a space.鈥�

Hypersonic propulsion would allow for air travel at speeds of Mach 6 to 17, or more than 4,600 to 13,000 miles per hour, and has applications in commercial and space travel.

Over the past year, the DoD has awarded funding to hypersonics research led by Mechanical and Aerospace Engineering Professor Kareem Ahmed to support the advancements he鈥檚 making in the technology.

The awards are funding the construction of a hypersonic testing facility, flight experiments and further advancements of the technology.

The support is a testament to the progress 麻豆原创 has made in the field, including developing the first hypersonic rotating detonation rocket engine, which could allow for air travel from New York to L.A in less than 30 minutes. It also comes on the heels of recently received DoD funding to build a morphing hypersonic engine.

鈥淗igh-hypersonic propulsion technology is being born here, similar to how new technology was developed at Kennedy Space Center during the space era,鈥� Ahmed says. 鈥淣ow it鈥檚 happening at 麻豆原创. The new funding highlights that we’re a major player in hypersonic propulsion.鈥�

The most recent projects include:

High-Hypersonic Enthalpy Facility (HiHYPER) for Hypersonic and Space Propulsion

Achieving ultra-high-speed flight at hypersonic speeds is a national priority and an international focus driving the hypersonics and space race. Such systems would allow flight through our atmosphere at very high speeds and allow efficient entry and exit from planetary atmospheres. This will make hypersonic defense systems, space exploration, and intercontinental travel as routine as intercity travel is today.

Advanced hypersonic propulsion systems are needed to maintain the technological superiority of the U.S. Air Force relative to the growing technological threat from adversaries. High-speed propulsion research requires hypersonic facilities that could generate the representative flight Mach numbers and enthalpies.

This project, funded by the U.S. Air Force Office of Scientific Research (AFOSR), aims to develop a unique mid-scale high-hypersonic enthalpy propulsion testing facility at 麻豆原创 for integrated hypersonic materials, aerodynamics, and propulsion research (HiHYPER). HiHYPER will provide significant new capabilities to explore the fundamentals of the hypersonic regime and overcome the most significant national challenges where advances are needed in hypersonic research.

Hypersonic Flight Experiment for High-Speed Propulsion Detonation Fundamentals

This project鈥檚 objective is to develop the experimental hardware for a flight experiment to stabilize and investigate standing oblique detonation waves under an AFOSR program.

The technology offers improved jet propulsion engine efficiency so that more power is generated while using less fuel than traditional propulsion engines, thus lightening the fuel load and reducing costs and emissions.

In addition to聽faster air travel, the technology could also be used in聽rockets for space missions聽to make them lighter by requiring less fuel, travel farther and burn more cleanly.

The flight experiments are critically needed to provide the structure and dynamic details of standing oblique detonation waves in a hypersonic flight regime. The flight experimental results will form the foundation for hypersonic detonation engines.

Distinguished Fellow: Advanced Flow-Independent Fuel Injector for Naval Propulsion

This project, funded by the Office of Naval Research, will explore and document the evolution spray and splash dynamics of the flow independent fuel injector, a type of fuel injector designed to deliver a consistent and precise amount of fuel regardless of variations in fuel pressure.

Fuel control will improve Navy applications system performance that are reliant on jet-in-crossflow fuel injectors commonly used in combustors and augmentors to fuel modern Navy propulsions systems, such as the F35.

These improvements will lead to efficient propulsion and power systems that control jet fueling for enhanced performance. Fuel injection is a critical technology for Navy Aircraft propulsion, unmanned aerial vehicles, ship propulsion and power, ramjets/scramjets and missiles.

Researcher Credentials

Ahmed joined 鲍颁贵鈥檚 Department of Mechanical and Aerospace Engineering, part of 鲍颁贵鈥檚 College of Engineering and Computer Science, in 2014. He is also a faculty member of the Center for Advanced Turbomachinery and Energy Research and the Florida Center for Advanced Aero-Propulsion. He served more than three years as a senior aero/thermo engineer at Pratt & Whitney military engines working on advanced engine programs and technologies. He also served as a faculty member at Old Dominion University and Florida State University. At 麻豆原创, he is leading research in propulsion and energy with applications for power generation and gas-turbine engines, propulsion-jet engines, hypersonics and fire safety, as well as research related to supernova science and COVID-19 transmission control. He earned his doctoral degree in mechanical engineering from the State University of New York at Buffalo. He is an American Institute of Aeronautics and Astronautics associate fellow and a U.S. Air Force Research Laboratory and Office of Naval Research faculty fellow.

In a first-of-its-kind mission for the United States that spanned over seven years, the unmanned spacecraft mapped and studied the surface of the near-Earth asteroid Bennu, then retrieved a sample for researchers to study the asteroid鈥檚 composition.

Topping the list was a story on the world鈥檚 first energy-saving paint inspired by butterflies. The plasmonic paint utilizes a nanoscale structural arrangement of colorless materials 鈥� aluminum and aluminum oxide 鈥� instead of pigments to create colors. The paint can contribute to energy-saving efforts and help reduce environmental impacts.

Other stories included a $12.6 million Defense Advanced Research Projects Agency grant looking to create self-repairing, biological and human-engineered reef-mimicking structures. 麻豆原创 is helping design reef structures that will be used to mitigate coastal flooding, erosion and storm damage that threaten civilian and Department of Defense infrastructure and personnel. Another story featured new research on the earliest presence of Homo sapiens in Southeast Asia, pushing back the presence of humans in that part of the world by at least 20,000 years and a human presence in the region for at least 56,000 years.

Here are the Top 10 麻豆原创 Research News Stories of 2023:

1. 麻豆原创 Researcher Creates World鈥檚 First Energy-saving Paint 鈥� Inspired by Butterflies

2. The Long Journey of NASA鈥橲 OSIRIS-REx

3. Human Migration Timeline Redrawn by Fresh Fossil Analysis

4. New 麻豆原创-developed Battery Could Prevent Post-hurricane Electric Vehicle Fires

5. 麻豆原创 Researchers Are Advancing AI-assisted Drug Discovery

6. 麻豆原创 is Designing Self-repairing Oyster Reefs to Protect Florida鈥檚 Coastlines

7. New DOD-funded Project Will Develop Morphing Hypersonic Engine

8. 麻豆原创 Researchers Create Bioabsorbable Implants for Better Bone Healing

9. 麻豆原创 Team Awarded $2.3M Grant for Innovative Intervention to Prevent Falls

10. Deadly Frog Disease More Prevalent in Central Florida Than Expected, 麻豆原创 Study Finds

The annual top 10 list is based on聽麻豆原创 Today聽page views and coverage 麻豆原创 research received by global, national, state, and local media. The stories were generated by news releases and pitches from 麻豆原创 Communications and Marketing, 鲍颁贵鈥檚 Office of Research and 鲍颁贵鈥檚 colleges.

Raytheon Technologies, a research partner of the Department of Mechanical and Aerospace Engineering, was so impressed with the work of recent intern Sydney Giannuzzi that they honored her with an Innovation Achievement Award for her outstanding contributions to their research and to the team.

鈥淪ydney’s work ethic and enthusiasm for the project are remarkable, and it has been a pleasure to have her be our intern this summer,鈥� the awarded certificate reads. 鈥淲e are looking forward to continued collaboration with her throughout her Ph.D. work.鈥�

Giannuzzi, an aerospace engineering doctoral student, completed the internship this past summer at the defense company鈥檚 Hartford, Connecticut, location. She worked on the design and analysis of a novel flow valve that can more easily test operating conditions for aircraft engines. The goal is to better understand the damping process so that aircraft engine designers can prevent the dangerous conditions that could lead to engine failure.

The project is funded through a $899,000 grant from the Office of Naval Research, which facilitated the collaboration between Raytheon and 麻豆原创. Jeffrey Kauffman, director of 鲍颁贵鈥檚 aerospace engineering program, is the principal investigator of the project, which includes two 10-week internships at Raytheon.

Although other 麻豆原创 students have assisted with the research, Giannuzzi is the first to work on the project as a Raytheon intern. She says she鈥檚 thrilled with the progress her team made and with the recognition it garnered.

鈥淚 am honored that my team and supervisor appreciated my contribution and thought to submit me for this award,鈥� Giannuzzi says. 鈥淚t means a lot to be recognized by such a talented group of individuals.鈥�

The project taught her the value of collaboration and how to work with various teams to produce a viable result 鈥� a lesson that will stay with her as she embarks on her career.

鈥淚 learned how valuable it is to get to know the people you work with and to identify everyone鈥檚 strengths,鈥� Giannuzzi says. 鈥淲e can accomplish so much more together if we utilize each other鈥檚 knowledge and experience.鈥�

After graduation, Giannuzzi plans to work in the aerospace industry with a focus on structural dynamics for aircraft and spacecraft. She says that 麻豆原创 was always the top choice for her doctoral education due to the location and its reputation for being a partnership university with relationships with aerospace engineering companies.

鈥淐onnecting with Dr. Kauffman helped to solidify my plans when I learned about his research focused on structural dynamics and adaptive structures,鈥� Giannuzzi says. 鈥淚 don鈥檛 think I could have found a better fit for me in regard to my research interests and the connections that I have made through my research at 麻豆原创.鈥�

This year, 165 students from 68 U.S. institutions were selected for this fellowship, which lasts for three years and covers tuition and fees for any doctoral program in the country. Participants also receive a monthly stipend and are paired with a research mentor who will guide them through their chosen project. At the end of the fellowship, students have the chance to present their research at the annual NDSEG Conference.

Since the program鈥檚 inception in 1989, more than 4,500 fellowships have been awarded to college students. This year鈥檚 麻豆原创 awardees are:

• Andrew DeRusha 鈥�22, aerospace engineering
• Daniel Dyson 鈥�21 鈥�22MS, aerospace engineering and Burnett Honors Scholar
• Alphonse Marra, physics

Andrew DeRusha 鈥�22

DeRusha may not have his career path solidified yet, but he鈥檚 already following in his father鈥檚 footsteps. His dad worked as an engineer while DeRusha was growing up and introduced him to the ultimate space saga, Star Wars. His interest in the franchise, paired with the influence of his father鈥檚 career, led him to pursue a degree in aerospace engineering.

DeRusha walked across the 麻豆原创 stage in Spring 2022 and has already completed the first year of his aerospace engineering doctoral degree. He says the NDSEG fellowship will help him explore his interests and entertain future engineering and research possibilities.

鈥淭he fellowship is the perfect opportunity to help me find out what I want to do,鈥� DeRusha says. 鈥淎ll I know is that I love engineering and am passionate about research. I hope that whatever my career ends up being, I can continue to work in a research role.鈥�

DeRusha will flex his research skills as he develops a multi-species laser-absorption sensor, used in diagnostics for combustion systems. He鈥檒l also continue to work in the Vasu Lab, led by Professor of Aerospace Engineering Subith Vasu, an experience that led him to the NDSEG fellowship.

鈥淚 am incredibly excited and honored to have been selected for the fellowship,鈥� DeRusha says. 鈥淚t鈥檚 incredibly satisfying to receive recognition, but it also reminds me to be thankful for all the people who helped me on the path to being given this award.鈥�

Daniel Dyson 鈥�21 鈥�22MS

Like many aerospace engineering students, Dyson was drawn to the field of astronautics through the space shuttle program and the burning questions it posed in his young mind: How does a rocket function? How can it carry a payload from Earth to space?

His career path was set after attending the Florida Space Grant Consortium Engineering Academy, which allowed him to tour the 麻豆原创 engineering labs, design and test model rockets, build popsicle-stick bridges, and code in Java.

鈥淭hese projects and my mentors from this program encouraged me to pursue a degree in engineering and really kickstarted my development as an engineer and a researcher,鈥� Dyson says.

After earning two degrees in aerospace engineering, interning at Northrop Grumman and working on research projects with Vasu, Dyson is now a full-fledged engineer and researcher. He鈥檒l use the skills he鈥檚 honed at 麻豆原创 to complete his NDSEG research project, which aims to reveal new insights regarding combustion and explosion dynamics.

Dyson will specifically study the combustion of burning fuel droplets that contain nitrogen and their effects post-detonation as well as the combustion process of nitromethane. But perhaps his most compelling discovery will come from the experience itself. Dyson says he looks forward to future mentorship from scientists and engineers and learning more about careers in research.

At 麻豆原创, the two-time alum will still be mentored by Vasu as he completes his doctoral degree in aerospace engineering. Dyson says he chose to attend 麻豆原创 not only for its location and tuition support, but its reputation as SpaceU.

鈥淢ost importantly, I recognized 鲍颁贵鈥檚 reputation as a leader in providing the Space Coast with new engineers ready to tackle the biggest challenges in industry,鈥� Dyson says. 鈥淩emembering that it was outer space that initially encouraged me to pursue engineering in the first place, it seemed like I was destined to pursue engineering in Central Florida and become a Knight.鈥�

Alphonse Marra

Physics doctoral student Marra鈥檚 research began with ultrafast physics during his undergraduate studies at the University of Wisconsin-Madison. He became fascinated with the use of lasers to study phenomena at very short timescales.

鈥淭o me, physics is all about pushing the limits of our knowledge of the physical universe,鈥� Marra says.

After graduating with his bachelor鈥檚 degree, Marra began working at 麻豆原创 on a new project to build a laser alongside a well-respected group with a history of success. Marra鈥檚 focus on physics is attosecond science, and he works with Pegasus Professor Zenghu Chang. The next step in their research is to focus on generating few-cycle pulses capable of driving single-isolated attosecond pulses.

The NDSEG fellowship he鈥檚 received will give him greater flexibility with his research and allow him to travel to conferences like a seminar at the Air Force Institute of Technology, where he is presenting this fall.

鈥淚’m grateful for the staff members in the Department of Physics and the sense of community in the department, Marra says. 鈥淚 have a lot of people from 麻豆原创 to thank, from machinists to fellow students to professors and many others. I especially am grateful to my PI (principal investigator), professor Chang, for his dedication to our research.鈥�

Hypersonic propulsion would allow for air travel at speeds of Mach 6 to 17, or more than 4,600 to 13,000 mph, and has applications in commercial and space travel. Although the technology has been around since the 1960s, countries including the U.S., Russia and China, are racing to improve the systems to achieve more efficient and longer, more sustained hypersonic flight.

The $450,000 Naval Research Laboratory grant-funded project will develop a hypersonic engine that can morph or transform its configuration during flights to optimize performance.

鈥淢ost hypersonic engines are structurally fixed due to the challenging flight environment,鈥� says the project鈥檚 principal investigator Kareem Ahmed, a professor in 鲍颁贵鈥檚 . 鈥淥ur research will show the performance gains from an adaptable engine configuration that would self-optimize its surfaces to maximize performance power, thrust and travel distance which is the first of its kind for hypersonic engines.鈥�

Ahmed is a leading researcher in the field of hypersonics, achieving the first stabilized and sustained rotating detonation wave for hypersonic travel and heading a $1.5 million U.S. Department of Defense award to develop high-performance fuels for hypersonic propulsion.

This new research project is based off Ahmed鈥檚 work on 鈥渟cramjet鈥�, or supersonic combustion ramjet engines. The key feature of a scramjet engine is its ability to combust air at supersonic speeds without slowing it down to subsonic speeds, as is done in traditional jet engines.

Ahmed and his research team have developed an aerothermodynamic model for the hypersonic, morphing scramjet engine and are currently in the stage of experimental testing it to assess the performance. Aerothermodynamics analyzes the interaction of gases at high speeds and elevated temperatures.

鈥淲e are very happy for being selected for the program,鈥� Ahmed says. 鈥淥ur lab has been a leader and innovator in high-speed and hypersonic propulsion and this program gives our group the opportunity to contribute and make an impact.鈥�

Ahmed joined 鲍颁贵鈥檚 Department of Mechanical and Aerospace Engineering, part of 鲍颁贵鈥檚 College of Engineering and Computer Science, in 2014. He is also a faculty member of the Center for Advanced Turbomachinery and Energy Research and the Florida Center for Advanced Aero-Propulsion. He served more than three years as a senior aero/thermo engineer at Pratt & Whitney military engines working on advanced engine programs and technologies. He also served as a faculty member at Old Dominion University and Florida State University. At 麻豆原创, he is leading research in propulsion and energy with applications for power generation and gas-turbine engines, propulsion-jet engines, hypersonics and fire safety, as well as research related to supernova science and COVID-19 transmission control. He earned his doctoral degree in mechanical engineering from the State University of New York at Buffalo. He is an American Institute of Aeronautics and Astronautics associate fellow and a U.S. Air Force Research Laboratory and Office of Naval Research faculty fellow.