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 麻豆原创鈥檚 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 麻豆原创鈥檚 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 麻豆原创鈥檚 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.

Their discovery in the Cygnus X region sheds new light on and deepens a long-standing mystery about the ionization state of the interstellar medium 鈥� the sparse material that fills the space between stars within a galaxy. This is crucial to understanding galactic evolution.

Using the 100-meter Green Bank Telescope in West Virginia, the team detected radio spectral lines from helium in diffuse ionized gas in the Cygnus X region, a massive star-forming complex located about 25,000 light-years from the galactic center.

鈥淲e are still investigating. This can provide a better understanding of how energy flows from stars to the interstellar medium in the inner region of the galaxy works,鈥� says Roshi, who has served in a few of the world鈥檚 most advanced observatories over his 20-year career.

A Decades-Old Galactic Puzzle

According to the Big Bang theory, hydrogen and most of the helium in the universe were created in the moments after the initial cosmic event.

Ionization is the process where energetic radiation (like UV light or cosmic rays) or extreme heat strips electrons from neutral atoms or molecules, turning them into charged particles. This ultimately is what makes nebulae visible and is fundamental to understanding stellar life cycles and galactic structure.

For more than 30 years, astronomers have struggled to explain why specific wavelengths of light known as helium spectral lines are faint or missing in the diffuse ionized gas in the inner Milky Way, even though massive stars there produce more than enough high-energy radiation to ionize both hydrogen and helium.

鈥淭his has been a persistent mystery,鈥� says Pooja Priyatharsheni, second author of the study and a doctoral student at India鈥檚 Lady Doak College, whom Roshi connected with two years ago while promoting astronomy to collegiate students in India. 鈥淲e know the galaxy contains plenty of massive stars capable of ionizing helium, yet in many inner regions, we simply don鈥檛 see the helium signal we expect.鈥�

Cygnus X Provides a Clue 鈥� and a Challenge

The new detection in Cygnus X demonstrates that helium within the diffuse gas associated with this region is fully ionized.

鈥淭his result confirms that when the radiation field is strong enough, helium becomes fully ionized and visible in radio observations,鈥� Priyatharsheni explains. 鈥淏ut it also raises new questions about why the same doesn鈥檛 occur in the inner galaxy.鈥�

What鈥檚 Next

Led by Roshi of the , researchers from the Green Bank Observatory, the National Radio Astronomy Observatory, West Virginia University and Lady Doak College are now analyzing new high-sensitivity data from the Green Bank Telescope targeting the inner galaxy.

Their goal: to determine whether unusual 聽radiation sources, interstellar dust absorption, or unknown processes might explain the missing helium emission in the inner galaxy.

Their findings will better inform other astrophysicists and aerospace scientists about the energy flow through the interstellar medium and physical conditions of the galaxy, allowing them to refine their research and observational strategies.

They hope to retrieve most of the data for 聽their next findings by the end of 2026.

麻豆原创鈥檚 expertise will help drive the success of DUSTER, a payload designed specifically to capture and measure dust behavior during spacecraft and human operations on the moon. Lunar Outpost鈥檚 Mobile Autonomous Prospecting Platform (MAPP) rover will support NASA鈥檚 DUSTER (Dust and plaSma environmenT survEyoR) investigation, selected for development through the Artemis IV Deployed Instruments program. The instruments will be built at the Laboratory for Atmospheric and Space Physics (LASP) at CU Boulder.

DUSTER represents the best opportunity to date to evaluate the theory on the physics of dust erosion, with implications for the activities being planned on the moon鈥檚 surface. The Artemis IV mission is due to launch in 2028.

Testing Rocket Exhaust and Dust Erosion

This theory introduces a fundamentally new understanding of the behavior of gas in the boundary layer, the thin region where rocket exhaust meets the moon鈥檚 surface. This new physics shows how the gas flow in that layer lifts dust grains 鈥攕omething no previous model could adequately explain. Before this breakthrough, NASA lacked a method to reliably predict how much lunar dust erosion a landing or departing spacecraft would generate, and therefore could not fully estimate how much sandblasting damage would occur to hardware on the moon.

However, several key parameters in this new model cannot be measured accurately using existing lunar data or Earth-based experiments. On Earth, large-scale testing is limited: rocket exhaust cannot be blasted into a vacuum chamber without destroying the vacuum, and gravity cannot be reduced to lunar levels for the necessary full-scale trials.

DUSTER will change that. By collecting data during actual Starship Human Landing System operations on the moon, DUSTER will allow scientists to measure these long-elusive parameters directly in the lunar environment 鈥� providing the highest-fidelity test yet of Metzger鈥檚 theory.

鈥淥ne of DUSTER鈥檚 capabilities is measuring the dust blown by rocket exhaust as the Starship Human Landing System lifts off and departs from the moon,鈥� Metzger says.

In this project, University of Colorado Boulder Laboratory for Atmospheric and Space Physics senior researcher Xu Wang, who serves as principal investigator, will analyze upstream plasma conditions. 麻豆原创 will interpret measurements of dust ejected during the Human Landing System liftoff.

鈥溌槎乖� brings to this project its expertise in the science of how rocket exhaust blows soil and dust.鈥� 鈥� Phil Metzger 鈥�00MS 鈥�05PhD, 麻豆原创 planetary scientist

鈥溌槎乖� brings to this project its expertise in the science of how rocket exhaust blows soil and dust,鈥� says Metzger.

The findings generated by DUSTER will directly inform NASA鈥檚 long-term plans for sustained lunar operations, providing critical insights to protect habitats, instruments, and other assets as human presence on the moon grows. As NASA plans to deliver major infrastructure to the lunar surface, Artemis IV presents a new opportunity to address this outstanding engineering challenge of lunar exploration.

In a new study published in The Planetary Science Journal, researchers from 麻豆原创, NASA鈥檚 Jet Propulsion Lab (JPL) and other institutions explored a unique, spider-like feature in Manann谩n Crater on Europa, one of Jupiter鈥檚 icy moons.

First observed by NASA鈥檚 Galileo spacecraft, the feature may have formed from briny water eruptions beneath the ice, offering clues about subsurface liquid water and potential habitability on Europa.

“Europa is a fascinating moon to study because its subsurface ocean may have the conditions to support life.” 鈥� Lauren Mc Keown, assistant professor at 麻豆原创

鈥淏y understanding surface expressions, we can learn more about processes and conditions where liquid water may exist below the surface,鈥� says Lauren Mc Keown, assistant professor at 麻豆原创鈥檚 .

Using Earth鈥檚 lake stars as analogs, combined with field observations, lab experiments and modeling, the researchers hope to gain valuable insights into how these icy features form, which could have implications for future missions that might land on Europa and other icy airless worlds.

Originally from Ireland, Mc Keown鈥檚 interest in space began as a teenager when she first learned about the Cassini spacecraft, which explored Enceladus, a small icy moon of Saturn.

鈥淚 was fascinated by the animations showing a water plume shooting miles above the moon鈥檚 surface and the possibility that liquid water, or even an ocean, might exist there,鈥� she says. 鈥淚t encouraged me to explore NASA鈥檚 website to learn more about icy planetary surfaces and eventually pursue a career in planetary science at Trinity College Dublin.鈥�

As an icy planetary geomorphologist, Mc Keown studies surface features and processes on icy planets, moons and small bodies.

鈥淢y research includes analyzing Martian 鈥榮piders,鈥� which are dendritic 鈥� branching, tree-like 鈥� features that form in the regolith near Mars鈥� south pole,鈥� she says. 鈥淣ow, I鈥檓 applying that knowledge to other planetary surfaces, including Europa.鈥�

While Martian spiders form when dust and sand are eroded by escaping gas below a seasonal dry ice layer, Mc Keown believes Europa鈥檚 鈥渁sterisk-shaped鈥� feature may have formed after impact, when liquid brine within the icy shell extruded through broken-up ice from impact to form a pattern similar to Earth鈥檚 lake stars.

鈥淟ake stars are radial, branching patterns that form when snow falls on frozen lakes, and the weight of the snow creates holes in the ice, allowing water to flow through the snow, melting it and spreading in a way that is energetically favorable,鈥� she says.

Dendritic patterns like these are common in nature, appearing in Lichtenberg figures created by lightning strikes, in beach rilles where tides flow through sand, and in many other systems where fluid flows through porous surfaces.

鈥淚鈥檓 fascinated by these beautiful features on Earth, and there is very little research on how lake stars are formed鈥�, Mc Keown says. 鈥淭his inspired my team to explore whether similar processes could explain the pattern on Europa, albeit under different pressure and temperature conditions.鈥�

In the study, researchers proposed a new explanation for the feature, informally naming it Damh谩n Alla, Irish for 鈥渟pider,鈥� to distinguish it from Martian spider formations. They suggest it may have formed in a way similar to lake stars on frozen Earth lakes, under locally temporary elevated temperatures and pressures caused by an impact that created Europa鈥檚 Manann谩n crater.

鈥淟ake stars on Earth are star-shaped or branched melt patterns that form when warmer water rises through thin ice and spreads through overlying slush or snow before freezing,鈥� Mc Keown says. 鈥淥n Europa, we believe a subsurface brine reservoir could have erupted and spread through porous surface ice, producing a similar pattern.鈥�

To test this hypothesis, Mc Keown and colleagues conducted field and lab experiments, observing lake stars in Breckenridge, Colorado, and recreating the process in a cryogenic glovebox at JPL, using Europa ice simulants cooled with liquid nitrogen.

鈥淲e flowed water through these simulants under different temperatures and found that similar star-like patterns formed even under extremely cold temperatures (-100掳C), supporting the idea that the same mechanism could occur on Europa after impact,鈥� Mc Keown says.

Elodie Lesage, a research scientist at the Planetary Science Institute and co-author of the study, modeled how a brine pool might behave beneath Europa鈥檚 surface after this impact, and the team created an animation illustrating the process.

Observations of Europa鈥檚 icy features have been limited to images from the Galileo spacecraft.

Mc Keown鈥檚 team hopes to resolve this question with higher-resolution imagery from the Europa Clipper mission, a NASA spacecraft scheduled to arrive at the Jupiter system in April 2030.

鈥淭he significance of our research is really exciting,鈥� Mc Keown says. 鈥淪urface features like these can tell us a lot about what鈥檚 happening beneath the ice. If we see more of them with Europa Clipper, they could point to local brine pools below the surface.鈥�

The findings provide insights for possible patterns on Europa; however, researchers caution against relying solely on Earth analogs to understand other planetary surfaces.

鈥淲hile lake stars have provided valuable insight, Earth鈥檚 conditions are very different from Europa鈥檚,鈥� Mc Keown says. 鈥淓arth has a nitrogen-rich atmosphere, while Europa鈥檚 environment is extremely low in pressure and temperature. In this study, we combined field observations with lab experiments to better simulate Europa鈥檚 surface conditions.鈥�

Mc Keown is also proud of the collaborative nature of the work.

鈥淭his study came together organically and reflects a value that鈥檚 important to me: community,鈥� she says. 鈥淚鈥檝e had the opportunity to work with an incredible group of scientists 鈥� including JPL Planetary Geologist Jennifer Scully, with whom I collaborated to name the feature 鈥� whose multidisciplinary expertise was essential to this research. There are not many Irish planetary scientists, so working together has been rewarding, particularly because many of Europa鈥檚 features have Irish and Celtic names.鈥�

Looking ahead, Mc Keown plans to investigate how low pressure affects the formation of these features and whether they could form beneath an icy crust, similar to how lava flows on Earth to create smooth, ropy textures called pahoehoe.

鈥淚鈥檓 setting up a new lab at 麻豆原创, called the FROSTIE (Facility for Research Observing Simulated Topography of Icy Environments) Lab, where I鈥檓 designing a chamber specifically for these experiments. I am currently involving students to create icy simulants for this work while continuing to collaborate with JPL,鈥� she says.

Although geomorphology was the main focus of this study, the findings offer important clues about subsurface activity and habitability, which are crucial for future astrobiology research.

鈥淚鈥檝e spoken with astrobiologists interested in these patterns, including how microbes might inhabit lakes on Earth,鈥� Mc Keown says. 鈥淭here鈥檚 great potential for collaboration across disciplines with this research, and I look forward to connecting with colleagues and students at 麻豆原创 who are as passionate and excited about this work as I am.鈥�

Lunar dust particles are sharp and abrasive due to the lack of atmosphere gradually dulling their surfaces, leading them to potentially damaging critical lunar equipment or causing respiratory issues for astronauts. Managing lunar dust (also known as regolith) and safeguarding astronauts or sensitive equipment on the moon isn鈥檛 as simple as sweeping it up with a broom and pan.

That鈥檚 why a team of NASA-funded 麻豆原创 researchers is pioneering a new nanocoating to passively mitigate the effects of lunar dust, protect equipment and ultimately extend future lunar missions.

鈥淭he dust particles on the moon are very sharp, very sticky and very toxic,鈥� says Lei Zhai, director of the NanoScience Technology Center and project lead. 鈥淩ight now, the efforts we have seen are based on studies here on Earth, and so we want to have a more complete picture of the interactions and guide the design on how to mitigate dust using a simulated lunar environment.鈥�

麻豆原创鈥檚 research team aims to conduct testing as true to a lunar environment as possible through modeling and the use of a simulated regolith in a vacuum chamber to mimic lunar conditions and exclude the effects of Earth鈥檚 atmosphere. The goal is to understand how lunar dust interacts with surfaces and which surface properties, such as surface structures, polarity and electrical conductivity, are key to repelling the dust, even in complex lunar charged particle and light radiation environments.

鈥淚t鈥檚 a really new, novel way to approach this. Lunar dust is one of the most significant problems that we have for going to the moon, especially for long duration stays.” 鈥� Adrienne Dove, professor of physics

鈥淲e鈥檒l put our engineered coatings or surfaces into the vacuum chamber with lunar simulants and study how the dust interacts with the surfaces in the simulated lunar surface environment,鈥� Zhai says. 鈥淭here is also strong irradiation on the moon, so we will also introduce irradiation sources in the setup. We also will use a specific instrument called an atomic force microscope to study these specific interactions at the dust particle level.鈥�

Repeated experimentation will allow Zhai and his team to adjust surface structure, hardness, conductivity and other properties to further fine tune the surface coatings.

鈥淲ith that data, we can design specific surface structures for effective dust mitigation,鈥� he says. 鈥淢y role is to provide the surface. Then I鈥檒l give this surface to Dr. [Laurene] Tetard who will carry out the atomic force microscope studies and also Dr. [Adrienne] Dove who has a vacuum chamber and irradiation sources.鈥�

Dove, who is a professor of physics and the department chair, says she鈥檚 excited to work on this project.

鈥淚t鈥檚 a really new, novel way to approach this,鈥� she says. 鈥淟unar dust is one of the most significant problems that we have for going to the moon, especially for long duration stays. So, it鈥檚 really exciting to be working on this, and to be doing this as an applied way to look at lunar dust problems.鈥�

Dove has been studying lunar dust physics for many years, and this project extends her existing knowledge and outcomes to how they may directly affect exploration. For this project, she studies how the dust particles interact with the new coatings during the experiments in the vacuum chamber to better inform the prototype coatings Zhai will develop.

鈥淎 lot of the work I do is to implement different ways to measure the sticking forces of dust grains and other materials,鈥� Dove says. 鈥淪o, one way to do that is to put a lot of dust on a surface and then to spin the surface really fast with a centrifuge and see at what speed the grains come off 鈥� we use that to measure the force.鈥�

The research team hopes that their new understandings of lunar dust can inform more efficient ways to reduce the dust鈥檚 harmful interactions with surfaces by minimizing efforts to physically remove the dust and instead use passive methods such as relying on solar wind or radiation.

鈥淲hen astronauts are hopping around the surface or rovers are driving around, they鈥檙e going to stir up dust, and that dust naturally gets all over the place,鈥� she says. 鈥淲e think of it like when we get sand on us at the beach, you can mostly just wipe it off. Sometimes you get a little scratched, though. That same thing can happen with lunar dust, but it鈥檚 much worse than beach sand 鈥� much harder to get clean and its scratchier.鈥�

The researchers are opting to explore passive methods to mitigate the dust to avoid potentially scratching technologies such as sensors or cameras by wiping away dust. Passive dust mitigation may rely on solar wind, radiation or other passive forces distinct from an active approach such as applying an electric field to remove the dust.

鈥淭his project is really focusing on passive ways to change the surface so that dust just doesn’t stick as well in the first place,鈥� Dove says. 鈥淪o, if we do things like shake it off or blow some air on it the dust comes off more easily.鈥�

The idea for the project progressed as the team continually discussed dust and surface interactions over the years.

Laurene Tetard, a professor of physics, specializes in atomic force microscopy. Atomic force microscopes (AFM) are powerful enough to examine challenges at the nanoscale, and they are critical to further understanding the dust experiments in the vacuum chamber and the effectiveness of the surfaces engineered by Zhai.

鈥淲e are hoping to develop a new platform that links nanoscience and space research in a new way.鈥� 鈥擫aurene Tetard, professor of physics

鈥淲e are hoping to develop a new platform that links nanoscience and space research in a new way,鈥� Tetard says. 鈥淲e will design a platform that can perform these measurements under conditions that mimic space conditions. The information obtained from these measurements will provide important feedback to optimize the engineered surface.鈥�

She says expanding the frontiers of AFM to space research is particularly unique, and that the future opportunities to build on this research are equally gratifying.

鈥淚t will be great to train students in this new direction for future applications of interest of NASA and other space-related industries,鈥� Tetard says. 鈥淎nd it鈥檚 especially exciting to do that with experts in these fields who know a lot about the complementary aspects of this work.鈥�

Tarek Elgohary, associate professor of mechanical and aerospace engineering, is collaborating with other team members to create simulations that will help them understand how the particles interact with each other and with different surfaces.

鈥淲e鈥檝e got particle-to-particle and particle to surface interactions,鈥� he says. 鈥淲e want to simulate those on the computers and then match what we know from the experiments, such as the physical properties, with what we get from the simulation. So essentially, we鈥檙e trying to close the loop between simulations and experiments to better understand the physical phenomenon.鈥�

Understanding how electrical charges may move amongst dust particles and how the dust maintains charges or discharges through simulated environments is an important aspect of the research component that Elgohary is studying.

鈥淭hat will essentially help us with the design process of the passive mitigation techniques that Lei, Addie and Laurene are looking into,鈥� he says.

The interdisciplinary nature of the project and the longstanding desire to tackle the elusive challenge of lunar dust are some of what Elgohary says are most rewarding aspects of the research process.

鈥淚 started talking to Addie many years ago, and we have had several efforts to try to understand how the dust moves and interacts,鈥� he says. 鈥淚t鈥檚 a fascinating problem, and it requires understanding the physics and connecting that to an engineering application to allow us to have a greater presence on the lunar surface. The fact that there are four of us covering each piece of this problem is one of the of the most exciting things about this project.鈥�

Researchers鈥� Credentials:

Dove received her doctorate in astrophysical and planetary sciences from the University of Colorado at Boulder and her bachelor鈥檚 degree in physics and astronomy from the University of Missouri. She joined 麻豆原创鈥檚 Department of Physics in 2012. In 2017, Dove was awarded the Susan Niebur Early Career Award by the NASA Solar System Exploration Virtual Research Institute for her contributions to the science and exploration communities. She is the deputy-principal investigator of the Lunar-VISE mission to the moon鈥檚 Gruithuisen Domes to examine lunar rocks and regolith, slated to launch in 2027.

Elgohary joined 麻豆原创 in 2016 as an assistant professor. He manages the Astrodynamics, Space and Robotics Laboratory in the Department of Mechanical and Aerospace Engineering. He earned a bachelor鈥檚 degree in mechanical engineering from the American University in Cairo and a master鈥檚 degree and doctoral degree in aerospace engineering from Texas A&M University. Elgohary鈥檚 research interests are developing analytical & computational techniques for multi-body dynamics problems, astrodynamics, space domain awareness and space flight guidance, navigation, and control problems. His research has been funded by the U.S. Air Force Office of Scientific Research, the Federal Aviation Administration, NASA, Lockheed Martin and the U.S. Space Force.

Tetard received her doctorate in physics from the University of Tennessee, Knoxville and joined 麻豆原创鈥檚 NanoScience Technology Center and Department of Physics in 2013. She is a U.S. National Science Foundation Faculty Early Career Development Program awardee and Moore Experimental Physics Investigator awardee. Her team’s research focuses on developments of Scanning Probe Microscopy to study complex systems with applications in life sciences, materials, energy, catalysis and more.

Zhai is a 麻豆原创 professor who received his doctorate in chemistry from Carnegie Mellon University. He joined 麻豆原创鈥檚 NanoScience Technology Center and Department of Chemistry in 2005. Zhai is a Scialog Fellow at Research Corporation for Science Advancement and received an NSF CAREER award in 2008. He was the faculty advisor of a 麻豆原创 team that won the Breakthrough, Innovative and Game-Changing Idea Challenge in 2021.

The material is based upon work supported by NASA ESI Program Award 80NSSC25K7282. Any opinions, findings, conclusions or recommendations expressed in this material are those of the principal investigators and do not necessarily reflect the views of NASA.

Using the James Webb Space Telescope (JWST), scientists analyzed far-away bodies 鈥� known as Trans-Neptunian Objects (TNOs) 鈥� and found varying traces of methanol. The discoveries are helping them better classify different TNOs and understand the complex chemical reactions in space that may relate to the formation of our solar system and the origin of life.

The findings, recently published in by the American Astronomical Society, reveal two distinct groups of TNOs with surface ice methanol presence: one with a depleted amount of surface methanol and a large reservoir beneath the surface, and another 鈥� furthest from the Sun 鈥� with an overall weaker methanol presence. The study suggests that cosmic irradiation over billions of years may have played a role in the first group鈥檚 varying methanol distribution, while raising new questions about the second group鈥檚 muted signatures.

Reaching Back in Time and Space

TNOs are important to our understanding of our solar system鈥檚 origins because they are incredibly well-preserved remnants of the protoplanetary disk 鈥� or disk of gas and dust surrounding a young star such as the Sun 鈥� and can give scientists a thorough glimpse into the past.

麻豆原创 Department of Physics Research Professor Noem铆 Pinilla-Alonso, who now works at the University of Oviedo in Spain, co-led the research as part of the 麻豆原创-led Discovering the Surface Compositions of Trans-Neptunian Objects (DiSCo) program which includes Associate Professor Ana Carolina de Souza-Feliciano.

Pinilla-Alonso says the research helps piece together the history of the solar system鈥檚 chemistry and gain insights into exoplanets, where methanol and methane play a crucial role in shaping atmospheres and hinting at the conditions of potentially habitable worlds.

鈥淢ethanol, a simple alcohol, has been found on comets and distant TNOs, hinting that it may be a primitive ingredient inherited from the early days of our solar system 鈥� or even from interstellar space,鈥� Pinilla-Alonso says. 鈥淏ut methanol is more than just a leftover from the past. When exposed to radiation, it transforms into new compounds, acting as a chemical time capsule that reveals how these icy worlds have evolved over billions of years.鈥�

Methanol ice is a key precursor that may lead to organic molecules such as sugars, and its discovery in TNOs paves the way for so much more, she says.

These spectral differences reveal that not all TNOs formed from the same molecular ingredients, Pinilla-Alonso says. Instead, their compositions reflect their origins 鈥� where and how they formed 鈥� and their transformations over time.

鈥淲hat excited me the most was realizing that these differences were linked to the behavior of methanol 鈥� a key ingredient that had long been elusive on TNOs from earth-based observations,鈥� she says. 鈥淥ur findings suggest that methanol is being destroyed on the surface of TNOs by irradiation, but remains more abundant in the subsurface, protected from this exposure.鈥�

Pinilla-Alonso worked alongside 麻豆原创 FSI researchers, including de Souza-Feliciano, who synthesized the laboratory data with modeling to better explain the behavior of methanol.

De Souza-Feliciano helped to better visualize the findings by reproducing some of the spectral features the scientists were seeing and could provide mathematical support for the data in the study.

鈥淥ne of the biggest surprises came from the methanol behavior,鈥� de Souza-Feliciano says. 鈥淔rom laboratory data, its signatures at shorter wavelengths differ from the fundamental ones in longer wavelengths.鈥�

De Souza-Feliciano collaborated on prior DiSCo research projects using JWST that characterized binary objects and other distant TNOs.

鈥淭he main DiSCo paper addressed the main characteristics of the three groups of TNOs,鈥� she says. 鈥淭his paper goes into detail about one of them, known as the cliff group, which is the nickname for the spectral group where the reflectance did not increase after approximately 3.3 microns.鈥�

Not only are these cliff group TNOs time capsules for our solar system, but the group houses cold-classical TNOs which have largely stayed in place since their formation, de Souza-Feliciano says.

鈥淥ne of the reasons why this group is a key for the outer solar system understanding is [because] it contains all the cold-classical TNOs,鈥� she says. 鈥淭he cold-classical TNOs are the only dynamic group that probably stayed in the place where they formed from the formation of the solar system to today.鈥�

International Collaboration

Rosario Brunetto, an astronomer at the Universit茅 Paris-Saclay, led the research with fellow scientists Elsa聽H茅nault and Sasha聽Cryan.

He says he believes this collaborative discovery will provide foundational knowledge of our solar system and ignite interest in planetary science.

鈥淭his discovery not only reshapes our understanding of TNOs but also provides a crucial reference for interpreting JWST鈥檚 observations of other distant objects, such as Neptune Trojans, Centaurs and asteroids, as well as for future missions exploring the outer solar system,鈥� Brunetto says. 鈥淏eyond its scientific significance, the search for methanol in the solar system also fuels curiosity and inspires new generations to explore the cosmos and understand the chemical evolutions in space.鈥�

麻豆原创 FSI Assistant Scientist Charles Schambeau and 麻豆原创 physics graduate student Brittany Harvison also contributed to the research.

The findings were made possible through an international collaboration with researchers from Northern Arizona University, the Laboratoire de G茅ologie de Lyon in France, NASA鈥檚 Space Telescope Science Institute, the Max-Planck-Institut f眉r extraterrestrische Physik in Germany, the Lowell Observatory, the Universidade de Coimbra in Portugal, INAF-Osservatorio Astrofisico di Catania in Italy, the University of Canterbury in New Zealand, the Instituto de Astrof铆sica de Canarias in Spain, the Universidad de La Laguna in Spain, Fundaci贸n Galileo Galilei-INAF in Spain and Observat贸rio Nacional do Rio de Janeiro in Brazil.

Researchers鈥� Credentials:

De Souza-Feliciano is an associate professor at FSI. She received a doctoral degree in astronomy from Observat贸rio Nacional de Rio de Janeiro, Brazil. Her main scientific interest is the characterization of the surface properties of small bodies in the solar system through an observational perspective. She鈥檚 been deeply involved in the study of the surface composition of TNOS to better understand the variety of the entire population using both ground-based and space-based facilities. Because of this, de Souza-Felicano is involved in several projects using the JWST.

Pinilla-Alonso is a former FSI professor who joined 麻豆原创 in 2015. Most of her work on this project was conducted while she was at 麻豆原创. Pinilla-Alonso also holds a joint appointment as a research professor in 麻豆原创鈥檚聽,聽and has led numerous international observational campaigns supporting NASA missions such as New Horizons, OSIRIS-REx and Lucy. Pinilla-Alonso is a distinguished researcher at the Institute for Space Sciences and Technologies in Asturias, within the Universidad de Oviedo. She received a doctoral degree in astrophysics and planetary sciences from the Universidad de La Laguna in Spain.

This strategic collaboration combines Operator Solutions鈥� hands-on operational expertise with 麻豆原创鈥檚 academic and research excellence to develop cutting-edge training programs, pioneer medical research and enhance real-world response capabilities in high-risk environments.

Key Initiatives of the Partnership

The collaboration will drive multiple initiatives aimed at improving medical preparedness in spaceflight and extreme environments.

• Developing Medical Training Modules for Commercial Spaceflight

Operator Solutions and 麻豆原创 will provide specialized training for physicians, paramedics, flight nurses, medical students and resident physicians. The focus will be on triage procedures, in-flight patient care using helicopters and managing mass casualty incidents at sea. Operator Solutions is also developing a medical skills lab at 麻豆原创, where paramedics can master critical techniques such as wound care, fluid resuscitation and stabilization under high-stress conditions. Additionally, trainees will gain hands-on experience in the College of Medicine鈥檚 Anatomy Lab, learning life-saving procedures like chest tube insertion and evisceration treatment.

• Enhancing In-flight Medical Care for Space Travelers

With the number of space travelers increasing and missions lasting longer, Operator Solutions and 麻豆原创 aim to develop new technologies to improve point-of-care medical treatment in space. Their research will focus on ultrasound and telemedicine systems for treating conditions such as kidney stones and blood clots, as well as real-time health monitoring solutions for astronauts 鈥� critical for long-duration missions, including those planned for Mars.

Advancing the Future of Aerospace Medicine

As America鈥檚 Space University, 麻豆原创 is the ideal academic partner for this endeavor. The university was founded to provide talent to fuel the nation鈥檚 space program and today is a national leader in many areas of space research, including developing new technologies for space missions and advancing the health and well-being of space travelers.

This partnership strengthens an unrivaled opportunity for 麻豆原创 students to prepare for careers in this rapidly growing field. 麻豆原创 is creating a new space medicine curriculum that will involve students from many disciplines, including medicine, nursing, engineering, computer science, optics and photonics 鈥� and establishing what will be the nation鈥檚 first master鈥檚 degree in space medicine.

Located in Melbourne, Florida, Operator Solutions combines decades of military, spaceflight and medical expertise to offer operational, rescue and recovery services to government and private companies. Its pararescuers are qualified to offer paramedic-level care anywhere in the world, including parachuting into remote rescue sites. The company specializes in open-ocean rescue of boaters and astronauts and helped develop procedures for astronaut rescue and retrieval for the commercial space program. Its workforce is 100% military veterans.

鈥淭his partnership represents a significant leap forward in aerospace medical training,鈥� says Christopher Lais of Operator Solutions. 鈥淏y combining our hands-on operational expertise with 麻豆原创鈥檚 world-class academic research, we are creating a framework that will shape the future of spaceflight medical preparedness and emergency response.鈥�

Emmanuel Urquieta, vice chair of at 麻豆原创鈥檚 College of Medicine, emphasized the growing importance of aerospace medical training.

鈥淎s commercial space travel expands, ensuring that astronauts, spaceflight crews and emergency responders are equipped with essential medical knowledge and skills is critical,鈥� Urquieta says. 鈥淭his collaboration will push the boundaries of medical science and training, helping us ensure safety and preparedness in extreme environments.鈥�

Urquieta is one of the world鈥檚 foremost leaders in space medicine. He came to 麻豆原创 after serving as chief medical officer of the NASA-funded Translational Institute for Space Health led by the Baylor College of Medicine. His goal is to make 麻豆原创 a model of interdisciplinary medical research focused on improving the health of space travelers and also those on Earth.

Setting the Standard for Space Mission Readiness

By leveraging their combined expertise, Operator Solutions and 麻豆原创鈥檚 College of Medicine are establishing new benchmarks in medical education, research and operational readiness for both spaceflight and emergency response. This partnership is poised to transform aerospace medicine, delivering life-saving solutions for the next generation of space missions.