Axiom received a nearly $230 million task order to develop the AxEMU suit, which Artemis astronauts will test out on the lunar surface. The task order is part of a contract with NASA worth up to $3.5 billion that also includes Collins Aerospace, which earlier this year abandoned efforts to develop extravehicular activity (EVA) spacesuits under its own $100 million task order.

NASA’s current EVA suits are more than four decades old, and recent malfunctions have forced the space agency to postpone several spacewalks.

“We have broken the mold,” said Matt Ondler, president of Axiom Space. “The Axiom Space-Prada partnership has set a new foundational model for cross-industry collaboration, further expanding what’s possible in commercial space.”

Artemis III will land a crew at the lunar south pole, so Axiom’s suit is designed to withstand extreme temperatures in regions devoid of sunlight. Its portable life support system will keep astronauts safe on spacewalks for up to eight hours, the company says.

Axiom says its design is more flexible, efficient, and safe than NASA’s existing suits. The AxEMU boots, for example, are built to withstand rough terrain and the freezing cold, while the helmet and visor covering are designed to improve astronauts’ vision of their surroundings. The suit can accommodate crew of nearly all body types.

Several AxEMU systems are redundant, including an onboard diagnostic system that tracks the wearer’s vital signs. Astronauts can control its temperature using a carbon dioxide scrubber and cooling system. A 4G/LTE communications system allows them to keep in touch with the rest of the crew during excursions.

The outer suit material, which was designed in partnership with Prada, will reflect heat and protect against small projectiles like dust.

“I’m very proud of the result we’re showing today, which is just the first step in a long-term collaboration with Axiom Space,” said Lorenzo Bertelli, chief marketing officer and head of corporate social responsibility for Prada Group. “We’ve shared our expertise on high-performance materials, features, and sewing techniques, and we learned a lot.”

According to Axiom, the suit will be designed for missions on the moon as well as in low-Earth orbit. That could be enticing for non-NASA customers that have different missions in mind.

The firm on Wednesday said the AxEMU suit is close to the final stage of development, with a critical design review expected next year. Already, it has endured underwater, reduced gravity, and pressurized simulation testing at NASA facilities. In the coming months, the space agency will perform crewed underwater testing at its Neutral Buoyancy Laboratory and gauge the suit’s fit with the prototype lunar rover the Artemis astronauts will drive.

Simultaneously, Axiom is developing the Axiom Station: one of several commercial space outposts that could replace the International Space Station (ISS) when NASA destroys it at the end of the decade. The firm has already completed three NASA-approved private astronaut missions to the ISS and is scheduled for a fourth in Spring 2025.

NASA’s largest commercial partner, SpaceX, meanwhile, has developed its own EVA spacesuit, which debuted during the first civilian spacewalk on September’s Polaris Dawn mission. The company claims it will one day manufacture thousands of suits for future astronauts to build and explore on Mars.

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The post NASA Astronauts Will Wear Prada for Artemis Moonwalk appeared first on FLYING Magazine.

The mission lifted off October 14 from Launch Complex 39A at NASA’s Kennedy Space Center in Florida at 12:06 p.m. EDT aboard a SpaceX Falcon Heavy rocket. Roughly an hour later, the spacecraft separated from its launch vehicle, embarking on a cruise through the inner solar system. A pair of gravity assists will ultimately slingshot it to Jupiter. The spacecraft will travel some 1.8 billion miles (2.9 billion kilometers) over the next 5½ years and reach the Jupiter system in 2030.

Europa Clipper’s launch was originally scheduled for October 10, but that was delayed by Hurricane Milton. The craft rode out the hurricane’s destructive trek across Florida the night of October 9-10 safely ensconced in a hangar. After a damage assessment and recovery team surveyed the damage, Kennedy Space Center was declared safe and open, with only minor damage.

Enigmatic Europa

One of Jupiter’s four Galilean moons, Europa has long fascinated scientists.

Some 90 percent the size of our own moon, the satellite is believed to host a global ocean of liquid saltwater twice the volume Earth’s oceans but locked beneath a water-ice crust some 2 to 20 miles (3 to 30 kilometers) thick. Not only that, the moon is heated through tidal flexing as it orbits Jupiter on an elliptical path, and also contains the chemical building blocks of life as we know it. 

• READ MORE:  NASA Awaits ‘All-Clear’ for Mission to Search for Life on Jupiter’s Moon

All these factors combine to create a compelling world where Earth-like life might find a way. In fact, when people think of the potentially habitable places within our solar system, Europa likely tops the list. 

“Europa Clipper is not specifically a life-search mission. [Instead], we’re going to understand the potential habitability of Europa,” said Europa Clipper project scientist Robert Pappalardo in a NASA video.

The mission will use nine instruments to study the moon’s interior and exterior, as well as the environment in which it sits, to learn about the ice shell and the ocean it hides, as well as the composition of the moon and whether it is geologically active.

A Dedicated Mission

Once it launches, Europa Clipper will complete a triad of Jupiter missions currently in action, joining NASA’s Juno, which has been orbiting Jupiter since July 2016, and ESA’s Jupiter Icy Moons Explorer (JUICE), which launched in April 2023 and is also on its way to the gas giant. In fact, Europa Clipper, currently scheduled to arrive at Jupiter in April 2030, will beat JUICE to its destination by about a year thanks to differing trajectories.

But why send Europa Clipper at all, if Juno is already in orbit and JUICE is on its way? 

Juno is dedicated to studying Jupiter itself, although it’s certainly sent back some stunning imagery of the moons as well. Additionally, Juno’s mission is coming to a close, planned to end in September 2025. And after JUICE arrives in 2031, it will complete just two flybys of Europa in July 2032, before move on to concentrate the bulk of its mission on Ganymede and Callisto. Like Europa, these larger moons also presumably host liquid subsurface oceans, though farther beneath their own icy crusts. 

“For the first time ever, we’re sending a spacecraft completely dedicated to studying this moon,” said Tracy Drain, Europa Clipper’s lead flight system systems engineer. 

Following its launch, Europa Clipper’s journey will take it past Mars (2025) and Earth (2026) for gravity assists before reaching the Jupiter system. Once there, it will use the Galilean moons to slow and shape its orbit, aiming to enter resonance with Europa’s orbit and make its first flyby of the eponymous moon in early 2031. Shortly after, in May that year, the craft will begin its science campaign, focusing first on the anti-Jupiter side of the moon (the side of Europa facing away from Jupiter). 

• READ MORE: NASA Reveals Messages to Be Carried to Jupiter on Europa Clipper Orbiter

A second science campaign, which will send the craft past the Jupiter-facing side of the moon, will begin in May 2033. In all, Europa Clipper will make 49 Europa flybys, each passing over different terrain as it builds up a nearly complete global map of the surface. At its closest, it will skim just 16 miles (25 km) above the surface.

Throughout these campaigns, the spacecraft will plunge into one of the worst environments imaginable, bathed by the intense radiation that surrounds Jupiter. The massive planet supports an extensive magnetosphere—the region of space where its magnetic field dominates. Charged particles from both the Sun and Jupiter itself, as well as from the highly volcanic moon Io, are trapped by the planet’s powerful magnetic field and generate huge, intense radiation belts—belts that encompass Io, Europa, and Ganymede, with the two innermost moons orbiting in the worst of it. 

While there is no avoiding this environment if one wants to study Europa—and indeed, scientists think this unique environment has actively shaped Europa into the world we see today—the mission is taking precautions. First, the spacecraft will orbit Jupiter rather than Europa, meaning it will fly through—but not continually sit within—the worst of the radiation. Nonetheless, according to NASA, during each flyby, Europa Clipper will experience a dose of radiation equivalent to 1 million chest X-rays.

That’s why Europa Clipper is also taking a design note from Juno: The craft’s computer and sensitive electronics are locked within a sealed central vault, whose aluminum-zinc walls are some one-third inch (9.2 millimeters) thick. These walls will keep out enough of the punishing, fast-moving particle radiation to ensure the electronics within experience only “acceptable” levels of radiation and can function throughout the mission duration, according to NASA. 

In May, however, engineers brought up concerns regarding the spacecraft’s transistors and their ability to withstand the high-radiation environment they were traveling to. It appeared that the parts might be less resistant to radiation than expected, and some would fail prematurely. However, additional testing ultimately bore out that the transistors would support the intended mission duration. 

Additional Specs

Europa Clipper is the largest NASA spacecraft ever built for a planetary mission. It weighs some 13,000 pounds (5,900 kilograms) and, with its two wide, winglike solar arrays extended, spans more than 100 feet (30.5 meters)—roughly the length of a basketball court.

The mission carries visible-light and infrared cameras, as well as ultraviolet and infrared spectrometers to measure composition. Its magnetometer and plasma instrument will measure the moon’s magnetic field (generated by its motion through Jupiter’s changing magnetic field). These observations will confirm the presence of a subsurface ocean, as well as measure its salinity, depth, and even the thickness of the ice shell above it. A radar instrument will also help map the surface, determine the thickness of the icy crust, and even pick up subsurface liquid to confirm the presence and depth of the ocean.

Gravity science experiments will allow astronomers to evaluate how Europa Clipper’s flight path changes as it is influenced by the moon’s gravitational environment, which changes as it orbits Jupiter. This will, in turn, reveal how much the moon’s shape changes due to tidal forces—a factor inherently tied to its internal structure. 

Finally, the craft’s mass spectrometer and surface dust analyzer will explore the environment around the moon. In particular, they will analyze material vented by geysers, as well as surface ice particles knocked into space by micrometeorites. By studying the chemistry of Europa’s surface ice and subsurface water directly, scientists will be able to determine whether its ocean could indeed be hospitable to life. 

Answers Ahead

“All these worlds are yours—except Europa. Attempt no landing there,” reads the radio message beamed to Earth at the end of Arthur C. Clarke’s novel 2010: Odyssey Two.

Although fueled by the presence of fictitious plantlike creatures beneath Europa’s surface, the sentiment behind the message rings true in real life. After a little less than a year and a half of science, Europa Clipper will end its mission in September 2034 with a “deorbit” into its fellow Galilean moon, Ganymede. 

But Ganymede, like Europa, also harbors a subsurface ocean. So, why is it being targeted for the crash?

According to the ESA, whose JUICE mission will also end by impacting Ganymede: “Icy moon Europa is the only object that is considered to have the potential for harboring life, and that therefore needs to be protected.…But as it stands, planetary protection rules allow a crash onto Ganymede, because there are no indications that the deep subsurface ocean on Ganymede can be in contact with the icy surface. Crashing into Europa would not be allowed because Europa’s subsurface oceans are suspected to be less deep and therefore contamination from the surface to the ocean would in theory be possible.”

Despite the mission’s brevity, Europa Clipper has the potential to unlock one of the most mysterious and enticing worlds in our solar system. And it will certainly bring us one step—or perhaps several steps—closer to answering the question of whether Earth is the only solar system world hospitable to life.

“This mission has been a long time coming, and we’re so excited about what we’re going to see when we get there,” said Pappalardo.

This story was updated October 15 to include information about Europa Clipper’s launch and the status of recovery efforts at Kennedy Space Center.

Editor’s Note: This article first appeared on Astronomy.

The post NASA’s Europa Clipper Sets Sail for Jupiter appeared first on FLYING Magazine.

But Isaacman—now a SpaceX “frequent flier” after also taking part in 2021’s Inspiration4 mission, the first all-civilian spaceflight—is just getting started.

“If we actually believe in the future that SpaceX is trying to create—where tens of thousands of people can be in space, on the moon, walking around on Mars—these kinds of capabilities have to exist within commercial industry,” Isaacman told FLYING at the 2024 UP.Summit.

Polaris Dawn was the first of three missions under Isaacman’s Polaris Program. The final mission, which does not yet have a target date, is expected to be the first crewed flight of SpaceX’s Starship: the most powerful rocket ever built and the vehicle CEO Elon Musk believes will help humans colonize Mars.

Isaacman and crewmates Sarah Gillis and Anna Menon, the first SpaceX employees to actually fly to space, sat down with FLYING for a mission debrief to highlight their favorite moments from Polaris Dawn—and talk about what comes next.

No Days Off

From the moment they lifted off from Launch Complex 39A at NASA’s Kennedy Space Center in Florida, secured in a SpaceX Dragon capsule strapped to a Falcon 9 rocket, the Polaris Dawn crew got to work.

On the first day of the mission, for example, the crew reached an orbital apogee of 870 miles—three times higher than the International Space Station and the farthest humans have traveled from Earth since the Apollo era. Gillis and Menon now share the record for the furthest distance traveled from Earth by a woman.

At that altitude, the crew passed through the Van Allen radiation belts, a treacherous environment for humans. It conducted research that will help scientists better understand how to protect astronauts flying through that region.

“There’s micrometeoroid and debris that’s out there. A little millimeter piece of aluminum traveling at 8 kilometers a second will shred just about everything,” Isaacman said during a panel discussion at UP.Summit. “It’s a scary prospect. But we’ve got to travel through that if we’re going to get to the moon and Mars.”

Isaacman’s favorite moment of the mission, however, was the spacewalk he and Gillis performed. It was the first time civilian astronauts ventured outside a spacecraft. And because the Dragon capsule lacks an airlock, it was also the first time four astronauts were simultaneously exposed to the vacuum of space.

“That moment when Jared opened the hatch and there was the black beauty of space outside the hatch was a moment full of sensation, full of the awe that that evoked, as well as a cold rushing over your body,” Menon said. “It’s a full body experience.”

Traveling at 17,500 mph at an orbital altitude north of 450 miles, the astronauts were protected by SpaceX’s extravehicular activity (EVA) spacesuits, which were specially designed for Polaris Dawn. The goal of the spacewalk was to perform mobility testing on the suits—a relatively simple objective compared to previous EVAs.

“The difference is—and this is so important—is all of those had the entire weight and resources of world superpowers behind them,” Isaacman said.

NASA’s budget peaked in the 1960s, when it was about 4.5 percent of the U.S. gross domestic product (GDP).

For Gillis, a classically trained violinist, the highlight was her on-orbit performance of “Rey’s Theme” from the Star Wars franchise. Incredibly, Gillis said she had no prior practice playing in microgravity, where pushing on the violin’s fingerboard can move the entire instrument. She used a quarter-sized bow for greater control.

“It was three crewmembers in front of me with this tangle of cables, and the chaos of them trying to get the right angle as they’re floating away, and I’m floating away,” Gillis said. “It was just this total joy to try and record that.”

The performance, organized in partnership with St. Jude Children’s Research Hospital and El Sistema USA, was a charitable effort to raise awareness and funding for cancer research and access to music education. But it was also a demonstration of SpaceX’s Starlink communications system. A Starlink module on Dragon used a beam of light to transmit the footage to another satellite while both were moving at orbital speeds.

How They Did It

Polaris Dawn was a private astronaut mission, meaning SpaceX was responsible for preparing the crew. Scott “Kidd” Poteet, the fourth crewmember and a retired U.S. Air Force fighter pilot of two decades, said the training was more intense than anything he has ever experienced.

Gillis, a SpaceX astronaut trainer, said that while the crewmembers brought plenty of experience, combining their strengths was a learning curve. Early on, for example, they struggled through teamwork exercises in a simulator.

“We might have all of this expertise across the four of us, but we utterly failed that sim,” Gillis said. “Just because you have your own expertise doesn’t mean you are yet able to work in a team well.”

Added Menon: “It is really, really neat to see how the team develops together, how they learn to work together, and how they prepare for a mission. And it was really confidence inspiring, and really, to me, a very beautiful part of the development process getting us to launch.”

Isaacman said the training for Polaris Dawn was as special as the mission itself. The astronauts’ preparations took them scuba diving and skydiving, into the cockpit of fighter jets, and even to the top of Mount Cotopaxi in Ecuador. Each day was a new adventure.

“You came in one day and this development suit had a handful of different rotators or joints in it that we were testing out,” Isaacman said, “and then we come back the next week and it would be entirely different.”

In just two and a half years, SpaceX trained the crew, modified Dragon, and developed the EVA suits for Polaris Dawn. To put that into perspective, Menon’s husband, Anil Menon, was selected by NASA for an astronaut mission four days before Menon was picked by SpaceX—but she flew first.

Why It Matters

The technology and capabilities demonstrated during Polaris Dawn could alter human spaceflight as we know it.

The spacewalk, for example, was more than a flashy achievement. NASA’s current EVA spacesuits were designed four decades ago, and suit maintenance has forced the agency to postpone several spacewalks in recent months. Earlier this year, NASA and Collins Aerospace “mutually agreed” to end a $100 million contract that would see Collins deliver new suits by 2026.

NASA could spend billions of dollars on a suit redesign. SpaceX’s EVA suit, meanwhile, is designed to be manufactured at scale for thousands of people to build and explore on Mars, Isaacman said. The suit was designed for Polaris Dawn specifically, “but just like a lot of things that SpaceX works on, the utility is quite broad,” he said, implying that other astronauts will one day wear it.

The Starlink communications system showcased during the mission, meanwhile, could be a tool to ease demand on NASA’s Deep Space Network: an array of giant radio antennas that supports communications in the final frontier.

“We’re even hearing now, just even alleviating the demand over the [U.S. Tracking and Data Relay Satellite System] and ground stations…as being a potential communication path to lunar missions, or potentially even Mars,” Isaacman said.

The altitude record, spacewalk, and symphony performance grabbed most of the Polaris Dawn headlines. But in between those objectives, the crew conducted an array of experiments to study the health of astronauts on long-duration spaceflight.

“There’s a lot of problems we have to solve if we’re going to have thousands of people living and working in space for really long periods of time and going really far from Earth,” said Menon.

For example, crewmembers stuck a device called an endoscope down their noses to image their airways, the first time that has been accomplished in space. They also researched spaceflight associated neuro ocular syndrome (SANS), a condition developed in microgravity that can impair astronauts’ vision. Other experiments focused on motion sickness, which according to Menon affects about 6 in 10 people when they first reach space.

“If you have 100 people in a spacecraft going up at the same time, and 60 of them are vomiting, that’s a big problem,” she said.

Data from these experiments will be entered into a database that is accessible to the wider space community, allowing non-SpaceX researchers to learn for years to come.

“If we want to have a future among the stars, if we want to have many people living and working there, we need these solutions,” Gillis said. “We need a new communication system. We need EVA suits so people can actually go and explore the surface of Mars. We need to understand the health implications so by the time we get there, they haven’t lost their vision and they aren’t sick.”

The crew also spent plenty of time studying problems back on Earth.

Isaacman’s Inspiration4 crewmate, St. Jude physician assistant Hayley Arceneaux, became the first human to fly to space with a prosthesis after recovering from childhood bone cancer. That mission raised more than a quarter of a billion dollars for the charity, which signed on as a partner for Polaris Dawn.

“You’ll continue to see [St. Jude] play a huge part in all of our missions until their work is done,” Isaacman said.

The astronauts traveled the world visiting hospitals and meeting children, medical professionals, and researchers who helped inform some of their experiments. They installed Starlink connections at many facilities, providing access to the Internet and education. The work was part of St. Jude’s effort to create cancer treatment programs, educate oncologists, and provide access to safe chemotherapy treatment worldwide.

“Right now, depending on where you’re born, you either have an 80 percent chance of survival, or you have a 20 percent chance if you’re not born in the U.S.,” Gillis said. “So [St. Jude has] pioneered extraordinary outcomes for children. But if you aren’t born here, you don’t benefit from that.”

One of the mission’s most special moments was Menon’s on-orbit reading of a children’s book she authored, Kisses from Space, to her two children and St. Jude patients. Proceeds from the book will go to St. Jude, and the charity will auction off the copy that traveled to space.

“It was ultimately the story of the power of love to overcome any distance, and I think, hopefully, sharing space but also sharing human connection and the power of that through this space story,” Menon said. “Reaching kids around the world was a powerful moment.”

What’s Next?

Isaacman said the Polaris Dawn crew still has a few weeks of debriefing, and he has yet to fully turn his sights to the next Polaris mission.

“We are still very on-mission,” he said. “We really need to understand everything we got right and could have done better on this one, things we got wrong and certainly could improve upon, before you even get to what’s in the realm of possibility for Mission Two.”

Isaacman couldn’t say much about the next mission. But some time next year, he said, the Polaris team will come together to determine what they can pull off.

For example, SpaceX could improve its EVA suit with added mobility, a portable life support system, or increased pressure, which would eliminate the “prebreathe” process Polaris astronauts used to remove nitrogen from their bodies before the EVA. Chances are the next mission will feature another spacewalk.

“It would be such a travesty if [SpaceX] didn’t take what they learned and take another giant leap in a good direction,” Isaacman said. “So I would fully expect EVAs are on the horizon for the next go.”

Mission Two will set the stage for the final Polaris mission, which is expected to be the debut crewed flight of SpaceX’s Starship. Both Starship and the Super Heavy booster are designed to be fully reusable, and SpaceX plans to fly them hundreds of times before adding crew. Musk in September said the company could launch uncrewed Starships to Mars within two years.

If SpaceX can successfully validate Starship, it could usher in a new era of civilian spaceflight. Gillis and Menon, for example, were the first two SpaceX employees to reach the final frontier, but they may not be the last.

“If you have a propulsion engineer, you have the interior engineer, the suit engineer on that spaceship, it makes a lot of sense to bring the expertise with you when you’re going to Mars,” Menon said. “I don’t think I ever thought it would happen this soon—and I definitely didn’t think it would be me.”

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The post Polaris Dawn Crew Talks Mission Highlights, Next Steps appeared first on FLYING Magazine.

On Sunday, Starship and the Super Heavy booster lifted off around 8:25 a.m. EDT from SpaceX’s Starbase launch pad in Boca Chica, Texas, on the rocket’s fifth suborbital test flight. But rather than splash down in the Gulf of Mexico, as it did on the previous flight, Super Heavy was caught in midair by a pair of metal “chopstick” arms the company refers to as “Mechazilla.”

It is the first time such a maneuver has been successfully completed and represents the program’s most ambitious milestone to date.

“The entire SpaceX team should take pride in the engineering feat they just accomplished,” the company said in a postlaunch update. “The world witnessed what the future will look like when Starship starts carrying crew and cargo to destinations on Earth, the moon, Mars and beyond.”

Built to Last

As SpaceX alluded to, Starship—which stands nearly 400 feet tall when stacked on Super Heavy—is being designed to one day ferry humans around the solar system.

The firm is also working under a $4 billion NASA contract to develop two human landing system (HLS) variants of Starship that will return Americans to the moon for the first time since the Apollo missions. The HLS will first fly on Artemis III, which is tentatively scheduled for September 2026 and will land NASA astronauts at the lunar south pole.

To develop such a vehicle, SpaceX will need to launch Starship hundreds of times. And to do that, both the rocket and booster will need to be turned around quickly. SpaceX therefore designed both components to be fully reusable. That makes Sunday’s mission—which returned Super Heavy to its launch pad intact—a key piece of validation.

“Congratulations to @SpaceX on its successful booster catch and fifth Starship flight test today!” said NASA Administrator Bill Nelson in a post on X. “As we prepare to go back to the Moon under Artemis, continued testing will prepare us for the bold missions that lie ahead—including to the South Pole region of the Moon and then on to Mars.”

Following liftoff, Super Heavy separated from Starship and reversed course back to Earth, descending at supersonic speed. The booster then fired a handful of engines to apply the brakes, slowing to a hover before Mechazilla snared it from the sky about seven minutes into the mission. It was a bull’s-eye landing and the first time the booster had launched and returned to the same pad. SpaceX captured the moment in real time.

“Thousands of distinct vehicle and pad criteria must be met prior to a return and catch attempt of the Super Heavy booster, which will require healthy systems on the booster and tower and a manual command from the mission’s flight director,” SpaceX said in a post on X.

Super Heavy is significantly larger than SpaceX’s ubiquitous Falcon 9 rocket, which it has successfully landed hundreds of times both on land and at sea. And because it lacks landing legs, SpaceX was forced to get creative.

The company achieved its goal remarkably quickly. Flight 4 was a huge step, as the booster splashed down “with half a centimeter accuracy,” according to Bill Gerstenmaier, vice president of build and flight reliability at SpaceX. Previous missions, however, lost the booster entirely.

According to Dan Huot, a SpaceX communications manager on Sunday’s live feed, “We’re going to start looking real soon at when we can catch a [Starship].”

Starship, meanwhile, completed its own objectives, executing hot-stage separation, ignition, and ascent to outer space. It coasted about halfway around the planet before reentering the atmosphere, flipping itself around, and making a controlled splashdown in the Indian Ocean. A camera buoy captured that moment as well.

Like Super Heavy during Flight 4, the rocket tipped over and sunk into the ocean. This time, though, SpaceX upgraded Starship’s thermal systems for reentry, where conditions are hot enough to envelop the rocket in plasma. The upgrade appeared to prevent the loss of flaps and other hardware that were jettisoned previously.

“We were not intending to recover any of the ship’s hardware, so that was the best ending that we could have hoped for,” said SpaceX engineer Kate Tice during Sunday’s live stream.

Under Scrutiny

SpaceX says it intends to churn out thousands of Starships per year at its one million-square-foot Starfactory plant. But the company is frustrated by the pace of the FAA launch licensing process, even going so far as to air its grievances publicly.

The FAA took extra time to review the Flight 5 mission profile.

“SpaceX’s current license authorizing the Starship Flight 4 launch also allows for multiple flights of the same vehicle configuration and mission profile,” an agency spokesperson told FLYING last month. “SpaceX chose to modify both for its proposed Starship Flight 5 launch which triggered a more in-depth review.”

The FAA evaluated a new splashdown site in the Gulf of Mexico as well as what it predicted would be an unusually large sonic boom during the booster landing, prompting respective 60-day consultations with the National Marine Fisheries Service and U.S. Fish and Wildlife Service. It has also proposed more than $630,000 in fines against SpaceX for allegedly violating the terms of its license during two previous missions, neither involving Starship.

According to FAA Administrator Mike Whitaker, the measures are “necessary” for safety. SpaceX takes a decidedly different perspective. It claims the agency communicated a September timeline for Flight 5 that was later revised to late November. Saturday’s approval of a launch license therefore came as a bit of a surprise.

“We continue to be stuck in a reality where it takes longer to do the government paperwork to license a rocket launch than it does to design and build the actual hardware,” SpaceX said in a September update. “This should never happen and directly threatens America’s position as the leader in space.”

SpaceX also faces scrutiny for failing to contain a liquid oxygen spill at Starbase in violation of the Clean Water Act, the EPA told FLYING last month. The company ate a $150,000 fine but denied it expels anything other than regular drinking water.

What’s Next?

If it sticks to the Flight 5 mission profile for the next Starship test, SpaceX will be able to launch under its current license.

But if the firm makes significant modifications—as it is prone to do, given that each mission has been more ambitious than the last—it could become entangled in another FAA feud.

Starship’s debut crewed flight is intended to be the third mission of the Polaris Program—a series of private flights purchased from SpaceX by billionaire CEO Jared Isaacman, the first of which concluded last month. Before then, SpaceX plans to fly hundreds of missions without crew. CEO Elon Musk even said last month that the firm intends to launch routine, uncrewed Starship missions to Mars within two years.

NASA has estimated that the spacecraft will require about 15 test flights before the Starship HLS is ready to put humans back on the moon. The next step for SpaceX will be to validate orbital flight (all Starship missions so far have been suborbital) and demonstrate orbital maneuvers like propellant transfer. That’s exactly what the firm plans to do as early as next year, launching twin Starships that will mate and transfer fuel from one to the other.

Starship is loaded with about 10 million pounds of propellant, generating some 17 million pounds of thrust from its 13 Raptor engines. It boasts greater fuel capacity than any modern technology. But to give it enough juice to fly to the moon and back, it will need to fuel up at an orbital propellant depot. To hit its Artemis III deadline, NASA will need Starship to complete several missions to stock up that fuel supply. Officials are contemplating alternative mission profiles in case there isn’t enough time..

“The pacing item is the rate at which SpaceX can launch the systems that can fuel the depot,” said Lori Glaze, acting deputy associate administrator of NASA’s exploration directorate, earlier this month.

In furtherance of that objective, SpaceX is developing a second launch pad at Starbase. The company also seeks to launch and recover rockets from Launch Complex 39A at Kennedy Space Center in Florida, which could increase Starship’s cadence.

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The spacecraft had been scheduled to launch Thursday from the Kennedy Space Center (KSC) at Cape Canaveral, Florida, aboard a SpaceX Falcon Heavy rocket. The highly anticipated mission is seeking to find out whether Europa and its subsurface ocean could support life.

But on Sunday, NASA and SpaceX announced they would be standing down the launch attempt “due to anticipated hurricane conditions in the area.”

Workers have secured the Europa Clipper craft in SpaceX’s hangar at Launch Complex 39A at KSC, NASA said, and the center began preparing for Hurricane Milton that day.

“The safety of launch team personnel is our highest priority, and all precautions will be taken to protect the Europa Clipper spacecraft,” said Tim Dunn, senior launch director at NASA’s Launch Services Program, in a statement.

The announcement came as Milton was rapidly intensifying from a tropical storm into one of the strongest hurricanes on record. On Monday evening, the National Weather Service’s National Hurricane Center reported Milton was a “potentially catastrophic” Category 5 hurricane with maximum sustained winds near 165 mph (270 km/h), threatening the northern coast of Mexico’s Yucatán Peninsula.

NASA’s Crew-8 mission has also been impacted by Hurricane Milton. The SpaceX Dragon capsule was scheduled to splash down Tuesday off the Florida coast carrying three NASA astronauts and one Russian cosmonaut, all of whom have completed a crew rotation at the International Space Station that began in March. The Crew-8 undocking has now been postponed to no earlier than Sunday.

KSC Will Face Weakened Milton

Milton’s winds are forecast to ease slightly before making landfall on Florida’s Gulf Coast as a still-deadly Category 3 hurricane late Wednesday or early Thursday. Storm surge warnings are in effect for much of Florida’s Gulf Coast, with water rising potentially by as much as 15 feet (4.6 meters) in the Tampa Bay area.

However, by the time Milton crosses the peninsula and reaches the Space Coast, the storm is expected to have weakened significantly to a Category 1 hurricane, the Space Force’s 45th Weather Squadron reported on Monday. A Category 1 hurricane has sustained winds between 74 and 95 mph (119 and 153 km/h).

Although KSC lies in roughly the center of the cone of possible paths, it is not under a mandatory evacuation order. Still, “we do expect downed trees, power outages, possible cell service outages, and localized flooding,” said the 45th Weather Squadron, which is responsible for KSC’s launch forecasts.

All of KSC’s original major facilities—including the massive Vehicle Assembly Building (VAB) and the launch pads—were designed to withstand winds of at least 104 mph (167 km/h). And every facility at KSC built after 1992’s Hurricane Andrew was built to a higher standard of 130 to 135 mph (209 to 217 km/h).

But that doesn’t mean the center is immune to wind damage. In 2004, Hurricane Frances ripped over 800 exterior panels off the south side of the Vehicle Assembly Building, leaving gaping holes requiring years of repairs—even though ground-level winds at KSC never reached hurricane strength.

How NASA Battens Down the Hatches

NASA has a well-defined hurricane preparation plan at KSC that it is currently carrying out.

On Monday night, KSC was at HURCON 3, or Hurricane Condition III, a status activated when surface winds of over 58 mph (93 km/h) could arrive within 48 hours. At HURCON 3, KSC’s protocol calls for securing facilities, property, and equipment.

HURCON 3 is also when NASA briefs and deploys the ride-out team (ROT)—a core team of around 100 to 120 essential personnel that will ride out the storm at KSC while all other workers are offsite. As the storm nears, KSC will go to HURCON 2 and eventually HURCON 1, with the ROT hunkered down and the facility closed.

During the storm, the ROT’s job is to keep essential infrastructure running. After the storm passes, the ROT will perform an initial damage assessment from a vehicle and do what it can before handing off to another team for a fuller assessment and to start recovery efforts.

When the facility is deemed safe, the rest of the center’s staff can return to work, including launch teams, who will assess launch pads and processing facilities for storm damage. Only then will NASA be able to set a new timeline for Europa Clipper’s launch.

“Once we have the ‘all-clear’ followed by facility assessment and any recovery actions, we will determine the next launch opportunity for this NASA flagship mission,” said Dunn.

The mission has daily launch opportunities during a window that runs through November 6.

Editor’s Note: This article first appeared on Astronomy.

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The agency on Sunday stood down from Thursday’s scheduled Europa Clipper launch due to the approaching Hurricane Milton. But crews on Friday completed one of the final steps in the prelaunch checklist, moving the spacecraft to the hangar at Launch Complex 39A at Kennedy Space Center in Florida. The launch window remains open until November 6.

“Once we have the ‘all-clear’ followed by facility assessment and any recovery actions, we will determine the next launch opportunity for this NASA flagship mission,” said Tim Dunn, senior launch director for NASA’s Launch Services Program.

Europa Clipper will fly nearly 1.8 billion miles to Jupiter’s icy moon, Europa, to study whether the rocky satellite could support life. The mission will produce the first detailed investigations of the moon and is expected to enter Jovian orbit in 2030.

Scientists believe Europa may hold an ocean beneath its icy surface that contains twice as much liquid water as all oceans on Earth, despite it being about the same size as our moon. NASA will perform nearly 50 close-proximity flybys to explore its composition and geography, coming as close as within 16 miles of the surface. The goal is to produce a scan of the entire moon.

NASA selected Europa Clipper in 2017 and began building the eponymous spacecraft in 2019. With its massive solar arrays unfurled, the vehicle is about 100 feet long, about the size of a basketball court. The spacecraft’s large solar panels will power it as it cruises through a portion of space more than five times as far from the Sun as Earth.

The robotic craft will weigh nearly 13,000 pounds at launch, about half of which comes from the weight of propellant. Adding to that is an array of nine dedicated science instruments, which are shielded by a vault made of titanium and aluminum to protect against radiation. Spectrometers will produce high-resolution maps of Europa’s surface and atmosphere, and ice-penetrating radar will scan for water below the surface. Other tools will be used to locate warmer pockets of ice, for example.

Europa Clipper will launch atop a SpaceX Falcon Heavy rocket from Launch Complex 39-A at Kennedy. En route to Europa, it will perform a pair of “gravity assists,” using the pull of both Earth and Mars to propel itself further.

The spacecraft is expected to enter Jupiter’s orbit in April 2030 and perform its first flyby of Europa the following spring. Science instruments will begin collecting data in May 2031. The mission is scheduled to conclude in September 2034 when Europa Clipper smashes into Jupiter’s largest moon, Ganymede.

NASA will provide live prelaunch and launch coverage on its website and social media channels. Members of the public can also register to attend the launch virtually.

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“[The class of 2024] represents the true pioneering spirit of aviation and space exploration, from the quest to travel across the globe faster, more safely and efficiently, to inventing the scientific inventions necessary to reach the moon,” said Jim Kidrick, president and CEO of the San Diego Air & Space Museum. “Achievements in aviation and space, as embodied by the honorees in the prestigious International Air & Space Hall of Fame, directly represent the human pioneering spirit and pursuit of mankind’s future frontiers.”

Among the members of the IASHF, which was established in 1963, are the Wright brothers, pilots Charles Lindbergh, Amelia Earhart, Chuck Yeager, and Jackie Cochran,  astronauts Neil Armstrong, Bill Anders, and Jim Lovell, and engineers and aircraft designers such as Igor Sikorsky, Wernher von Braun, Jack Northrop, William Boeing Sr., Reuben H. Fleet, and Glenn Curtiss.

The gala event to welcome the honorees is set for November 9 in the Edwin D. McKellar Pavilion of Flight.

This year’s honorees include:

• Stephen Altemus: Altemus is the co-founder, president, and CEO of Intuitive Machines, a company that develops designs to advance both human and robotic exploration of the moon, Mars, and the planets beyond. Altemus and Intuitive Machines partnered with NASA and are a key player in the plans for a manned return to the moon.

• Bell Flight: Bell has been developing helicopters since 1939. The Bell 47, also known as the MASH helicopter, is one of its more famous designs. Known for its versatility, there is hardly a television news department, medical service provider, or law enforcement agency in a large city that hasn’t used a Bell aircraft, a testament to the versatility of the rotor-wing designs. And, of course, the Bell X-1 was the vehicle that ushered in the age of supersonic flight.

• Salvatore “Tory” Bruno: The president and CEO of United Launch Alliance (ULA) will be recognized for his leadership at the nation’s most reliable and experienced launch service provider. Since 2006, ULA has made more than 150 consecutive launches using Atlas and Delta rockets. The company is continuing its efforts with the new Vulcan rocket family that will be used for future launches.

• International Council of Air Shows (ICAS): The International Council of Air Shows is the organization behind many of the aviation events that attract thousands to airports around the world. The organization was established in 1967 by airshow professionals and has evolved into a globally recognized authority on airshow safety. ICAS plays a pivotal role in advancing best practices, addressing regulatory and safety concerns, and fostering collaboration with military and civilian stakeholders, resulting in entertaining and safe events.

• Katherine Johnson: The former NASA mathematician was celebrated in the 2016 biopic movie Hidden Figures. Johnson’s calculations in orbital mechanics, done on a chalkboard or with pencil and paper, were instrumental in the success of America’s first crewed spaceflights, including the Apollo moon landings. At the time there were very few women or people of color involved in the space program. Johnson, being both, often had to deal with the stereotypes to have her work recognized and accepted.

• Laurans “Larry” Mendelson: In 1990, Mendelson, with the help of his sons Eric and Victor, took a small Florida-based public company, HEICO, and turned it into an international supplier for aerospace and electronics. Under their leadership, the company makes hundreds of thousands of parts and employs approximately 10,000 team members in 21 states in North America and 15 countries.

• Northrop Grumman B-21 Raider: The B-21 Raider is the next generation of long-range strike bombers. Designed for endurance and stealth as well as manned and unmanned operations, the advanced aircraft is intended to be a key player in the U.S. Air Force strategic bomber fleet.

• Blake Scholl: ,In 2014, Scholl wanted to make high-speed travel a reality as a means to foster deeper global connections, so he founded Boom Supersonic. Through the development of Overture, the world’s fastest commercial airliner, the company strives to create faster, more affordable, and more environmentally sustainable air travel.

The complete list of Hall of Fame members is available here.

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The firm is preparing for the Crew-9 astronaut rotation mission to the International Space Station (ISS), which will culminate in the long-awaited return of astronauts Butch Wilmore and Suni Williams in February. Wilmore and Williams hitched a ride to the ISS on Boeing’s Starliner in June and have remained there as engineers contended with several issues on the spacecraft.

Crew-9 will be the first human spaceflight to launch from Space Launch Complex-40. Initially scheduled to fly in August, the mission was pushed back to give NASA and Boeing more time to analyze and eventually undock Starliner, freeing up space for Dragon to dock.

The flight is NASA’s ninth Commercial Crew mission with SpaceX, the agency’s sole active contractor for that program. Boeing, the other contract recipient, is still developing Starliner but hopes to fly an inaugural astronaut rotation mission late next year. The program seeks to maintain a continuous human presence on the ISS, which in 2025 will enter its 24th consecutive year of occupation.

Crew-9 was originally slated to be a four-person mission. But only NASA astronaut Nick Hague and Roscosmos cosmonaut Aleksandr Gorbunov will fly up to the space station, meaning Dragon will launch with a pair of empty seats. NASA astronauts Zena Cardman and Stephanie Wilson were taken off the flight to make way for Williams and Wilmore but are eligible for reassignment.

Hague was chosen due to his experience. Gorbunov, who has never flown to space, remains on the manifest because NASA is required to send a Roscosmos cosmonaut on the mission.

After liftoff, Dragon will accelerate to 17,500 mph before docking autonomously with the space station. Upon arrival, they will join the crew of ISS Expedition 72, which includes Wilmore, Williams, NASA astronaut Don Pettit, and Roscosmos cosmonauts Alexey Ovchinin and Ivan Vagner.

Over the course of about five months, the crew will perform station maintenance via spacewalk and conduct more than 200 scientific research experiments, intended to prepare humans for exploration beyond low-Earth orbit as well as solve problems back on Earth. Among other things, they will study the physics of supernova explosions, the behavior of cells and platelets during long-duration spaceflight, and methods to reduce changes to astronaut brain and ocular structure due to low gravity.

NASA will provide live streaming coverage of the Crew-9 prelaunch, launch, postlaunch, and docking on NASA+ and the agency’s website, starting Friday afternoon. It will also maintain a live video feed of the launchpad in the hours leading up to liftoff and provide blog updates. Spaceflight enthusiasts can register to attend the launch virtually.

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December 11 is the submission deadline for Stage 1 of GoAERO—a three-year contest backed by NASA, Boeing, RTX, and other key aviation stakeholders seeking to aid the estimated 4.5 million Americans living in “ambulance deserts,” who may need to wait longer than 25 minutes for emergency services to arrive. The aircraft created by competitors could rescue people in danger and respond to disasters, medical emergencies, or humanitarian crises.

Officially launched on February 5, GoAERO (Aerial Emergency Response Operations) has been recruiting teams of university students who lack the financial backing of large corporations. But the competition is open to just about anyone over the age of 18, GoAERO founder and CEO Gwen Lighter told FLYING.

“It is a call for engineers and entrepreneurs and innovators and universities and students and professors and retirees and businesses and corporations and all of that to join us and to create these emergency response fliers,” said Lighter.

Lighter envisions GoAERO’s emergency response flyers as “another tool in the first response toolkit.” Helicopters, she said, are great for emergency response but are expensive to procure and operate, require a pilot, and struggle to operate in tight spaces.

Drones, at the other end of the spectrum, are excellent for delivering medical supplies. Drone delivery companies Zipline and Wing, for instance, have collectively transported hundreds of thousands of shipments of blood, vaccines, and equipment. But when it comes to search and rescue, drones can only complete the latter portion of the mission.

“What we are doing is we are saying, ‘OK, helicopters are one end of the spectrum, drones are the other,’ and then putting them together, molding them into something that can deliver a first responder to someone in need, rescue someone who needs help, deliver needed goods and supplies, all within the rubric of natural disasters, everyday medical emergencies, events caused by climate change, humanitarian crises,” Lighter said.

The aircraft are intended to be simple, compact, and uncrewed, flying either entirely on their own or with help from a remote pilot. They must also be easily transportable, deployable within minutes, and capable of delivering first responders, patients, or supplies in cities, rural areas, and disaster zones.

Aviation for Public Good

Lighter previously organized GoAERO’s predecessor GoFLY, which similarly sought to put groundbreaking technology into the hands of people who otherwise would not have access. But whereas GoFLY was geared toward personal, recreational flight, GoAERO is about helping others.

“GoAERO is really focused on a singular mission, which is saving lives,” Lighter said. “It is aviation for public good.”

According to Lighter, all GoFLY partners have signed on to the new initiative, and even more have joined. Boeing is the lead GoAERO sponsor, but the contest is also backed by RTX, Honeywell, Iridium, and industry groups such as the Aircraft Owners and Pilots Association (AOPA) and International Council of the Aeronautical Sciences (ICAS). First responders, aviation regulators, and other organizations are on board.

“We’ve had hundreds of discussions with not only aviation [firms], but first responders in a wide variety of different types of response, whether that is search and rescue, whether that is wildfire, whether that is earthquake, whether that is everyday medical emergencies and EMTs,” said Lighter.

She added: “Collectively, we have landed on these technical rules and specifications to create aircraft that really allow first responders to be first responders, rather than pilots and all of these other things.”

GoAERO will provide teams with some design guidelines. But Lighter told FLYING that the goal is for participants to produce a wide range of designs. Teams will be permitted to focus on medical needs and disaster scenarios specific to their area, for example.

“Success for us looks like in three years, at the end of the competition, that we have a multitude of different flyers that show up, and some are better in everyday medical emergencies, and some are better in urban environments, and some are better in remote environments, and some are better in wildfires,” said Lighter.

Participants will have some help from above. The competition offers what Lighter called a “full education platform,” with educational webinars, legal assistance, and one-on-one mentorship opportunities with experts from Boeing, U.S. government agencies such as the FAA or Department of Defense, and other mentors. Those relationships can help them refine design concepts, build autonomy, or raise funding.

GoAERO earlier this month, for example, signed a Space Act Agreement with NASA that will see the space agency lend its personnel to the initiative. NASA also committed $400,000 through its University Innovation Project to support U.S.-based university teams and will grant access to free or discounted software, services, and products.

“I think GoAERO represents bringing the best of aeronautics and aviation to the public space, to public good, making sure that we are bringing our capabilities, our technologies, our genius together to work for the American people and for the people across the globe that need these kind of services,” said Bob Pearce, associate administrator of NASA’s Aeronautics Research Mission Directorate (ARMD) and GoAERO mentor.

The Fly-Off

The GoAERO competition will culminate in a three-day “fly-off” beginning February 2027, during which teams will put their aircraft through a series of missions to gauge adversity, productivity, and maneuverability.

At stake are $2 million worth of prizes, including a $1 million grand prize for the winner. In addition, the top performer in each of the three fly-off missions will win $150,000. A $100,000 RTX Disruptor Award will be handed out for “disruptive advancement of the state of the art,” while a $100,000 autonomy prize will highlight the best use of automation.

All missions will be flown in a single-occupant aircraft carrying a mannequin, “Alex,” or other nonhuman payload. The contest will evaluate a range of different scenarios, testing competitors’ ability to save an injured person from under a forest canopy, douse a wildfire, rescue a drowning victim, and complete other emergency missions.

All of these must be performed under difficult conditions such as inclement weather, unknown terrain, or uncooperative air traffic control. Competitors will not have access to the mission courses or locations of obstacles until the day of the event. In addition, they should “expect the unexpected”—mission conditions and elements may not be exactly as advertised.

The FAA helped write the technical rules of the competition and will mentor teams to ensure their aircraft comply with federal rules. The agency will be “deeply involved” in the fly-off to maintain safety.

“We are closely working with the FAA in a number of their departments, and we have fully integrated our programming into today’s FAA certification process, and we will be helping our teams through that,” Lighter said.

During the contest, teams will have to dodge pylons and walls and contend with less-than-ideal takeoff and landing conditions. “The Flood” site, for example, is an 18-inch deep pool with simulated rain conditions—teams must touch or pop a balloon floating on its surface. Other locations will feature inclined slopes, sandy pits, or heavy winds.

A panel of expert judges will rank attempts by completion, speed, and payload, with bonus points awarded for one-person crew operations, quick deployment, and few operator inputs. To be eligible for the grand prize, a team needs to complete two missions, or complete one and partially complete another.

What Happens After?

Lighter emphasized that GoAERO hopes to produce not just emergency response flyers, but an ecosystem around them.

“We’re building this ecosystem so it’s not one company, it’s not one university, it’s not one entrepreneur, it’s not one regulator, it’s everybody coming together to use transformative technology to save lives,” she said.

At the end of the fly-off, the winning teams will have full control over what happens next. They will retain all intellectual property rights and do not necessarily need to commercialize their technology with a partner.

But while there are zero post-competition requirements, GoAERO aims to set teams up for success. Partners such as Boeing and RTX will be present for the fly-off, and winners will then have the option to meet with them and start a partnership.

“What we want to do is enable our teams to make the best choices for themselves at the end of the competition, whether that is licensing technology, whether that is building on their own, whether that is raising funds to commercialize, whether that is joining with a strategic partner—all are open and options for each of our teams,” Lighter said. “We certainly would never dictate to our teams how they should deploy. Rather, we will create the conditions where they have multiple options to be able to commercialize should they wish to do so.”

She added: “We all came together because we realized that there’s been a convergence of breakthrough technologies in aviation and in adjacent industries, and we now have this first moment in history that we have the ability to create new forms of emergency response aircraft.”

How to Get Involved

The deadline for GoAERO’s initial paper submission phase is December 11, which means there is plenty of time to apply.

To do so, applicants can visit goaeroprize.com to find the Stage 1 application forms, which include short biographies of each team member and legal documents covering liability and insurance, for example. Application is free, but there is a design submission fee of $250 for individuals and $500 for teams.

“Everything is on the website, from the technical rules to the schedules to the webinars to who the advisors are and who the partners are to how to engage with us,” said Lighter.

GoAERO excludes applicants under the age of 18, employees of Boeing or RTX and their families, and citizens or residents of countries subject to U.S. sanctions or export controls. But all others may apply, and the competition already includes teams from 40 countries. Entities that would prefer not to form a team but are interested in a partnership can also contact GoAERO.

Ten $10,000 winners will be selected from the Stage 1 pool, and eight Stage 2 teams will win $40,000 each. But teams can enter the competition at any time, including during the final fly-off. For that last phase, participants will need an aircraft with registration and airworthiness certification that has demonstrated, via video evidence, controlled flight with a full payload.

The stage is set. The rules are clear. All interested parties need to do is join the competition.

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Wyche is set to speak at the “Women Take Flight: Fashion to Fission” luncheon at the Frontiers of Flight Museum in Dallas on October 1. The event is sponsored by JSX, a private jet service, and scheduled to begin at 11:30 a.m. CST.

As part of her anticipated keynote presentation, Wyche, who has been part of NASA’s leadership team for the past 20 years, is expected to discuss her professional journey and how STEM made it possible for her to pursue the career she enjoys.

“The Frontiers of Flight Museum is truly honored to have Vanessa Wyche as our phenomenal keynote speaker for our inaugural ‘Women Take Flight: Fashion to Fission’ luncheon,” said Abigail Erickson-Torres, president and CEO of the museum. 

The event includes a panel discussion featuring women who are leaders in the aerospace industry, including:

• Leanne Caret, retired president and CEO of Boeing Defense, Space and Security
• Dyan Medina Gibbens, pilot, SpaceWERX, and U.S. Space Force adviser
• Caeley Looney, CEO and founder of Reinvented Inc. and flight director at Firefly Aerospace
• Amy Spowart, CEO of the National Aeronautic Association

The panelists will be discussing the paths they took to achieve their successes in aerospace and offer suggestions on ways to support more girls and women with an interest in STEM.

Tickets for the lunch start at $185 and may be purchased here. Proceeds will go toward supporting future STEM programs at the museum, as well as creating a new permanent exhibit to honor women in aerospace.

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