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By NASA
3 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
El piloto de pruebas de la NASA Nils Larson inspecciona el avión de investigación F-15D de la agencia en el Centro de Investigación de Vuelo Armstrong de la NASA en Edwards, California, antes de un vuelo de calibración para una sonda de detección de impactos de campo cercano recién instalada. Montada en el F-15D, la sonda está diseñada para medir las ondas de choque generadas por el silencioso avión supersónico X-59 durante el vuelo. Los datos ayudarán a los investigadores a comprender mejor cómo se comportan las ondas de choque en las proximidades de la aeronave, apoyando la misión Quesst de la NASA para permitir vuelos supersónicos silenciosos sobre tierra.NASA/Steve Freeman El piloto de pruebas de la NASA Nils Larson inspecciona el avión de investigación F-15D de la agencia en el Centro de Investigación de Vuelo Armstrong de la NASA en Edwards, California, antes de un vuelo de calibración para una sonda de detección de impactos de campo cercano recién instalada. Montada en el F-15D, la sonda está diseñada para medir las ondas de choque generadas por el silencioso avión supersónico X-59 durante el vuelo. Los datos ayudarán a los investigadores a comprender mejor cómo se comportan las ondas de choque en las proximidades de la aeronave, apoyando la misión Quesst de la NASA para permitir vuelos supersónicos silenciosos sobre tierra.NASA/Steve Freeman El avión de investigación F-15D de la NASA realiza un vuelo de prueba cerca de Edwards, California, con una sonda de detección de impactos de campo cercano. Idéntica a una versión previamente volada que estaba prevista como reserva, esta nueva sonda captará datos de ondas de choque cerca del X-59 mientras vuela a velocidad más rápida que la del sonido apoyando la misión Quesst de la NASA.NASA/Jim Ross El avión de investigación F-15D de la NASA realiza un vuelo de prueba cerca de Edwards, California, con una sonda de detección de impactos de campo cercano. Idéntica a una versión previamente volada que estaba prevista como reserva, esta nueva sonda captará datos de ondas de choque cerca del X-59 mientras vuela a velocidad más rápida que la del sonido apoyando la misión Quesst de la NASA.NASA/Jim Ross Read this story in English here.
Cuando se prueba un avión de última generación de la NASA, se necesitan herramientas especializadas para realizar pruebas y capturar datos, pero si esas herramientas necesitan mantenimiento, hay que esperar hasta que se reparen. A menos que tengas un respaldo. Por eso, recientemente la NASA ha calibró una nueva sonda de deteccíon de impactos para capturar datos de ondas de choque cuando el silencioso avión de investigación supersónico X-59 de la agencia inicie sus vuelos de prueba.
Cuando un avión vuela más rápido que la velocidad del sonido, produce ondas de choque que viajan a través del aire, creando fuertes estampidos sónicos. El X-59 desviará esas ondas de choque, produciendo sólo un silencioso golpe supersónico. En las últimas semanas, la NASA ha completado los vuelos de calibración de una nueva sonda de detección de impactos de campo cercano, un aparato en forma de cono que captará datos sobre las ondas de choque que generará el X-59.
Esta sonda está montada en un avión de investigación F-15D que volará muy cerca del X-59 para recopilar los datos que necesita la NASA. La nueva unidad servirá como la sonda de campo cercano principal de la NASA, con un modelo idéntico desarrollado por la NASA el año pasado actuará como reserva montada en otro F-15B.
Las dos unidades significan que el equipo del X-59 tiene una alternativa lista en caso de que la sonda principal necesite mantenimiento o reparaciones. Para pruebas de vuelo como las del X-59, donde la recopilación de datos es crucial y las operaciones giran en torno a plazos ajustados, condiciones meteorológicas y otras variables, las copias de respaldo de los equipos críticos ayudan a garantizar la continuidad, mantener los plazos y preservar la eficiencia de las operaciones.
“Si le ocurre algo a la sonda, como una falla en unsensor, no hay una solución fácil,” explica Mike Frederick, investigador principal de la sonda en el Centro de Investigación de Vuelos Armstrong de la NASA en Edwards, California. “El otro factor es el propio avión. Si uno necesita mantenimiento, no queremos retrasar los vuelos del X-59.”
Para calibrar la nueva sonda, el equipo midió las ondas de choque de un avión de investigación F/A-18 de la NASA. Los resultados preliminares indicaron que la sonda captó con éxito los cambios de presión asociados a las ondas de choque, de acuerdo con las expectativas del equipo. Frederick y su equipo ahora están revisando los datos para confirmar que se alinean con los modelos matemáticos en tierra y cumplen las normas de precisión requeridas para los vuelos X-59.
Los investigadores de la NASA en Armstrong se están preparando para vuelos adicionales con las sondas principal y de respaldo en sus aviones F-15. Cada avión volará a velocidad supersónico y recopilará datos de las ondas de choque del otro. El equipo está trabajando para validar tanto la sonda principal como la de respaldo para confirmar la redundancia total;en otras palabras, asegurarse de que tengan un respaldo fiable y listo para usar.
Artículo Traducido por: Priscila Valdez
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Last Updated May 13, 2025 EditorDede DiniusContactNicolas Cholulanicolas.h.cholula@nasa.gov Related Terms
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By NASA
Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22, 2025. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. NASA/Steven Seipel NASA completed another step to ready its SLS (Space Launch System) rocket for the Artemis III mission as crews at the agency’s Michoud Assembly Facility in New Orleans recently applied a thermal protection system to the core stage’s liquid hydrogen tank.
Building on the crewed Artemis II flight test, Artemis III will add new capabilities with the human landing system and advanced spacesuits to send the first astronauts to explore the lunar South Pole region and prepare humanity to go to Mars. Thermal protection systems are a cornerstone of successful spaceflight endeavors, safeguarding human life, and enabling the launch and controlled return of spacecraft.
The tank is the largest piece of SLS flight hardware insulated at Michoud. The hardware requires thermal protection due to the extreme temperatures during launch and ascent to space – and to keep the liquid hydrogen at minus 423 degrees Fahrenheit on the pad prior to launch.
“The thermal protection system protects the SLS rocket from the heat of launch while also keeping the thousands of gallons of liquid propellant within the core stage’s tanks cold enough. Without the protection, the propellant would boil off too rapidly to replenish before launch,” said Jay Bourgeois, thermal protection system, test, and integration lead at NASA Michoud. “Thermal protection systems are crucial in protecting all the structural components of SLS during launch and flight.”
In February, Michoud crews with NASA and Boeing, the SLS core stage prime contractor, completed the thermal protection system on the external structure of the rocket’s liquid hydrogen propellant fuel tank, using a robotic tool in what is now the largest single application in spaceflight history. The robotically controlled operation coated the tank with spray-on foam insulation, distributing 107 feet of the foam to the tank in 102 minutes. When the foam is applied to the core stage, it gives the rocket a canary yellow color. The Sun’s ultraviolet rays naturally “tan” the thermal protection, giving the SLS core stage its signature orange color, like the space shuttle external tank.
Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall liquid hydrogen tank with critical systems to ready it for its designated Artemis III mission. The core stage of SLS is the largest ever built by length and volume, and was manufactured at Michoud using state-of-the-art manufacturing equipment. (NASA/Steven Seipel) While it might sound like a task similar to applying paint to a house or spraying insulation in an attic, it is a much more complex process. The flexible polyurethane foam had to withstand harsh conditions for application and testing. Additionally, there was a new challenge: spraying the stage horizontally, something never done previously during large foam applications on space shuttle external tanks at Michoud. All large components of space shuttle tanks were in a vertical position when sprayed with automated processes.
Overall, the rocket’s core stage is 212 feet with a diameter of 27.6 feet, the same diameter as the space shuttle’s external tank. The liquid hydrogen and liquid oxygen tanks feed four RS-25 engines for approximately 500 seconds before SLS reaches low Earth orbit and the core stage separates from the upper stage and NASA’s Orion spacecraft.
“Even though it only takes 102 minutes to apply the spray, a lot of careful preparation and planning is put into this process before the actual application of the foam,” said Boeing’s Brian Jeansonne, the integrated product team senior leader for the thermal protection system at NASA Michoud. “There are better process controls in place than we’ve ever had before, and there are specialized production technicians who must have certifications to operate the system. It’s quite an accomplishment and a lot of pride in knowing that we’ve completed this step of the build process.”
The core stage of SLS is the largest NASA has ever built by length and volume, and it was manufactured at Michoud using state-of-the-art manufacturing equipment. Michoud is a unique, advanced manufacturing facility where the agency has built spacecraft components for decades, including the space shuttle’s external tanks and Saturn V rockets for the Apollo program.
Through Artemis, NASA will send astronauts to explore the Moon for scientific discovery, economic benefits, and build the foundation for the first crewed missions to Mars.
For more information on the Artemis Campaign, visit:
https://www.nasa.gov/feature/artemis/
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Jonathan Deal
Marshall Space Flight Center, Huntsville, Ala.
256-544-0034
jonathan.e.deal@nasa.gov
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By NASA
2 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
What is a black hole?
Well, the name is actually a little misleading because black holes aren’t actually holes. They’re regions in space that have a gravitational pull that is so strong that nothing can escape, not even light. Scientists know about two different sizes of black holes — stellar-mass black holes and supermassive black holes.
A stellar-mass black hole is born when a massive star dies. That’s a star that’s larger than our own Sun. These stars burn up all the nuclear fuel in their cores, and this causes them to collapse under their own gravity. This collapse causes an explosion that we call a supernova. The entire mass of the star is collapsing down into a tiny point, and the area of the black hole is just a few kilometers across.
Supermassive black holes can have a mass of millions to tens of billions of stars. Scientists believe that every galaxy in the universe contains a supermassive black hole. That’s up to one trillion galaxies in the universe. But we don’t know how these supermassive black holes form. And this is an area of active research.
What we do know is that supermassive black holes are playing a really important part in the formation and evolution of galaxies, and into our understanding of our place in the universe.
[END VIDEO TRANSCRIPT]
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Last Updated May 13, 2025 Related Terms
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By NASA
5 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
ICON’s next generation Vulcan construction system 3D printing a simulated Mars habitat for NASA’s Crew Health and Performance Exploration Analog (CHAPEA) missions.ICON One of the keys to a sustainable human presence on distant worlds is using local, or in-situ, resources which includes building materials for infrastructure such as habitats, radiation shielding, roads, and rocket launch and landing pads. NASA’s Space Technology Mission Directorate is leveraging its portfolio of programs and industry opportunities to develop in-situ, resource capabilities to help future Moon and Mars explorers build what they need. These technologies have made exciting progress for space applications as well as some impacts right here on Earth.
The Moon to Mars Planetary Autonomous Construction Technology (MMPACT) project, funded by NASA’s Game Changing Development program and managed at the agency’s Marshall Space Flight Center in Huntsville, Alabama, is exploring applications of large-scale, robotic 3D printing technology for construction on other planets. It sounds like the stuff of science fiction, but demonstrations using simulated lunar and Martian surface material, known as regolith, show the concept could become reality.
Lunar 3D printing prototype.Contour Crafting With its partners in industry and academic institutions, MMPACT is developing processing technologies for lunar and Martian construction materials. The binders for these materials, including water, could be extracted from the local regolith to reduce launch mass. The regolith itself is used as the aggregate, or granular material, for these concretes. NASA has evaluated these materials for decades, initially working with large-scale 3D printing pioneer, Dr. Behrokh Khoshnevis, a professor of civil, environmental and astronautical engineering at the University of Southern California in Los Angeles.
Khoshnevis developed techniques for large-scale extraterrestrial 3D printing under the NASA Innovative Advanced Concepts (NIAC) program. One of these processes is Contour Crafting, in which molten regolith and a binding agent are extruded from a nozzle to create infrastructure layer by layer. The process can be used to autonomously build monolithic structures like radiation shielding and rocket landing pads.
Continuing to work with the NIAC program, Khoshnevis also developed a 3D printing method called selective separation sintering, in which heat and pressure are applied to layers of powder to produce metallic, ceramic, or composite objects which could produce small-scale, more-precise hardware. This energy-efficient technique can be used on planetary surfaces as well as in microgravity environments like space stations to produce items including interlocking tiles and replacement parts.
While NASA’s efforts are ultimately aimed at developing technologies capable of building a sustainable human presence on other worlds, Khoshnevis is also setting his sights closer to home. He has created a company called Contour Crafting Corporation that will use 3D printing techniques advanced with NIAC funding to fabricate housing and other infrastructure here on Earth.
Another one of NASA’s partners in additive manufacturing, ICON of Austin, Texas, is doing the same, using 3D printing techniques for home construction on Earth, with robotics, software, and advanced material.
Construction is complete on a 3D-printed, 1,700-square-foot habitat that will simulate the challenges of a mission to Mars at NASA’s Johnson Space Center in Houston, Texas. The habitat will be home to four intrepid crew members for a one-year Crew Health and Performance Analog, or CHAPEA, mission. The first of three missions begins in the summer of 2023. The ICON company was among the participants in NASA’s 3D-Printed Habitat Challenge, which aimed to advance the technology needed to build housing in extraterrestrial environments. In 2021, ICON used its large-scale 3D printing system to build a 1,700 square-foot simulated Martian habitat that includes crew quarters, workstations and common lounge and food preparation areas. This habitat prototype, called Mars Dune Alpha, is part of NASA’s ongoing Crew Health and Performance Exploration Analog, a series of Mars surface mission simulations scheduled through 2026 at NASA’s Johnson Space Center in Houston.
With support from NASA’s Small Business Innovation Research program, ICON is also developing an Olympus construction system, which is designed to use local resources on the Moon and Mars as building materials.
The ICON company uses a robotic 3D printing technique called Laser Vitreous Multi-material Transformation, in which high-powered lasers melt local surface materials, or regolith, that then solidify to form strong, ceramic-like structures. Regolith can similarly be transformed to create infrastructure capable of withstanding environmental hazards like corrosive lunar dust, as well as radiation and temperature extremes.
The company is also characterizing the gravity-dependent properties of simulated lunar regolith in an experiment called Duneflow, which flew aboard a Blue Origin reusable suborbital rocket system through NASA’s Flight Opportunities program in February 2025. During that flight test, the vehicle simulated lunar gravity for approximately two minutes, enabling ICON and researchers from NASA to compare the behavior of simulant against real regolith obtained from the Moon during an Apollo mission.
Learn more: https://www.nasa.gov/space-technology-mission-directorate/
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By NASA
Artemis II crew members, shown inside the Neil Armstrong Operations and Checkout Building at NASA’s Kennedy Space Center in Florida, stand in front of their Orion crew module on Aug. 8, 2023. Pictured from left are CSA (Canadian Space Agency) astronaut Jeremy Hansen, and NASA astronauts Victor Glover, Reid Wiseman, and Christina Koch.Credit: NASA/Kim Shiflett NASA will host a live Twitch event to highlight the ongoing Moon Mascot Challenge, which invites the public to design a zero gravity indicator for the agency’s Artemis II crewed test flight around the Moon. Viewers will have the opportunity to provide real-time input to an artist who will create an example of a zero gravity indicator during the livestream.
Zero gravity indicators are small, plush items carried aboard spacecraft to provide a visual indication of when the crew reaches space.
The event will begin at 3 p.m. EDT on Tuesday, May 13, on the agency’s official Twitch channel:
https://www.twitch.tv/nasa
The contest invites global creators of all ages to submit design ideas for a zero gravity indicator that will fly aboard the agency’s Artemis II test flight, the first crewed mission under NASA’s Artemis campaign.
Up to 25 finalists, including entries from a K-12 student division, will be selected. The Artemis II crew will choose one design that NASA’s Thermal Blanket Lab will fabricate to fly alongside the crew in the Orion spacecraft.
During this Twitch event, NASA experts will discuss the Moon Mascot Challenge while the artist incorporates live audience feedback into a sample design. Although the design example will not be eligible for the contest, it will demonstrate how challenge participants can develop their own zero gravity indicator designs. The example will be shared on the @NASAArtemis social media accounts following the Twitch event.
The Artemis II test flight will take NASA astronauts Reid Wiseman, Victor Glover, and Christina Koch, and CSA (Canadian Space Agency) astronaut Jeremy Hansen on a 10-day journey around the Moon and back. The mission is another step toward missions on the lunar surface to help the agency prepare for future human missions to Mars.
To learn more about NASA’s missions, visit:
https://www.nasa.gov
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Rachel Kraft
Headquarters, Washington
202-358-1600
rachel.h.kraft@nasa.gov
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Last Updated May 12, 2025 EditorJessica TaveauLocationNASA Headquarters Related Terms
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