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By NASA
9 min read
Launch Your Creativity with These Space Crafts!
In honor of the completion of our Nancy Grace Roman Space Telescope’s spacecraft — the vehicle that will maneuver the observatory to its place in space and enable it to function once there — we’re bringing you some space crafts you can complete at home!
Join us for a journey across the cosmos, starting right in your own pantry.
Stardust Slime
Did you know that most of your household ingredients are made of stardust? And so are you! Nearly every naturally occurring element was forged by living or dying stars.
Take the baking soda in this slime recipe, for example. It’s made up of sodium, hydrogen, carbon, and oxygen. The hydrogen was made during the big bang, right at the start of the universe. But the other three elements were created by dying stars. So when you show your friends your space-y slime, you can tell them it’s literally made of stardust!
Instructions:
1 5 oz. bottle clear glue ½ tablespoon baking soda food coloring 1 tablespoon contact lens solution 1 tablespoon glitter Directions:
Pour the glue into a bowl
Mix in the baking soda
Add food coloring (we recommend blue, purple, black, or a combination).
Add contact lens solution and use your hands to work it through the slime. It will initially be very sticky! You can add a little extra contact lens solution to make it firmer and less goopy.
Add glitter a teaspoon at a time, using as much or as little as you like!
Space Suckers
Now let’s travel a little farther, past Earth’s atmosphere and into the realm of space. That’s where Roman is headed once the whole observatory is complete and passes all of its testing!
Roman will scan the skies from space to make it extra sensitive to faint infrared light. It’s harder to see from the ground because our atmosphere scatters and absorbs infrared radiation, which obscures observations.
Some astronauts have reported that space smells metallic or like gunpowder, but don’t worry — you can choose a more pleasant flavor for your space suckers!
Ingredients
2 cups sugar 2/3 cup light corn syrup 2/3 cup water gel food coloring flavor oil edible glitter dust sucker sticks sucker mold Directions
Prep the molds by adding sucker sticks.
Mix sugar, light corn syrup, and water together in a pot on the stove over medium heat.
Turn it up to medium-high heat and let it boil without stirring for about 6 minutes.
Quickly stir in the flavor oil of your choice, gel food coloring, plus as much edible glitter as you like (reserve some for dusting).
Carefully but quickly spoon the mixture into the molds. Spin the sticks so they’re evenly coated. Add a sprinkle of reserved edible glitter and allow to harden.” An image on the left side of the card shows the result: a deep purple sucker with silver glitter embedded.
Fizzy Planets
As we move toward our outer solar system, we’ll pass the orbits of the gas giant planets Jupiter and Saturn. While they don’t actually fizz like the mini planets you can make at home, they do have some pretty exotic chemistry that stems from their extreme pressures, temperatures, and compositions. For example, the hydrogen in their cores behaves like liquid metal instead of a gas. It even conducts electricity!
Roman will use multiple planet-spotting techniques –– microlensing, transits, and direct imaging –– to help us study a variety of worlds, including both gas giants and rocky worlds similar to our own.
Ingredients
3 cups baking soda ¾ cup water food coloring ¼ cup vinegar Directions
Mix a few drops of food coloring into ¼ cup of water and pour into a bowl with 1 cup of baking soda.
Repeat step one two more times using different colors.
Scoop together bits from each mixture to form small balls. Add an extra splash of water to any mixture that’s too crumbly.
Douse the balls with vinegar using an eye dropper or teaspoon and watch them fizz!
Marshmallow Constellations
As we venture farther out into space, we’ll reach some familiar stars! Constellations are groups of stars that appear close together in the sky as seen from Earth. But if you actually journeyed out to them, you might be surprised to discover that they’re often super far apart from each other!
Though constellations aren’t made of stars that are actually bound together in any way, they can still be useful for referencing a cosmic object’s location in the sky. For example, you can use a pair of binoculars or a telescope to take a look at the nebula found beneath Orion’s Belt, marked by the glitter patch in the recipe card above! You can find the constellation printables here.
Supplies
toothpicks or mini pretzel sticks mini marshmallows constellation printables scissors Directions
Attach marshmallows to toothpicks or pretzel sticks using the constellation cards as a guide. Carefully trim toothpicks or pretzel sticks as needed using scissors.
Black Hole Bath Bombs
Black holes –– objects with such strong gravity that not even light can escape their clutches –– lurk unseen throughout our galaxy. Stray too close to one and you’re in for a wild ride! But they aren’t cosmic vacuum cleaners, despite what you may have grown to believe. Just keep your distance and they’ll affect you the same way as any other object of the same mass.
Astronomers have found dozens of black holes in our galaxy by seeing how their gravity affects nearby objects. But there may be 100 million more that lack a visible companion to signal their presence. Roman will find some of these solitary black holes by seeing how their gravity focuses the light from farther stars.
Ingredients
1 cup baking soda ½ cup citric acid ½ cup cornstarch 2 tablespoons coconut oil black food coloring optional: 2 teaspoons essential oil for scent optional: ½ cup Epsom salt Directions
Mix the baking soda, citric acid, cornstarch, and Epsom salt (optional) together in a bowl.
In a separate bowl, mix the coconut oil, food coloring, and essential oil (optional).
Pour the liquid mixture into the dry mixture slowly while whisking it all together. Add a couple tiny splashes of water and whisk it in quickly.
Tightly press the mixture into round molds. Leave them for a few hours and then they’ll be ready to use!
Galaxy in a Jar
Now let’s go so far we can see our Milky Way galaxy from the outside — something many astronomers probably wish they could do at times!
Sort of like how Earth’s atmosphere can affect our view of space, dust in our galaxy can get in the way, too. That makes it easier to study other galaxies than our own in some ways! Roman’s combination of a large field of view, crisp resolution, and the ability to peer through dust make it the ideal instrument to study the Milky Way. The mission will build on previous observations to generate the most detailed map of our galaxy to date.
Ingredients
hot water glitter glue glitter super glue (optional) Directions
Mostly fill a 16 oz. glass jar with very hot water, leaving a couple inches of space at the top.
Add at least ¼ cup of glitter glue in colors of your choosing.
Add loose glitter a couple of teaspoons at a time, using as much or as little as you like! You can use a combination of fine and chunky glitter for an extended swirling effect.
Optional: Super glue the lid to the jar.
Once the water has sufficiently cooled, give the jar a gentle shake to see your galaxy swirl!
NOTE: Closely monitor children to ensure the jar doesn’t break.
Pinwheel Galaxy Pinwheels
As we continue our cosmic excursion, you’ll see other galaxies sprinkled throughout space. Many are spiral galaxies, like our Milky Way and the Pinwheel Galaxy from the craft described above. (You can find more detailed instructions and the printout you’ll need here.)
But galaxies come in other varieties, too. Through Roman’s wide, deep surveys, astronomers are sure to see every type. Scientists will study the shapes and distances of billions of galaxies to help us understand dark energy — a mysterious pressure that’s speeding up the universe’s expansion.
Supplies
Pinwheel Galaxy printout pipe cleaner or chopsticks scissors popsicle stick single hole puncher Directions
Cut out the hexagonal shape for your galaxy pinwheel.
Make cuts down the white lines.
Punch holes in the white dots: six around the edges and one in the center.
Turn the paper so it’s face-down.
Thread a pipe cleaner through the center hole.
Going around the circle, fold each flap so the pipe cleaner goes through the hole.
Tie a knot in the pipe cleaner to secure the front of the pinwheel. Wrap the other side of the pipe cleaner around a popsicle stick.
Universe Dough
We’re nearing the end of our voyage, having traveled so far through space and time that we can take in the whole universe! We’ve learned a lot about it, but there are still plenty of open questions. Some of its biggest components, dark energy and dark matter (invisible matter seen only via its gravitational influence), are huge mysteries Roman will explore. And since the observatory will reveal such large, deep swaths of space, who knows what new puzzles we’ll soon uncover!
Ingredients 1 cup flour ½ cup salt 1 tablespoon vegetable oil ½ cup hot water food coloring glitter Directions
Mix flour and salt in a bowl.
Add several drops of food coloring to hot water, and stir into dry mixture along with the oil.
Add as much glitter as you like and knead it into the dough for several minutes.
Add water or flour as needed to adjust the consistency.
Still feeling crafty? Try your hand at these 3D and paper spacecraft models. If you’re eager for a more advanced space craft, check out these embroidery creations for inspiration! Or if you’re ready for a break, take a virtual tour of an interactive version of the Roman Space Telescope here.
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Last Updated Sep 27, 2024 Related Terms
For Kids and Students Nancy Grace Roman Space Telescope NASA STEM Projects View the full article
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By NASA
4 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
Water piping is installed near the Thad Cochran Test Stand (B-1/B-2) at NASA’s Stennis Space Center in December 2014. The project to replace and upgrade the center’s high pressure industrial water system was a key milestone in preparations to test the SLS (Space Launch System) core stage ahead of the successful Artemis I launch.NASA/Danny Nowlin Employees install a 96-inch valve near the Thad Cochran Test Stand (B-1/B-2) at NASA’s Stennis Space Center as part of a high-pressure industrial water upgrade project in March 2015.NASA/Danny Nowlin In this March 2022 photo, crews use a shoring system to hold back soil as they install new 75-inch piping leading from the NASA Stennis High Pressure Industrial Water Facility to the valve vault pit serving the Fred Haise Test Stand.NASA/Danny Nowlin Crews use a specially designed tool to place a new pipeline liner inside the existing carrier pipe near the Fred Haise Test Stand in 2024 in the last phase of updating the original test complex industrial water system at NASA’s Stennis Space Center.NASA/Danny Nowlin Crews prepare new pipeline liner sections for installation near the Fred Haise Test Stand in 2024 in the last phase of updating the original test complex industrial water system at NASA’s Stennis Space Center.NASA/Danny Nowlin For almost 60 years, NASA’s Stennis Space Center has tested rocket systems and engines to help power the nation’s human space exploration dreams. Completion of a critical water system infrastructure project helps ensure the site can continue that frontline work moving forward.
“The infrastructure at NASA Stennis is absolutely critical for rocket engine testing for the agency and commercial companies,” said NASA project manager Casey Wheeler. “Without our high pressure industrial water system, testing does not happen. Installing new underground piping renews the lifespan and gives the center a system that can be operated for the foreseeable future, so NASA Stennis can add to its nearly six decades of contributions to space exploration efforts.”
The high pressure industrial water system delivers hundreds of thousands of gallons of water per minute through underground pipes to cool rocket engine exhaust and provide fire suppression capabilities during testing. Without the water flow, the engine exhaust, reaching as hot as 6,000 degrees Fahrenheit, could melt the test stand’s steel flame deflector.
Each test stand also features a FIREX system that holds water in reserve for use in the event of a mishap or fire. During SLS (Space Launch System) core stage testing, water also was used to create a “curtain” around the test hardware, dampening the high levels of noise generated during hot fire and lessening the video-acoustic impact that can cause damage to infrastructure and the test hardware.
Prior to the system upgrade, the water flow was delivered by the site’s original piping infrastructure built in the 1960s. However, that infrastructure had well exceeded its expected 30-year lifespan.
Scope of the Project
The subsequent water system upgrade was planned across multiple phases over a 10-year span. Crews worked around ever-changing test schedules to complete three major projects representing more than $50 million in infrastructure investment.
“Many people working the construction jobs for these projects are from the Gulf Coast area, so it has created jobs and work for the people doing the construction,” Wheeler said. “Some of the specialty work has had people coming in from all over the country, as well as vendors and suppliers that are supplying the materials, so that has an economic impact here too.”
Crews started by replacing large sections of piping, including a 96-inch line, from the 66-million-gallon onsite reservoir to the Thad Cochran (B-1/B-2) Test Stand. This phase also included the installation of a new 25,000-gallon electric pump at the High Pressure Industrial Water Facility to increase water flow capacity. The upgrades were critical for NASA Stennis to conduct Green Run testing of the SLS core stage in 2020-21 ahead of the successful Artemis I launch.
Work in the A Test Complex followed with crews replacing sections of 75-inch piping from the water plant and installing several new 66-inch gate valves.
In the final phase, crews used an innovative approach to install new steel liners within existing pipes leading to the Fred Haise Test Stand (formerly A-1 Test Stand). The work followed NASA’s completion of a successful RS-25 engine test campaign last April for future Artemis missions to the Moon and beyond. The stand now is being prepared to begin testing of new RS-25 flight engines.
Overall, the piping project represents a significant upgrade in design and materials. The new piping is made from carbon steel, with protective linings to prevent corrosion and gate valves designed to be more durable.
Importance of Water
It is hard to overstate the importance of the work to ensure ongoing water flow. For a typical 500-second RS-25 engine test on the Fred Haise Test Stand, around 5 million gallons of water is delivered from the NASA Stennis reservoir through a quarter-of-a-mile of pipe before entering the stand to supply the deflector and cool engine exhaust.
“Without water to cool the deflector and the critical parts of the test stand that will get hot from the hot fire itself, the test stand would need frequent corrective maintenance,” Wheeler said. “This system ensures the test stands remain in a condition where continuous testing can happen.”
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Last Updated Sep 26, 2024 EditorNASA Stennis CommunicationsContactC. Lacy Thompsoncalvin.l.thompson@nasa.gov / (228) 688-3333LocationStennis Space Center Related Terms
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By NASA
A SpaceX Falcon 9 rocket carrying the company’s Dragon spacecraft is launched on NASA’s SpaceX Crew-8 mission to the International Space Station with NASA astronauts Matthew Dominick, Michael Barratt, and Jeanette Epps, and Roscosmos cosmonaut Alexander Grebenkin onboard, Sunday, March 3, 2024, at NASA’s Kennedy Space Center in Florida.NASA/Aubrey Gemignani NASA invites the public to participate as virtual guests in the launch of the agency’s SpaceX Crew-9 mission. NASA astronaut Nick Hague, commander, and Roscosmos cosmonaut Aleksandr Gorbunov, mission specialist, will embark on a flight aboard a SpaceX Dragon spacecraft, launching no earlier than 1:17 p.m. EDT on Saturday, Sept. 28, from Space Launch Complex-40 at Cape Canaveral Space Force Station in Florida.
Members of the public can register to attend the launch virtually. Virtual guests for this mission will receive curated resources, interactive opportunities, updates with the latest news, and a mission-specific collectible stamp for their virtual guest passport after liftoff. Don’t have a passport yet? Print yours here and get ready to add a stamp!
Live coverage and countdown commentary will begin at 9:10 a.m. EDT Saturday, Sept. 28, streaming on NASA+ agency’s website. Learn how to stream NASA content on a variety of platforms, including social media.
Want to learn more about the mission and NASA’s Commercial Crew Program? Follow along on the mission blog, Commercial Crew blog, @commercial_crew on X, or check out Commercial Crew on Facebook.
View the full article
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By NASA
NASA astronaut Nick Hague and Roscosmos cosmonaut Aleksandr Gorbunov walk across the crew access arm at Space Launch Complex-40 at Cape Canaveral Space Force Station in Florida.Credit: SpaceX NASA will provide coverage of the upcoming prelaunch and launch activities for the agency’s SpaceX Crew-9 mission to the International Space Station.
Liftoff is targeted for 1:17 p.m. EDT, Saturday, Sept. 28, from Space Launch Complex-40 at Cape Canaveral Space Force Station in Florida. This is the first human spaceflight mission to launch from that pad. The targeted docking time is approximately 5:30 p.m. Sunday, Sept. 29.
Live coverage of the prelaunch news conference, launch, the post-launch news conference, and docking stream on NASA+ and the agency’s website. Learn how to stream NASA content through a variety of additional platforms, including social media.
The SpaceX Dragon spacecraft will carry NASA astronaut Nick Hague and Roscosmos cosmonaut Aleksandr Gorbunov to the orbiting laboratory for an approximate five-month science mission. This is the ninth crew rotation mission and the 10th human spaceflight mission for NASA to the space station supported by Dragon since 2020 as part of the agency’s Commercial Crew Program.
The deadline for media accreditation for in-person coverage of this launch has passed. The agency’s media credentialing policy is available online. For questions about media accreditation, please email: ksc-media-accreditat@mail.nasa.gov.
Media looking for access to NASA live video feeds can subscribe to the agency’s media resources distribution list to receive daily updates and links.
NASA’s mission coverage is as follows (all times Eastern and subject to change based on real-time operations):
Friday, Sept. 27
11:30 a.m. – One-on-one media interviews at NASA’s Kennedy Space Center in Florida with various mission subject matter experts. Sign-up information will be emailed to media accredited to attend this launch.
1:15 p.m. – NASA’s SpaceX Crew-9 Panel: Space Station 101 with the following participants:
NASA Associate Administrator Jim Free Robyn Gatens, director, NASA’s International Space Station Program, and acting director, NASA’s Commercial Spaceflight Division Jennifer Buchli, chief scientist, NASA’s International Space Station Program John Posey, Dragon engineer, NASA’s Commercial Crew Program Media may ask questions in person and via phone. Limited auditorium space will be available for in-person participation. For the dial-in number and passcode, media should contact the Kennedy newsroom no later than 12:15 p.m. Friday, Sept. 27, at ksc-newsroom@mail.nasa.gov.
Coverage of the virtual news conference will stream live on NASA+, YouTube, Facebook, and the agency’s website. Members of the public may ask questions online by posting questions to the YouTube, Facebook, and X livestreams using #AskNASA.
5 p.m. – Prelaunch news conference from Kennedy with the following participants:
NASA Associate Administrator Jim Free Ken Bowersox, associate administrator, NASA’s Space Operations Mission Directorate Steve Stich, manager, NASA’s Commercial Crew Program Dina Contella, deputy manager, NASA’s International Space Station Program Jennifer Buchli, chief scientist, NASA’s International Space Station Program William Gerstenmaier, vice president, Build & Flight Reliability, SpaceX Brian Cizek, launch weather officer, 45th Weather Squadron, Cape Canaveral Space Force Station Coverage of the virtual news conference will stream live on NASA+ and the agency’s website.
Media may ask questions in person and via phone. Limited auditorium space will be available for in-person participation. For the dial-in number and passcode, media should contact the Kennedy newsroom no later than 4 p.m. Friday, Sept. 27, at ksc-newsroom@mail.nasa.gov.
Saturday, Sept. 28
9:10 a.m. – Launch coverage begins on NASA+ and the agency’s website.
1:17 p.m. – Launch
Following the conclusion of launch and ascent coverage, NASA will switch to audio only. Continuous coverage resumes on NASA+ at the start of rendezvous and docking and continues through hatch opening and the welcome ceremony. For NASA+ information, schedules, and links to streaming video, visit:
https://plus.nasa.gov
3 p.m. – Postlaunch news conference with the following participants:
NASA Deputy Administrator Pam Melroy Ken Bowersox, associate administrator, NASA’s Space Operations Mission Directorate Dana Hutcherson, deputy program manager, NASA’s Commercial Crew Program Dina Contella, deputy manager, NASA’s International Space Station Program Sarah Walker, director, Dragon Mission Management, SpaceX The virtual news conference will stream live on NASA+, YouTube, and the agency’s website.
Media may ask questions in person and via phone. Limited auditorium space will be available for in-person participation. For the dial-in number and passcode, please contact the Kennedy newsroom no later than 2 p.m. Saturday, Sept. 28, at ksc-newsroom@mail.nasa.gov.
Sunday, Sept. 29
3:30 p.m. – Arrival coverage begins on NASA+ and the agency’s website.
5:30 p.m. – Targeted docking to the forward-facing port of the station’s Harmony module
7:15 p.m. – Hatch opening
7:40 p.m. – Welcome ceremony
All times are estimates and could be adjusted based on real-time operations after launch. Follow the space station blog for the most up-to-date operations information.
Audio Only Coverage
Audio only of the news conferences and launch coverage will be carried on the NASA “V” circuits, which may be accessed by dialing 321-867-1220, -1240 or -7135. On launch day, “mission audio,” countdown activities without NASA+ launch commentary, will be carried on 321-867-7135.
Launch audio also will be available on Launch Information Service and Amateur Television System’s VHF radio frequency 146.940 MHz and KSC Amateur Radio Club’s UHF radio frequency 444.925 MHz, FM mode, heard within Brevard County on the Space Coast.
Live Video Coverage Prior to Launch
NASA will provide a live video feed of Space Launch Complex-40 approximately six hours prior to the planned liftoff of the Crew-9 mission. Pending unlikely technical issues, the feed will be uninterrupted until the prelaunch broadcast begins on NASA+, approximately four hours prior to launch. Once the feed is live, find it online at: http://youtube.com/kscnewsroom
NASA Website Launch Coverage
Launch day coverage of NASA’s SpaceX Crew-9 mission will be available on the agency’s website. Coverage will include livestreaming and blog updates beginning no earlier than 9:10 a.m. Sept. 28, as the countdown milestones occur. On-demand streaming video and photos of the launch will be available shortly after liftoff.
For questions about countdown coverage, contact the Kennedy newsroom at 321-867-2468. Follow countdown coverage on the commercial crew or Crew-9 blog.
Attend Launch Virtually
Members of the public can register to attend this launch virtually. NASA’s virtual guest program for this mission also includes curated launch resources, notifications about related opportunities or changes, and a stamp for the NASA virtual guest passport following a successful launch.
Watch, Engage on Social Media
Let people know you’re following the mission on X, Facebook, and Instagram by using the hashtags #Crew9 and #NASASocial. You can also stay connected by following and tagging these accounts:
X: @NASA, @NASAKennedy, @NASASocial, @Space_Station, @ISS_Research, @ISS National Lab, @SpaceX, @Commercial_Crew
Facebook: NASA, NASAKennedy, ISS, ISS National Lab
Instagram: @NASA, @NASAKennedy, @ISS, @ISSNationalLab, @SpaceX
Coverage en Espanol
Did you know NASA has a Spanish section called NASA en Espanol? Make sure to check out NASA en Espanol on X, Instagram, Facebook, and YouTube for more coverage on Crew-9.
Para obtener información sobre cobertura en español en el Centro Espacial Kennedy o si desea solicitar entrevistas en español, comuníquese con Antonia Jaramillo: 321-501-8425;antonia.jaramillobotero@nasa.gov; o Messod Bendayan: 256-930-1371; messod.c.bendayan@nasa.gov.
NASA’s Commercial Crew Program has delivered on its goal of safe, reliable, and cost-effective transportation to and from the International Space Station from the United States through a partnership with American private industry. This partnership is changing the arc of human spaceflight history by opening access to low-Earth orbit and the International Space Station to more people, more science, and more commercial opportunities. The space station remains the springboard to NASA’s next great leap in space exploration, including future missions to the Moon and, eventually, to Mars.
For NASA’s launch blog and more information about the mission, visit:
https://www.nasa.gov/commercialcrew
-end-
Joshua Finch / Jimi Russell
Headquarters, Washington
202-358-1100
joshua.a.finch@nasa.gov / james.j.russell@nasa.gov
Steven Siceloff / Danielle Sempsrott / Stephanie Plucinsky
Kennedy Space Center, Florida
321-867-2468
steven.p.siceloff@nasa.gov / danielle.c.sempsrott@nasa.gov / stephanie.n.plucinsky@nasa.gov
Leah Cheshier
Johnson Space Center, Houston
281-483-5111
leah.d.cheshier@nasa.gov
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Last Updated Sep 25, 2024 LocationNASA Headquarters Related Terms
International Space Station (ISS) Commercial Crew Humans in Space ISS Research Johnson Space Center Kennedy Space Center View the full article
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