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Gojo SMAU - The Art of Falling Fake
Chapter 1 - Invisible in the Spotlight
Summary: The campus buzzes with life, but you feel like a shadow slipping through the cracks—unnoticed, unimportant. At home, it’s no better. Your parents dote on your step-sister, the star tennis player, while you’re the afterthought they barely acknowledge. She’s here too, her perfect reputation casting an even bigger shadow over your existence. College was supposed to be your escape, but living at home and walking the same halls as her makes it impossible. Then he shows up—Satoru Gojo, the rich, arrogant engineering major everyone seems to worship. His smug grin and effortless charm are the kind of things you can’t stand, but when a ridiculous twist of fate forces your lives together, you find yourself fake dating the most insufferable man you’ve ever met. It’s just a deal, temporary and harmless—or so you try to convince yourself.
an: Welcome to chapter one guys! Feedback is appreciated as always hehe. Also, the taglists for all of my stories are still OPEN, so make sure to get tagged so you don’t miss out on any new chapters! SMOOCHES 💋💋💋
{introduction} ; {next}
taglist: @hanakotateyama @sleepykittyenergy
࣪˖ ִ𐙚 𝜗𝜚 ࣪˖ ִ𐙚 𝜗𝜚 ࣪˖ ִ𐙚 𝜗𝜚 ࣪˖ ִ𐙚 𝜗𝜚 ࣪˖ ִ𐙚 𝜗𝜚 ࣪˖ ִ𐙚 𝜗𝜚 ࣪˖ ִ𐙚 𝜗𝜚 ࣪˖ ִ𐙚
Campus is chaos, as always. The sidewalks are packed with students rushing to their next class or chatting in tight little groups like they’ve known each other forever. It’s the first month of the semester, but it feels like everyone’s already found their place—everyone but you. You walk with your head down, weaving through the crowd as quietly and invisibly as possible. That’s been your strategy for years now. It works. Mostly.
You didn’t think living at home while attending college would feel so… stifling. At first, it seemed like the logical choice: save money, stay close to the familiar, and avoid the pressure of navigating both a new school and a new city. But now you’re not so sure. Sharing a roof with your parents and your step-sister, Mia, is starting to feel like you’re suffocating.
The comparisons never stop. Mia, the perfect daughter with her flawless tennis career and her endless achievements. She’s a campus celebrity in her own right—everyone knows her name, her face, her victories. And then there’s you. The one people glance at for a second before looking past you. The one who never quite measures up.
You pull your hoodie tighter around you as you pass a group of students standing by the fountain. One of them mentions Mia’s name, and you feel your stomach twist. Something about her latest tournament win, how she’s heading to the finals soon. It’s not surprising, but it still stings. She’s everywhere. Even here.
You shake the thoughts away and head toward the coffee shop near the engineering building. It’s your usual escape—a place to grab a moment of quiet before your next class. The line is long when you step in, but the familiar smell of coffee and the soft hum of indie music make it worth the wait. You tug your phone out of your pocket, scrolling mindlessly through messages you’re too tired to respond to.
That’s when it happens.
The force of someone slamming into you from behind nearly sends you tumbling forward. Your bag slips off your shoulder, and your coffee almost flies out of your hands.
“Whoa, careful there,” a smooth voice says, almost lazily, as though you were the one at fault.
You turn around, already annoyed, and find yourself face-to-face with him.
Satoru Gojo.
Of course, it’s him. Because who else would nearly knock you over and then smile at you like you owe him an apology? His snowy white hair practically glows under the fluorescent lights, and his blue eyes—hidden behind those ridiculous round sunglasses—glint with amusement. He’s tall, too tall, and he carries himself with the kind of confidence that only someone who’s never been told “no” can manage.
You’ve seen him around. Everyone has. Satoru Gojo is one of those people you can’t ignore even if you try. He’s an engineering major with top grades, an influential family name, and a reputation that precedes him. Girls throw themselves at him. Guys want to be him. He’s the king of campus—loud, obnoxious, and completely full of himself.
And now, unfortunately, he’s staring right at you.
“I think you dropped something,” he says, gesturing to your bag on the floor.
“No, really? Thanks for pointing that out,” you deadpan, bending down to pick it up.
When you straighten, his grin is still plastered on his face. It’s infuriatingly smug, like he’s thoroughly enjoying this interaction.
“You’re new,” he states, as if it’s a fact.
You glance around the room, hoping the line will move faster. “Why does it matter?”
“Because I know everyone here, and I definitely don’t know you,” he says, leaning casually against the counter like this is the most fascinating conversation he’s had all day.
“Congratulations. You’ve solved the mystery. I’m new.”
There’s a pause, and you can feel his eyes studying you, probably trying to figure out why you’re not falling all over yourself like the others do. “You don’t seem very impressed by me,” he finally says, and there’s a mock pout in his tone.
You can’t help but snort. “Why would I be?”
His grin widens, and for a split second, you see something flash in his eyes. Amusement? Curiosity? You don’t care enough to figure it out.
You step forward as the line moves, eager to order and leave before he decides to keep talking. But, of course, he follows.
“New girl, huh? So, what’s your name?”
“None of your business,” you reply, still not looking at him.
“Ouch,” he says, clutching his chest dramatically. “Cold and mysterious. I like it.”
You roll your eyes and finally make it to the counter, ordering the cheapest coffee on the menu. As you fumble with your wallet, you hear him behind you, ordering something unnecessarily complicated and way too expensive.
When you turn to leave, you catch his gaze one last time. His grin hasn’t wavered. “See you around, mystery girl,” he calls after you.
You don’t bother responding, walking out the door as quickly as you can.
But as you step back into the crowd, you can’t shake the feeling that he’s right.
Because as much as you want to stay invisible, something tells you Satoru Gojo isn’t about to let that happen.
Sewing Machines & Planned Obsolescence
I've got these two sewing machines, made about 100 years apart. An old treadle machine from around 1920-1930, that I pulled out of the trash on a rainy day, and a new Brother sewing machine from around 2020.
I've always known planned obsolescence was a thing, but I never knew just how insidious it was till I started looking at these two side by side.
I wasn't feeling hopeful at first that I'd actually be able to fix the old one, I found it in the trash at 2 am in a thunderstorm. It was rusty, dusty, soggy, squeaky, missing parts, and 100 years old.
How do you even find specialized parts 100 years later? Well, easily, it turns out. The manufacturers at the time didn't just make parts backwards compatible to be consistent across the years, but also interchangeable across brands! Imagine that today, being able to grab a part from an old iPhone to fix your Android.
Anyway, 6 months into having them both, I can confidently say that my busted up trash machine is far better than my new one, or any consumer-grade sewing machine on the market.
Old Machine Guts
The old machine? Can sew through a pile of leather thicker than my fingers like it's nothing. (it's actually terrifying and I treat it like a power tool - I'll never sew drunk on that thing because I'm genuinely afraid it'd sew through a finger!) At high speeds, it's well balanced and doesn't shake. The parts are all metal, attached by standard flathead screws, designed to be simple and strong, and easily reachable behind large access doors. The tools I need to work on it? A screwdriver and oil. Lost my screwdriver? That's OK, a knife works too.
New Machine Guts
The new machine's skipping stitches now that the plastic parts are starting to wear out. It's always throwing software errors, and it damn near shakes itself apart at top speed. Look at it's innards - I could barely fit a boriscope camera that's about as thick as spaghetti in there let alone my fingers. Very little is attached with standard screws.
And it's infuriating. I'm an engineer - there's no damn reason to make high-wear parts out of plastic. Or put them in places they can't be reached to replace. There's no reason to make your mechanism so unbalanced it's reaching the point of failure before reaching it's own design speed. (Oh yeah there is, it's corporate greed)
100 years, and your standard home sewing machine has gone from a beast of a machine that can be pulled out of the literal waterlogged trash and repaired - to a machine that eats itself if you sew anything but delicate fast-fashion fabrics that are also designed to fall apart in a few years.
Looking for something modern built to the standard that was set 100 years ago? I'd be looking at industrial machines that are going for thousands of dollars... Used on craigslist. I don't even want to know what they'd cost new.
We have the technology and knowledge to manufacture "old" sewing machines still. Hell, even better, sewing machines with the mechanical design quality of the old ones, but with more modern features. It would be so easy - at a technical level to start building things well again. Hell, it's easier to fabricate something sturdy than engineer something to fail at just the right time. (I have half a mind to see if any of my meche friends with machine shops want to help me fabricate an actually good modern machine lol)
We need to push for right-to-repair laws, and legislation against planned obsolescence. Because it's honestly shocking how corporate greed has downright sabotaged good design. They're selling us utter shit, and expecting us to come back for more every financial quarter? I'm over it.
Why are they telling all the engineers at graduating to cum loudly
My engineering teacher just called me out in class for having a super neat signature and I've never felt so genuinely amazing about a compliment I think.
BOOK RECOMMENDATIONS!
HELLO! I WOULD LIKE BOOK RECOMMENDATIONS!! any book really but im mainly looking for something revolving around nature/science/math!! something like that!! fiction for nature is okay but i would like nonfiction for the math and science books :3 (example for fic. nature is like "hatchet") THANKS!!! other genres/books i like are psychology, fantasy, sci-fi, mangas (just not romance), philosophy, and history!!! IF ANYONE COMMENTS I WOULD GREATLY APPRECIATE IT OK THANK YOU
Hey y’all
My first time making a moodboard, and I don’t know if it’s good or bad...
Anyway!
I tried to go for a Melissa Shield/engineer-girl theme, so feedback it always appreciated!
Love you all!
(Please don’t repost, just reblog XD)
Scary puppy
The Close-Up Face of a Spider.
Imagining your future is weird cause I know I am getting an engineering degree but what if after that I moved across the country and started working with a YouTube channel. Like will it ever happen? No. But is it fun to picture? Yes. Have I been watching too much Smosh? Maybe.
thank you, googly eyes on the red fire bell on the third floor of the engineering building. some days you're carrying all of us
Launch Your Creativity with 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 a space craft you can complete at home! Join us for a journey across the cosmos, starting right in your own pantry.
Stardust Slime
Ingredients:
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!
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!
Still feeling crafty? Try your hand at more pantry projects or 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.
Make sure to follow us on Tumblr for your regular dose of space!
This photo contains both flight (flat in the foreground) and qualification assembly (upright in the background) versions of the Solar Array Sun Shield for NASA’s Nancy Grace Roman Space Telescope. These panels will both shade the mission’s instruments and power the observatory.
Double Vision: Why Do Spacecraft Have Twin Parts?
Seeing double? You’re looking at our Nancy Grace Roman Space Telescope’s Solar Array Sun Shield laying flat in pieces in the foreground, and its test version connected and standing upright in the back. The Sun shield will do exactly what it sounds like –– shade the observatory –– and also collect sunlight for energy to power Roman.
These solar panels are twins, just like several of Roman’s other major components. Only one set will actually fly in space as part of the Roman spacecraft…so why do we need two?
Sometimes engineers do major tests to simulate launch and space conditions on a spare. That way, they don’t risk damaging the one that will go on the observatory. It also saves time because the team can do all the testing on the spare while building up the flight version. In the Sun shield’s case, that means fitting the flight version with solar cells and eventually getting the panels integrated onto the spacecraft.
Our Nancy Grace Roman Space Telescope's primary structure (also called the spacecraft bus) moves into the big clean room at our Goddard Space Flight Center (top). While engineers integrate other components onto the spacecraft bus in the clean room, the engineering test unit (also called the structural verification unit) undergoes testing in the centrifuge at Goddard. The centrifuge spins space hardware to ensure it will hold up against the forces of launch.
Engineers at our Goddard Space Flight Center recently tested the Solar Array Sun Shield qualification assembly in a thermal vacuum chamber, which simulates the hot and cold temperatures and low-pressure environment that the panels will experience in space. And since the panels will be stowed for launch, the team practiced deploying them in space-like conditions. They passed all the tests with flying colors!
The qualification panels will soon pass the testing baton to the flight version. After the flight Solar Array Sun Shield is installed on the Roman spacecraft, the whole spacecraft will go through lots of testing to ensure it will hold up during launch and perform as expected in space.
For more information about the Roman Space Telescope, visit: www.nasa.gov/roman. You can also virtually tour an interactive version of the telescope here.
Make sure to follow us on Tumblr for your regular dose of space!
Nora AlMatrooshi
Nora AlMatrooshi, the first Emirati woman astronaut, worked as a piping engineer before becoming an astronaut candidate for the United Arab Emirates. https://mbrsc.ae/team/nora/
Make sure to follow us on Tumblr for your regular dose of space!
Deniz Burnham
A former NASA intern, Deniz Burnham started her career as an engineer on an oil rig in Prudhoe Bay, Alaska, and went on to lead operations on drilling rigs in Canada, Ohio, and Texas. https://go.nasa.gov/3wDpfBo
Make sure to follow us on Tumblr for your regular dose of space!
Black Scientists and Engineers Past and Present Enable NASA Space Telescope
The Nancy Grace Roman Space Telescope is NASA’s next flagship astrophysics mission, set to launch by May 2027. We’re currently integrating parts of the spacecraft in the NASA Goddard Space Flight Center clean room.
Once Roman launches, it will allow astronomers to observe the universe like never before. In celebration of Black History Month, let’s get to know some Black scientists and engineers, past and present, whose contributions will allow Roman to make history.
Dr. Beth Brown
The late Dr. Beth Brown worked at NASA Goddard as an astrophysicist. in 1998, Dr. Brown became the first Black American woman to earn a Ph.D. in astronomy at the University of Michigan. While at Goddard, Dr. Brown used data from two NASA X-ray missions – ROSAT (the ROentgen SATellite) and the Chandra X-ray Observatory – to study elliptical galaxies that she believed contained supermassive black holes.
With Roman’s wide field of view and fast survey speeds, astronomers will be able to expand the search for black holes that wander the galaxy without anything nearby to clue us into their presence.
Dr. Harvey Washington Banks
In 1961, Dr. Harvey Washington Banks was the first Black American to graduate with a doctorate in astronomy. His research was on spectroscopy, the study of how light and matter interact, and his research helped advance our knowledge of the field. Roman will use spectroscopy to explore how dark energy is speeding up the universe's expansion.
NOTE - Sensitive technical details have been digitally obscured in this photograph.
Sheri Thorn
Aerospace engineer Sheri Thorn is ensuring Roman’s primary mirror will be protected from the Sun so we can capture the best images of deep space. Thorn works on the Deployable Aperture Cover, a large, soft shade known as a space blanket. It will be mounted to the top of the telescope in the stowed position and then deployed after launch. Thorn helped in the design phase and is now working on building the flight hardware before it goes to environmental testing and is integrated to the spacecraft.
Sanetra Bailey
Roman will be orbiting a million miles away at the second Lagrange point, or L2. Staying updated on the telescope's status and health will be an integral part of keeping the mission running. Electronics engineer Sanetra Bailey is the person who is making sure that will happen. Bailey works on circuits that will act like the brains of the spacecraft, telling it how and where to move and relaying information about its status back down to Earth.
Learn more about Sanetra Bailey and her journey to NASA.
Dr. Gregory Mosby
Roman’s field of view will be at least 100 times larger than the Hubble Space Telescope's, even though the primary mirrors are the same size. What gives Roman the larger field of view are its 18 detectors. Dr. Gregory Mosby is one of the detector scientists on the Roman mission who helped select the flight detectors that will be our “eyes” to the universe.
Dr. Beth Brown, Dr. Harvey Washington Banks, Sheri Thorn, Sanetra Bailey, and Dr. Greg Mosby are just some of the many Black scientists and engineers in astrophysics who have and continue to pave the way for others in the field. The Roman Space Telescope team promises to continue to highlight those who came before us and those who are here now to truly appreciate the amazing science to come.
To stay up to date on the mission, check out our website and follow Roman on X and Facebook.
Make sure to follow us on Tumblr for your regular dose of space!
How did you get to where you are now? and di you always know that this is where you wanted to end up?
The Nancy Grace Roman Space Telescope’s flight harness is transferred from the mock-up structure to the spacecraft flight structure.
Your Body is Wired Like a NASA Space Telescope. Sort Of.
If our Nancy Grace Roman Space Telescope were alive, its nervous system would be the intricate wiring, or “harness,” that helps different parts of the observatory communicate with one another. Just like the human body sends information through nerves to function, Roman will send commands through this special harness to help achieve its mission: answering longstanding questions about dark energy, dark matter, and exoplanets, among other mind-bending cosmic queries.
Roman’s harness weighs around 1,000 pounds and is made of about 32,000 wires and 900 connectors. If those parts were laid out end-to-end, they would be 45 miles long from start to finish. Coincidentally, the human body’s nerves would span the same distance if lined up. That’s far enough to reach nearly three-fourths of the way to space, twice as far as a marathon, or eight times taller than Mount Everest!
An aerial view of the harness technicians working to secure Roman’s harness to the spacecraft flight structure.
Over a span of two years, 11 technicians spent time at the workbench and perched on ladders, cutting wire to length, carefully cleaning each component, and repeatedly connecting everything together.
Space is usually freezing cold, but spacecraft that are in direct sunlight can get incredibly hot. Roman’s harness went through the Space Environment Simulator – a massive thermal vacuum chamber – to expose the components to the temperatures they’ll experience in space. Technicians “baked” vapors out of the harness to make sure they won’t cause problems later in orbit.
Technicians work to secure Roman’s harness to the interior of the spacecraft flight structure. They are standing in the portion of the spacecraft bus where the propellant tanks will be mounted.
The next step is for engineers to weave the harness through the flight structure in Goddard’s big clean room, a space almost perfectly free of dust and other particles. This process will be ongoing until most of the spacecraft components are assembled. The Roman Space Telescope is set to launch by May 2027.
Learn more about the exciting science this mission will investigate on X and Facebook.
Make sure to follow us on Tumblr for your regular dose of space!
Our Roman Space Telescope’s Dish is Complete!
NASA engineers recently completed tests of the high-gain antenna for our Nancy Grace Roman Space Telescope. This observatory has some truly stellar plans once it launches by May 2027. Roman will help unravel the secrets of dark energy and dark matter – two invisible components that helped shape our universe and may determine its ultimate fate. The mission will also search for and image planets outside our solar system and explore all kinds of other cosmic topics.
However, it wouldn’t be able to send any of the data it will gather back to Earth without its antenna. Pictured above in a test chamber, this dish will provide the primary communication link between the Roman spacecraft and the ground. It will downlink the highest data volume of any NASA astrophysics mission so far.
The antenna reflector is made of a carbon composite material that weighs very little but will still withstand wide temperature fluctuations. It’s very hot and cold in space – Roman will experience a temperature range of minus 26 to 284 degrees Fahrenheit (minus 32 to 140 degrees Celsius)!
The dish spans 5.6 feet (1.7 meters) in diameter, standing about as tall as a refrigerator, yet only weighs 24 pounds (10.9 kilograms) – about as much as a dachshund. Its large size will help Roman send radio signals across a million miles of intervening space to Earth.
At one frequency, the dual-band antenna will receive commands and send back information about the spacecraft’s health and location. It will use another frequency to transmit a flood of data at up to 500 megabits per second to ground stations on Earth. The dish is designed to point extremely accurately at Earth, all while both Earth and the spacecraft are moving through space.
Engineers tested the antenna to make sure it will withstand the spacecraft’s launch and operate as expected in the extreme environment of space. The team also measured the antenna’s performance in a radio-frequency anechoic test chamber. Every surface in the test chamber is covered in pyramidal foam pieces that minimize interfering reflections during testing. Next, the team will attach the antenna to the articulating boom assembly, and then electrically integrate it with Roman’s Radio Frequency Communications System.
Learn more about the exciting science this mission will investigate on Twitter and Facebook.
Make sure to follow us on Tumblr for your regular dose of space!
Roman’s Heat-Vision Eyes Are Complete!
Our Nancy Grace Roman Space Telescope team recently flight-certified all 24 of the detectors the mission needs. When Roman launches in the mid-2020s, the detectors will convert starlight into electrical signals, which will then be decoded into 300-megapixel images of huge patches of the sky. These images will help astronomers explore all kinds of things, from rogue planets and black holes to dark matter and dark energy.
Eighteen of the detectors will be used in Roman’s camera, while another six will be reserved as backups. Each detector has 16 million tiny pixels, so Roman’s images will be super sharp, like Hubble’s.
The image above shows one of Roman’s detectors compared to an entire cell phone camera, which looks tiny by comparison. The best modern cell phone cameras can provide around 12-megapixel images. Since Roman will have 18 detectors that have 16 million pixels each, the mission will capture 300-megapixel panoramas of space.
The combination of such crisp resolution and Roman’s huge view has never been possible on a space-based telescope before and will make the Nancy Grace Roman Space Telescope a powerful tool in the future.
Learn more about the Roman Space Telescope!
Make sure to follow us on Tumblr for your regular dose of space!
Download Software Used to Get Rovers to the Red Planet
Watching our Perseverance rover safely land on the surface of Mars is the kind of historic feat that gets our adventure-loving hearts racing.
Launching and landing rovers on Mars requires overcoming challenges like defying gravity on two planets, surviving the extreme heat of atmospheric entry, and avoiding rocky obstacles. This takes more than just rocket science – it takes incredible software too.
Did you know that some of the same tried and tested software that helped ensure a safe arrival for Perseverance (and its predecessor, Curiosity) can be downloaded – by you...for free...right now?
Our 2021-22 Software Catalog is full of codes made for space that can be used by entrepreneurs, teachers, gamers, or just about anyone. Whether you are curious about the Martian atmosphere, want to visualize the inside of a volcano, or have an application we’ve never even considered, our software may be able to help. Check out our full site, updated regularly with the latest codes available for download.
Here are a few examples of what you could do with our software!
1. Simulate the Martian atmosphere to prepare spacecrafts for landing
To prepare for exactly what a spacecraft will face on landing day, no matter the location scientists choose, we created software that simulates the Martian atmosphere. The code, Mars (GRAM), is now available to anyone.
We also have a version that simulates Earth's atmosphere, allowing users (especially those in the world of drone design) a way to replicate and design for, potentially dangerous conditions without ever stepping away from the computer.
2. Explore the Red Planet virtually from home with help from the Curiosity rover team
Originally developed for scientists and engineers working on the Curiosity rover mission, OnSight allowed the team a virtual way to walk on and look around Mars. Using an immersive display, such as a virtual reality headset, scientists could see the Red Planet the way a rover would.
This software can also be used to provide virtual experiences of places here on Earth, such as caves and lava fields.
3. Dodge disasters with a risk management tool made for space missions
When preparing for complex space missions, like the upcoming Mars Sample Return mission, it’s crucial to examine how different elements, independently and collectively, impact the probability of success.
But risk management has become an important tool for businesses of all disciplines, from engineering to accounting – and the Space Mission Architecture and Risk Analysis Tool (SMART) could help.
Sound interesting? The NASA software catalog has these and more than 800 additional codes ready for download.
You can also follow our Technology Transfer program on Twitter to learn more about software and technology that can be put to use on Earth.
Make sure to follow us on Tumblr for your regular dose of space!
How do you deal with/account for low/no gravity in space (ex. stuff floating around), if it's not a factor of the experiment? (I hope that makes sense? Words are hard)
How long does each project take (approximately) . . . PS: you guys are so awesome >:D
When sending experiments to space, what is the most unexpected thing you have to think about? Like you're probably have to consider things like radiation damage, but what is something that isn't an immediately obvious issue that you have to account for?
What inspired you to attempt a SPOCS project?
Curious about how to send research to the International Space Station or how to get involved with NASA missions as a college student? Ask our experts!
Through our Student Payload Opportunity with Citizen Science, or SPOCS, we’re funding five college teams to build experiments for the International Space Station. The students are currently building their experiments focusing on bacteria resistance or sustainability research. Soon, these experiments will head to space on a SpaceX cargo launch! University of Idaho SPOCS team lead Hannah Johnson and NASA STEM on Station activity manager Becky Kamas will be taking your questions in an Answer Time session on Thurs., June 3, from 12-1 p.m. EDT here on our Tumblr! Make sure to ask your question now by visiting http://nasa.tumblr.com/ask. Hannah Johnson recently graduated from the University of Idaho with a Bachelor of Science in Chemical Engineering. She is the team lead for the university’s SPOCS team, Vandal Voyagers I, designing an experiment to test bacteria-resistant polymers in microgravity. Becky Kamas is the activity manager for STEM on Station at our Johnson Space Center in Houston. She helps connect students and educators to the International Space Station through a variety of opportunities, similar to the ones that sparked her interest in working for NASA when she was a high school student. Student Payload Opportunity with Citizen Science Fun Facts:
Our scientists and engineers work with SPOCS students as mentors, and mission managers from Nanoracks help them prepare their experiments for operation aboard the space station.
The Vandal Voyagers I team has nine student members, six of whom just graduated from the Department of Chemical and Biological Engineering. Designing the experiment served as a senior capstone project.
The experiment tests polymer coatings on an aluminum 6061 substrate used for handles on the space station. These handles are used every day by astronauts to move throughout the space station and to hold themselves in place with their feet while they work.
The University of Idaho’s SPOCS project website includes regular project updates showing the process they followed while designing and testing the experiment.
Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com.
One Step Closer to the Moon with the Artemis Program! 🌙
The past couple of weeks have been packed with milestones for our Artemis program — the program that will land the first woman and the next man on the Moon!
Artemis I will be an integrated, uncrewed test of the Orion spacecraft and Space Launch System (SLS) rocket before we send crewed flights to the Moon.
On March 2, 2021, we completed stacking the twin SLS solid rocket boosters for the Artemis I mission. Over several weeks, workers with NASA's Exploration Ground Systems used one of five massive cranes to place 10 booster segments and nose assemblies on the mobile launcher inside the Vehicle Assembly Building at the Kennedy Space Center (KSC) in Florida.
On March 18, 2021, we completed our Green Run hot fire test for the SLS core stage at Stennis Space Center in Mississippi. The core stage includes the flight computers, four RS-25 engines, and enormous propellant tanks that hold more than 700,000 gallons of super cold propellant. The test successfully ignited the core stage and produced 1.6 million pounds of thrust. The next time the core stage lights up will be when Artemis I launches on its mission to the Moon!
In coming days, engineers will examine the data and determine if the stage is ready to be refurbished, prepared for shipment, and delivered to KSC where it will be integrated with the twin solid rocket boosters and the other rocket elements.
We are a couple steps closer to landing boots on the Moon!
Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com
Local D.C. Artists Celebrate Mary W. Jackson's Legacy
On June 24, 2020, NASA announced the agency’s headquarters building in Washington, D.C., was to be named after Mary W. Jackson to celebrate her life and legacy. We collaborated with Events DC to create artwork inspired by Jackson’s story as the agency’s first Black female engineer.
Take a look at how six local female artists interpreted Jackson’s place in history through their individual creative lenses.
1. Trap Bob
“To see Mary [W.] Jackson be so successful and to get the recognition that she deserves, it hits home for me in a couple ways.”
Tenbeete Solomon AKA Trap Bob is a visual artist, illustrator, and animator based in Washington, D.C.
“Art is so important across the board because it’s really a form of documentation,” says Trap Bob. “It’s creating a form of a history… that’s coming from the true essence of what people feel in the communities.”
2. Jamilla Okubo
“People can relate to things that may seem foreign to them through imagery.”
Jamilla Okubo is an interdisciplinary artist exploring the intricacies of belonging to an American, Kenyan, and Trinidadian identity.
“I wanted to create a piece that represented and celebrated and honored Mary [W.] Jackson, to remember the work that she did,” says Okubo.
3. Tracie Ching
“This is a figure who actually looks like us, represents us.”
Tracie Ching is an artist and self-taught illustrator working in Washington, D.C.
“The heroes and the figures that we had presented to us as kids didn’t ever look like me or my friends or the vast majority of the people around me,” says Ching.
4. Jennifer White-Johnson
"To be even a Black artist making artwork about space — it’s because of her triumphs and her legacy that she left behind.”
Jennifer White-Johnson is an Afro-Latina, disabled designer, educator, and activist whose work explores the intersection of content and caregiving with an emphasis on redesigning ableist visual culture.
“My piece is… a take on autistic joy because my son is autistic," says White-Johnson. "And I really just wanted to show him… in a space where we often don’t see Black disabled kids being amplified.”
5. Kimchi Juice
“In my art, I try to highlight really strong and empowering women."
Julia Chon, better known by her moniker “Kimchi Juice,” is a Washington, D.C.-based artist and muralist.
“As minority women, we are too often overlooked and under recognized for the work and time that we give," says Kimchi Juice. "And so to see Mary W. Jackson finally being given this recognition is fulfilling to me.”
6. OG Lullabies
“I wanted when one listens to it, to feel like there is no limit.”
OG Lullabies is a Washington D.C. songwriter, multi-instrumentalist, including violin and electronics.
“When you look back at history… art is the color or the sound in the emotions that encapsulated the moment,” says OG Lullabies. “It’s the real human experience that happens as time passes.”
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Who Was Mary W. Jackson?
On June 24, 2020, NASA announced the agency’s headquarters building in Washington, D.C., was to be named after Mary W. Jackson, the first African American female engineer at NASA.
Jackson’s story — along with those of her colleagues Katherine Johnson, Dorothy Vaughan, and Christine Darden — was popularized with the release of the “Hidden Figures” movie, based on Margot Lee Shetterly’s book by the same name.
Today, as the accomplishments of these women are brought to light, we celebrate them as Modern Figures — hidden no longer. Despite their recent recognition, we cannot forget the challenges that women and BIPOC faced and continue to face in the STEM fields.
Background
Jackson showed talent for math and science at an early age. She was born in 1921 in Hampton, Virginia, and attended the all-Black George P. Phenix Training School where she graduated with honors. She graduated from Hampton Institute (now Hampton University) in 1942 with a bachelor of science degree in both mathematics and physical sciences.
Jackson worked several jobs before arriving at the National Advisory Committee on Aeronautics (NACA), the precursor organization to NASA. She was a teacher, a receptionist, and a bookkeeper — in addition to becoming a mother — before accepting a position with the NACA Langley Aeronautical Laboratory’s segregated West Area Computers in 1951, where her supervisor was Dorothy Vaughan.
Accomplishments
After two years in West Computing, Jackson was offered a computing position to work in the 4-foot by 4-foot Supersonic Pressure Tunnel. She was also encouraged to enter a training program that would put her on track to become an engineer — however, she needed special permission from the City of Hampton to take classes in math and physics at then-segregated Hampton High School.
She completed the courses, earned the promotion, and in 1958 became NASA’s first African-American female engineer. That same year, she co-authored her first report, “Effects of Nose Angle and Mach Number on Transition on Cones at Supersonic Speeds.” By 1975, she had authored or co-authored 12 NACA and NASA technical publications — most focused on the behavior of the boundary layer of air around an airplane.
Legacy
Jackson eventually became frustrated with the lack of management opportunities for women in her field. In 1979, she left engineering to become NASA Langley’s Federal Women’s Program Manager to increase the hiring and promotion of NASA’s female mathematicians, engineers, and scientists.
Not only was she devoted to her career, Jackson was also committed to the advancement of her community. In the 1970s, she helped the students in the Hampton King Street Community Center build their own wind tunnel and run experiments. She and her husband Levi took in young professionals in need of guidance. She was also a Girl Scout troop leader for more than three decades.
Jackson retired from Langley in 1985. Never accepting the status quo, she dedicated her life to breaking barriers for minorities in her field. Her legacy reminds us that inclusion and diversity are needed to live up to NASA’s core values of teamwork and excellence.
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