NASA’s Hubble Celebrates 21st Anniversary with “Rose” of Galaxies

NASA’s Hubble Celebrates 21st Anniversary with “Rose” of Galaxies

To celebrate the 21st anniversary of the Hubble Space Telescope's deployment into space, astronomers at the Space Telescope Science Institute in Baltimore, Md., pointed Hubble's eye at an especially photogenic pair of interacting galaxies called Arp 273. The larger of the spiral galaxies, known as UGC 1810, has a disk that is distorted into a rose-like shape by the gravitational tidal pull of the companion galaxy below it, known as UGC 1813. This image is a composite of Hubble Wide Field Camera 3 data taken on December 17, 2010, with three separate filters that allow a broad range of wavelengths covering the ultraviolet, blue, and red portions of the spectrum.

To celebrate the 21st anniversary of the Hubble Space Telescope’s deployment into space, astronomers at the Space Telescope Science Institute in Baltimore, Md., pointed Hubble’s eye at an especially photogenic pair of interacting galaxies called Arp 273. The larger of the spiral galaxies, known as UGC 1810, has a disk that is distorted into a rose-like shape by the gravitational tidal pull of the companion galaxy below it, known as UGC 1813. This image is a composite of Hubble Wide Field Camera 3 data taken on December 17, 2010, with three separate filters that allow a broad range of wavelengths covering the ultraviolet, blue, and red portions of the spectrum.

Powered by WPeMatico

Get The Details…
Gary Daines

NASA Invites Media to ‘NASA in the Park’ June 22

NASA Invites Media to ‘NASA in the Park’ June 22

1 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

A blue background has NASA in the Park on it with Orange and White letters. The SLS Rocket graphic and stars appear as well.
Downtown Huntsville Inc.

Media are invited to attend a celebration of space and the Rocket City during NASA in the Park on Saturday, June 22, 10 a.m. to 2 p.m. CDT at Big Spring Park East in Huntsville, Alabama.

NASA and partners will pack the park with exhibits, music, food vendors, and hands-on activities for all ages. This event is free and open to the public.

Joseph Pelfrey, director of NASA’s Marshall Space Flight Center, and local leaders will kick off the program of activities at 10:15 a.m. at the central stage on the south side of the park.

Pelfrey and other NASA team members will be available to speak with reporters between 10:30 and 11 a.m. near the stage.

Reporters interested in interviews should contact Molly Porter, molly.a.porter@nasa.gov or 256-424-5158.

For more information about Marshall, visit:

https://www.nasa.gov/marshall

Molly Porter
Marshall Space Flight Center
256-424-5158
molly.a.porter@nasa.gov

Share

Details

Last Updated

Jun 20, 2024

Powered by WPeMatico

Get The Details…
Beth Ridgeway

Augmented Reality Speeds Spacecraft Construction at NASA Goddard

Augmented Reality Speeds Spacecraft Construction at NASA Goddard

  • Augmented reality tools have helped technicians improve accuracy and save time on fit checks for the Roman Space Telescope being assembled at NASA’s Goddard Space Flight Center in Greenbelt, Maryland.
  • In one instance, manipulating a digital model of Roman’s propulsion system into the real telescope structure revealed the planned design would not fit around existing wiring. The finding helped avoid a need to rebuild any components.
  • The R&D team at Goddard working on this AR project suggests broader adoption in the future could potentially save weeks of construction time and hundreds of thousands of dollars.
people in white, full-body "bunny suits" position hardware in a gleaming metallic clean room at NASA Goddard
In this photograph from Feb. 29, 2024, at NASA’s Goddard Space Flight Center in Greenbelt, Md., the Roman Space Telescope’s propulsion system is positioned by engineers and technicians under the spacecraft bus. Engineers used augmented reality tools to prepare for the assembly.
NASA/Chris Gunn

Technicians armed with advanced measuring equipment, augmented reality headsets, and QR codes virtually checked the fit of some Roman Space Telescope structures before building or moving them through facilities at NASA’s Goddard Space Flight Center in Greenbelt, Maryland.

“We’ve been able to place sensors, mounting interfaces, and other spacecraft hardware in 3D space faster and more accurately than previous techniques,” said NASA Goddard engineer Ron Glenn. “That could be a huge benefit to any program’s cost and schedule.” 

Projecting digital models onto the real world allows the technicians to align parts and look for potential interference among them. The AR heads-up display also enables precise positioning of flight hardware for assembly with accuracy down to thousandths of an inch.

a translucent computer projection of scaffolding is projected into the real environment of a workshop while a person with an AR headset in the background gestures toward a part of the projection
Engineers wearing augmented reality headsets test the placement of a scaffolding design before it is built to ensure accurate fit in the largest clean room at NASA’s Goddard Space Flight Center in Greenbelt, Md.
NASA

Using NASA’s Internal Research and Development program, Glenn said his team keeps finding new ways to improve how NASA builds spacecraft with AR technology in a project aiding Roman’s construction at NASA Goddard. 

Glenn said the team has achieved far more than they originally sought to prove. “The original project goal was to develop enhanced assembly solutions utilizing AR and find out if we could eliminate costly fabrication time,” he said. “We found the team could do so much more.”

For instance, engineers using a robotic arm for precision measuring and 3D laser scanning mapped Roman’s complex wiring harness and the volume within the spacecraft structure.  

“Manipulating the virtual model of Roman’s propulsion assembly into that frame, we found places where it interfered with the existing wiring harness, team engineer Eric Brune said. “Adjusting the propulsion assembly before building it allowed the mission to avoid costly and time-consuming delays.”

Roman’s propulsion system was successfully integrated earlier this year.

The Roman Space Telescope is a NASA mission designed to explore dark energy, exoplanets, and infrared astrophysics.
Equipped with a powerful telescope and advanced instruments, it aims to unravel mysteries of the universe and expand our understanding of cosmic phenomena. Roman is scheduled to launch by May 2027.
Credit: NASA’s Goddard Space Flight Center
Download this video in HD formats from NASA Goddard’s Scientific Visualization Studio

Considering the time it takes to design, build, move, redesign, and rebuild, Brune added, their work saved many workdays by multiple engineers and technicians.

“We have identified many additional benefits to these combinations of technologies,” team engineer Aaron Sanford said. “Partners at other locations can collaborate directly through the technicians’ point of view. Using QR codes for metadata storage and document transfer adds another layer of efficiency, enabling quick access to relevant information right at your fingertips. Developing AR techniques for reverse engineering and advanced structures opens many possibilities such as training and documentation.” 

The technologies allow 3D designs of parts and assemblies to be shared or virtually handed off from remote locations. They also enable dry runs of moving and installing structures as well as help capture precise measurements after parts are built to compare to their designs. 

Adding a precision laser tracker to the mix can also eliminate the need to create elaborate physical templates to ensure components are accurately mounted in precise positions and orientations, Sanford said. Even details such as whether a technician can physically extend an arm inside a structure to turn a bolt or manipulate a part can be worked out in augmented reality before construction. 

During construction, an engineer wearing a headset can reference vital information, like the torque specifications for individual bolts, using a hand gesture. In fact, the engineer could achieve this without having to pause and find the information on another device or in paper documents.  

In the future, the team hopes to help integrate various components, conduct inspections, and document final construction. Sanford said, “it’s a cultural shift. It takes time to adopt these new tools.”  

“It will help us rapidly produce spacecraft and instruments, saving weeks and potentially hundreds of thousands of dollars,” Glenn said. “That allows us to return resources to the agency to develop new missions.” 

This project is part of NASA’s Center Innovation Fund portfolio for fiscal year 2024 at Goddard. The Center Innovation Fund, within the agency’s Space Technology Mission Directorate, stimulates and encourages creativity and innovation at NASA centers while addressing the technology needs of NASA and the nation.

To learn more, visit: https://www.nasa.gov/center-innovation-fund/

By Karl B. Hille
NASA’s Goddard Space Flight Center, Greenbelt, Md.

Share

Details

Last Updated

Jun 20, 2024

Editor
Rob Garner
Contact
Rob Garner
Location
Goddard Space Flight Center

Powered by WPeMatico

Get The Details…
Karl B. Hille

Why Scientists Are Intrigued by Air in NASA’s Mars Sample Tubes

Why Scientists Are Intrigued by Air in NASA’s Mars Sample Tubes

5 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

NASA’s Perseverance rover viewed these dust devils
NASA’s Perseverance rover viewed these dust devils swirling across the surface of Mars on July 20, 2021. Scientists want to study the air trapped in samples being collected in metal tubes by Perseverance. Those air samples could help them better understand the Martian atmosphere.
NASA/JPL-Caltech

Tucked away with each rock and soil sample collected by the agency’s Perseverance rover is a potential boon for atmospheric scientists.

Atmospheric scientists get a little more excited with every rock core NASA’s Perseverance Mars rover seals in its titanium sample tubes, which are being gathered for eventual delivery to Earth as part of the Mars Sample Return campaign. Twenty-four have been taken so far.

Most of those samples consist of rock cores or regolith (broken rock and dust) that might reveal important information about the history of the planet and whether microbial life was present billions of years ago. But some scientists are just as thrilled at the prospect of studying the “headspace,” or air in the extra room around the rocky material, in the tubes.

They want to learn more about the Martian atmosphere, which is composed mostly of carbon dioxide but could also include trace amounts of other gases that may have been around since the planet’s formation.

“The air samples from Mars would tell us not just about the current climate and atmosphere, but how it’s changed over time,” said Brandi Carrier, a planetary scientist at NASA’s Jet Propulsion Laboratory in Southern California. “It will help us understand how climates different from our own evolve.”

The Value of Headspace

Among the samples that could be brought to Earth is one tube filled solely with gas deposited on the Martian surface as part of a sample depot. But far more of the gas in the rover’s collection is within the headspace of rock samples. These are unique because the gas will be interacting with rocky material inside the tubes for years before the samples can be opened and analyzed in laboratories on Earth. What scientists glean from them will lend insight into how much water vapor hovers near the Martian surface, one factor that determines why ice forms where it does on the planet and how Mars’ water cycle has evolved over time.

Scientists also want a better understanding of trace gases in the air at Mars. Most scientifically tantalizing would be the detection of noble gases (such as neon, argon, and xenon), which are so nonreactive that they may have been around, unchanged in the atmosphere, since forming billions of years ago. If captured, those gases could reveal whether Mars started with an atmosphere. (Ancient Mars had a much thicker atmosphere than it does today, but scientists aren’t sure whether it was always there or whether it developed later). There are also big questions about how the planet’s ancient atmosphere compared with early Earth’s.

The headspace would additionally provide a chance to assess the size and toxicity of dust particles — information that will help future astronauts on Mars.

“The gas samples have a lot to offer Mars scientists,” said Justin Simon, a geochemist at NASA’s Johnson Space Center in Houston, who is part of a group of over a dozen international experts that helps decide which samples the rover should collect. “Even scientists who don’t study Mars would be interested because it will shed light on how planets form and evolve.”

Apollo’s Air Samples

In 2021, a group of planetary researchers, including scientists from NASA, studied the air brought back from the Moon in a steel container by Apollo 17 astronauts some 50 years earlier.

“People think of the Moon as airless, but it has a very tenuous atmosphere that interacts with the lunar surface rocks over time,” said Simon, who studies a variety of planetary samples at Johnson. “That includes noble gases leaking out of the Moon’s interior and collecting at the lunar surface.”

The way Simon’s team extracted the gas for study is similar to what could be done with Perseverance’s air samples. First, they put the previously unopened container into an airtight enclosure. Then they pierced the steel with a needle to extract the gas into a cold trap — essentially a U-shaped pipe that extends into a liquid, like nitrogen, with a low freezing point. By changing the temperature of the liquid, scientists captured some of the gases with lower freezing points at the bottom of the cold trap.

“There’s maybe 25 labs in the world that manipulate gas in this way,” Simon said. Besides being used to study the origin of planetary materials, this approach can be applied to gases from hot springs and those emitted from the walls of active volcanoes, he added.

Of course, those sources provide much more gas than Perseverance has in its sample tubes. But if a single tube doesn’t carry enough gas for a particular experiment, Mars scientists could combine gases from multiple tubes to get a larger aggregate sample — one more way the headspace offers a bonus opportunity for science.

More About the Mission

A key objective for Perseverance’s mission on Mars is astrobiology, including the search for signs of ancient microbial life. The rover is also characterizing the planet’s geology and past climate, which paves the way for human exploration of the Red Planet. JPL, which is managed for NASA by Caltech in Pasadena, California, built and manages operations of the Perseverance rover.

For more about Perseverance:

mars.nasa.gov/mars2020/

News Media Contacts

Andrew Good
Jet Propulsion Laboratory, Pasadena, Calif.
818-393-2433
andrew.c.good@jpl.nasa.gov

Karen Fox / Charles Blue
NASA Headquarters, Washington
202-285-1600 / 202-802-5345
karen.c.fox@nasa.gov / charles.e.blue@nasa.gov

2024-087

Powered by WPeMatico

Get The Details…
Anthony Greicius

NASA CubeSats Loaded for Launch

NASA CubeSats Loaded for Launch

A Satellite for Optimal Control and Imaging (SOC-i) CubeSat awaits integration at Firefly’s Payload Processing Facility at Vandenberg Space Force Base, California on Thursday, June 6, 2024. SOC-i, along with several other CubeSats, will launch to space on an Alpha rocket during NASA’s Educational Launch of Nanosatellites (ELaNa) 43 mission as part of the agency’s CubeSat Launch Initiative and Firefly’s Venture-Class Launch Services Demonstration 2 contract.
Photo credit: NASA

Eight CubeSats that are part of NASA’s CubeSat Launch Initiative have been integrated into Firefly Aerospace’s deployment hardware and are ready to be encapsulated into the payload fairing of Firefly’s Alpha rocket. The launch, named “Noise of Summer,” will lift off early this summer from Space Launch Complex 2 at Vandenberg Space Force Base in California. 

University students from several schools, along with some technicians from NASA, brought their small satellites to Firefly for integration with the rocket. The satellites are designed to perform a range of scientific experiments and technical demonstrations including high-speed communications, cosmic ray detection, climate monitoring, and new de-orbiting techniques. 

The CubeSats on the ELaNa 43 (Educational Launch of a Nanosatellite) manifest are: 

  • CatSat – University of Arizona, Tucson, Arizona 
  • KUbe-Sat-1 – University of Kansas, Lawrence, Kansas 
  • MESAT1 – University of Maine, Orono, Maine 
  • R5-S4 – NASA’s Johnson Space Center, Houston, Texas 
  • R5-S2-2.0 – NASA’s Johnson Space Center, Houston 
  • SOC-i – University of Washington, Seattle, Washington 
  • TechEdSat-11 – NASA’s Ames Research Center, California’s Silicon Valley 
  • Serenity – Teachers in Space  

Students are heavily involved in all aspects of their mission from developing, assembling, and testing payloads to working with NASA and the launch vehicle integration teams. The CubeSats are held to rigorous standards like that of the primary spacecraft.  

Firefly Aerospace is one of three companies selected under NASA’s Launch Services Program Venture-Class Launch Services Demonstration 2 (VCLS Demo 2) contract awarded in December 2020. These VCLS Demo 2 missions can tolerate a higher level of risk and help create opportunities for new launch vehicles, helping grow the launch vehicle market while increasing access to space for small spacecraft and science missions. 

Powered by WPeMatico

Get The Details…
Laura Aguiar