NASA’s Roman Mission Gears Up for a Torrent of Future Data

NASA’s Roman Mission Gears Up for a Torrent of Future Data

NASA’s Nancy Grace Roman Space Telescope team is exploring ways to support community efforts that will prepare for the deluge of data the mission will return. Recently selected infrastructure teams will serve a vital role in the preliminary work by creating simulations, scouting the skies with other telescopes, calibrating Roman’s components, and much more.

Their work will complement additional efforts by other teams and individuals around the world, who will join forces to maximize Roman’s scientific potential. The goal is to ensure that, when the mission launches by May 2027, scientists will already have the tools they need to uncover billions of cosmic objects and help untangle mysteries like dark energy.

“We’re harnessing the science community at large to lay a foundation, so when we get to launch we’ll be able to do powerful science right out of the gate,” said Julie McEnery, Roman’s senior project scientist at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “There’s a lot of exciting work to do, and many different ways for scientists to get involved.”

Thousands of tiny red dots speckle a black background like spilled salt. Additional yellow blobs that are slightly larger and appear more like galaxies, are overlaid on top and a few areas appear to bloom outward and slightly warp. Then even more galaxies, this time yellow and white, are overlaid over that, and the other areas "bloom" with even more exaggerated effects, the edges of the circular areas appearing to be smeared into arcs and streaks while the inside of the areas are magnified.
This animation shows a simulation of the type of science that astronomers will be able to do with future deep field observations from NASA’s Nancy Grace Roman Space Telescope. The gravity of intervening galaxy clusters and dark matter can lens the light from farther objects, warping their appearance as shown in the animation. By studying the distorted light, astronomers can study elusive dark matter, which can only be measured indirectly through its gravitational effects on visible matter. As a bonus, this lensing also makes it easier to see the most distant galaxies whose light they magnify. Simulations like this one help astronomers understand what Roman’s future observations could tell us about the universe, and provide useful data to validate data analysis techniques.
Credit: Caltech-IPAC/R. Hurt

Simulations lie at the heart of the preparatory efforts. They enable scientists to test algorithms, estimate Roman’s scientific return, and fine-tune observing strategies so that we’ll learn as much as possible about the universe.

Teams will be able to sprinkle different cosmic phenomena through a simulated dataset and then run machine learning algorithms to see how well they can automatically find the phenomena. Developing fast and efficient ways to identify underlying patterns will be vital given Roman’s enormous data collection rate. The mission is expected to amass 20,000 terabytes (20 petabytes) of observations containing trillions of individual measurements of stars and galaxies over the course of its five-year primary mission.

“The preparatory work is complex, partly because everything Roman will do is quite interconnected,” McEnery said. “Each observation is going to be used by multiple teams for very different science cases, so we’re creating an environment that makes it as easy as possible for scientists to collaborate.”

Some scientists will conduct precursor observations using other telescopes, including NASA’s Hubble Space Telescope, the Keck Observatory in Hawaii, and Japan’s PRIME (Prime-focus Infrared Microlensing Experiment) located in the South African Astronomical Observatory in Sutherland. These observations will help astronomers optimize Roman’s observing plan by identifying the best individual targets and regions of space for Roman and better understand the data the mission is expected to deliver.

Some teams will explore how they might combine data from different observatories and use multiple telescopes in tandem. For example, using PRIME and Roman together would help astronomers learn more about objects found via warped space-time. And Roman scientists will be able to lean on archived Hubble data to look back in time and see where cosmic objects were and how they were behaving, building a more complete history of the objects astronomers will use Roman to study. Roman will also identify interesting targets that observatories such as NASA’s James Webb Space Telescope can zoom in on for more detailed studies.

A series of images showing wispy stellar streams surrounding eight individual galaxies. Light and dark are reversed so that the background is gray-white and the galaxies appear as black blobs. Extending out from each like tentacles are streams of stars.
This series of images shows how astronomers find stellar streams by reversing the light and dark, similar to negative images, but stretched to highlight the faint streams. Color images of each of the nearby galaxies featured are superposed to scale to highlight the easily visible disk. Galaxies are surrounded by enormous halos of hot gas sprinkled with sporadic stars, seen as the shadowy regions that encase each galaxy here. NASA’s upcoming Nancy Grace Roman Space Telescope is expected to improve on these observations by resolving individual stars to understand each stream’s stellar populations and see stellar streams of various sizes in even more galaxies.
Credit: Carlin et al. (2016), based on images from Martínez-Delgado et al. (2008, 2010)

It will take many teams working in parallel to plan for each Roman science case. “Scientists can take something Roman will explore, like wispy streams of stars that extend far beyond the apparent edges of many galaxies, and consider all of the things needed to study them really well,” said Dominic Benford, Roman’s program scientist at NASA Headquarters in Washington, D.C. “That could include algorithms for dim objects, developing ways to measure star positions very precisely, understanding how detector effects could influence the observations and knowing how to correct for them, coming up with the most effective strategy to image stellar streams, and much more.”

One group is developing processing and analysis software for Roman’s Coronagraph Instrument. This instrument will demonstrate several cutting-edge technologies that could help astronomers directly image planets beyond our solar system. This team will also simulate different objects and planetary systems the Coronagraph could unveil, from dusty disks surrounding stars to old, cold worlds similar to Jupiter.

The mission’s science centers are gearing up to manage Roman’s data pipeline and archive and establishing systems to plan and execute observations. As part of a separate, upcoming effort, they will convene a survey definition team that will take in all of the preparatory information scientists are generating now and all the interests from the broader astronomical community to determine Roman’s optimal observation plans in detail.

“The team is looking forward to coordinating and funneling all the preliminary work,” McEnery said. “It’s a challenging but also exciting opportunity to set the stage for Roman and ensure each of its future observations will contribute to a wealth of scientific discoveries.”

The Nancy Grace Roman Space Telescope is managed at NASA’s Goddard Space Flight Center in Greenbelt, Maryland, with participation by NASA’s Jet Propulsion Laboratory and Caltech/IPAC in Southern California, the Space Telescope Science Institute in Baltimore, and a science team comprising scientists from various research institutions. The primary industrial partners are Ball Aerospace and Technologies Corporation in Boulder, Colorado; L3Harris Technologies in Melbourne, Florida; and Teledyne Scientific & Imaging in Thousand Oaks, California.

By Ashley Balzer
NASA’s Goddard Space Flight Center, Greenbelt, Md.

Media contact:

Claire Andreoli
NASA’s Goddard Space Flight Center, Greenbelt, Md.
301-286-1940

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Ashley Balzer

Evolution Space to Produce and Test Solid Rocket Motors at NASA Stennis

Evolution Space to Produce and Test Solid Rocket Motors at NASA Stennis

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Evolution Space to Produce and Test Solid Rocket Motors at NASA Stennis

NASA’s Stennis Space Center near Bay St. Louis, Mississippi, joined with Evolution Space on Oct. 10 to announce plans for the aerospace company to establish production and testing operations for solid rocket motors onsite.

“This is another great addition to south Mississippi’s commercial space engagement,” Center Director Dr. Rick Gilbrech said. “Evolution Space gains access to critical NASA Stennis infrastructure and expertise as it continues to build its propulsion capabilities. In turn, we continue frontline work with commercial companies as we support NASA’s commitment to increase access to space and grow our federal city. We look forward to working with Evolution Space.”

The announcement grants access for Evolution Space to establish its Minor Scale Propulsion Center, while also opening the door to a larger future presence at the center. It also marks the first time in NASA Stennis’ 62-year history to support production and testing of solid rocket motors, and continues the center’s efforts to maximize use of its unique location, operating model, and propulsion infrastructure and capabilities by commercial aerospace companies and others.

“By partnering with NASA, we are able to rapidly stand up a facility which will add considerable capability to the US solid rocket motor industrial base,” said Manny Ballestero, a U.S. Army veteran and Evolution Space vice president of production and development. “We look forward to the future of our partnership as we continue to expand our presence at Stennis.”

Under the arrangement, Evolution Space gains access to previously vacant NASA Stennis facilities to mix, cast, and store propellants. The company’s production facility is expected to be operational by spring 2024. It also will use the E-3 Test Complex at NASA Stennis to conduct solid rocket motor hot fires onsite for the first time. Evolution Space will provide all equipment, components, and electrical systems needed for a blended team of company and NASA personnel to test the motors.

“Evolution Space is moving fast and scaling with purpose,” added Josh Marino, U.S. Navy veteran and vice president of operations at Evolution Space. “We see our collaboration with the NASA Stennis propulsion center as a strategic expansion to help meet the growing demands of both the commercial and defense sectors.”

The news represents the latest collaboration between NASA Stennis and a commercial aerospace company. The nation’s largest propulsion test site, NASA Stennis features a secure setting and 125,000-acre acoustical buffer zone that enables 365/24/7 operations and testing. Historically, the site has supported propulsion projects that use liquid fuels and oxidizers as propellants. For solid rocket motors, fuel and oxidizer are mixed together into a solid propellant.

“This is an exciting agreement for NASA Stennis,” said Duane Armstrong, manager of the NASA Stennis Strategic Business Development Office. “It is yet another demonstration of the value of the center and its ability to support a range of commercial aerospace companies.”

For information about Stennis Space Center, visit: www.nasa.gov/centers/stennis/.

C. Lacy Thompson
Stennis Space Center, Bay St. Louis, Mississippi
228-363-5499
calvin.l.thompson@nasa.gov

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Oct 10, 2023

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LaToya Dean

Tracing the Origin and Energization of Plasma inthe Heliosphere

Tracing the Origin and Energization of Plasma inthe Heliosphere

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Tracing the Origin and Energization of Plasma inthe Heliosphere

An artist’s depiction of dark starry background with the Sun in the upper right corner, the Earth in the center, and a circular spacecraft in the bottom left corner. Gold lines stream away from the Sun on all directions, colliding with Earth.
Credits:
Stephen Alvey, University of Michigan

PROJECT:

Solar Wind Pickup Ion Composition Energy Spectrometer (SPICES)

SNAPSHOT:

SPICES is a new sensor that will help scientists discover where matter originates and how it is energized throughout the solar system

An artist’s depiction of dark starry background with the Sun in the upper right corner, the Earth in the center, and a circular spacecraft in the bottom left corner. Gold lines stream away from the Sun on all directions, colliding with Earth.
SPICES will measure plasma in space and trace its origin back to the Sun, planetary atmospheres, comet tails, and interstellar space.
Credits: Stephen Alvey, University of Michigan

Imagine that you have a secret decoder ring that you can use to decipher a secret message with important clues about things around you: where they came from, why they are there, and what will become of them in the future. Now imagine that the secret decoder ring is actually a sensor that can be flown in space to unravel secrets about the matter in the solar system. Where did this matter originate, how did it become energized, and how could it impact humans living on Earth and traveling in space? SPICES is like a decoder ring for the plasma (gas consisting of electrically charged particles) in the solar system. It has the potential to reveal important information about how the Sun behaves and interacts with planets and their atmospheres, and how the solar system is impacted by its own motion through interstellar space. 

The universe is mostly made of hydrogen, but the elements that make up life as well as the planets, comets, and many other celestial bodies are heavier than hydrogen. In fact, these heavier elements, although not as abundant, can hold the key to understanding how numerous processes in the universe work. In our solar system, these “heavy elements”—which are called “heavy ions” when they are electrically charged—can help us trace plasma to its origin at planets, comets, the Sun and solar atmosphere, and even to interstellar space. 

Heavy ions are an important piece of the puzzle that describes how the solar system supports and sustains life. They also play a role in large eruptions on the Sun that cause solar storms. For example, solar flares that emit vast amounts of X-rays are mostly due to excitation of heavy ions on the Sun. Being able to predict and prepare for solar storms is important to keep humans and robotics safe on space missions. SPICES will enable us to better understand how these solar storms form by giving scientists information about how eruptions on the Sun occur and how they accelerate plasma. With this information, scientists can better predict when and how severe solar storms will be. 

SPICES is designed to measure the chemical makeup of electrically charged streams of particles (also called wind) that blow in space. SPICES will measure the solar wind—the wind that blows away from the Sun, including the wind that results from the most severe solar storms. It will also measure neutral wind that blows into the solar system from interstellar space and becomes charged as it encounters the Sun, and wind that blows off planetary surfaces and out of planetary atmospheres. Measuring the chemical composition of these streams of particles can help us understand how the solar system was created, its behavior today, and how it will behave in the future. 

SPICES is optimized to detect less common heavy ions—like low-charge ions and isotopes—that are not well measured by current spaceborne sensors. The SPICES design incorporates a novel and state-of-the-art method of boosting the energy of incoming ions so that their fingerprints can be more clearly identified, allowing the abundance and variability of these rare species to be accurately measured. Some of these rarer species are only found inside solar storms and can change how these storms interact with Earth’s space environment. 

But boosting the energy of these incoming ions is challenging; it must be done safely, without putting the SPICES electronics or other instruments at risk, and without heating the sensor up too much.  The methods used on SPICES to boost the ion energy are based on traditional methods, but the new design can boost the ion energy 60% higher than prior space sensors by stepping up the energy one stage at a time to reach the maximum level desired. The design also incorporates a protective bubble to shield electronics and other onboard systems from the high energy ions generated by SPICES.  SPICES will soon be ready to fly on upcoming missions that study the global behavior of the Sun, planetary atmospheres, monitor space weather, or fly out to the edges of the solar system into interstellar space. 

This engineering challenge is being tackled by engineers at the University of Michigan Space Physics Research Laboratory, with contributions from Southwest Research Institute in Texas.  The sensor’s original design was a result of collaboration of scientists at the University of Michigan including Dr. George Gloeckler, one of the pioneers of space-based ion mass spectrometers; Professor Susan Lepri; Dr. Jason Gilbert; and Associate Professor Jim Raines. 

PROJECT LEAD:

Professor Susan Lepri, The University of Michigan

SPONSORING ORGANIZATION

Heliophysics Strategic Technology Office (HESTO)

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Five Tips for Photographing the Annular Solar Eclipse on Oct. 14

Five Tips for Photographing the Annular Solar Eclipse on Oct. 14

3 min read

Five Tips for Photographing the Annular Solar Eclipse on Oct. 14

A woman, seen from the torso up, stands on a beach. She is wearing white solar viewing glasses and has a camera strap around her neck.
Sarah Baker views the partial solar eclipse as the sun rises, Thursday, June 10, 2021, at Lewes Beach in Delaware.
NASA/Aubrey Gemignani

An annular solar eclipse is crossing the Americas on Oct. 14, 2023. This astronomical event is a perfect opportunity to capture unforgettable images of the Moon “taking a bite” out of the Sun or creating a “ring of fire” effect in the sky. Whether you’re an amateur photographer or a selfie master, try out these tips for photographing the eclipse. 

#1 – Safety First

To take images as the Sun is being eclipsed, you’ll need to use a special solar filter to protect your camera, just as you’ll need a pair of eclipse glasses to protect your own eyes. 

Having a few other pieces of equipment can also come in handy during the eclipse. Using a tripod can help you stabilize the camera and avoid taking blurry images during the low lighting. Additionally, using a delayed shutter release timer will allow you to snap shots without jiggling the camera.

#2 – Any Camera Is a Good Camera

Taking a stunning photo has more to do with the photographer than the camera. Whether you have a high-end DSLR, or a camera phone, you can take great photos during the eclipse; after all, the best piece of equipment you can have is a good eye and a vision for the image you want to create. If you don’t have a telephoto zoom lens, focus on taking landscape shots, which capture the changing environment.

Trees line the landscape. On the right, a camera sits on a tripod. Two hands hold either side of the camera.
A safe solar filter must be used in front of a camera lens whenever photographing an annular solar eclipse or a partial solar eclipse. Putting the camera on a tripod will help stabilize the view and produce clearer photos.
Danny B. Thomas

#3 – Look Up, Down, All Around

While the Sun is the most commanding element of an eclipse, remember to look around you. As the Moon slips in front of the Sun, the landscape will be bathed in long shadows, creating eerie lighting across the landscape. Light filtering through the overlapping leaves of trees create natural pinholes, which will also create mini eclipse replicas on the ground. Everywhere you can point your camera can yield exceptional imagery, so be sure to compose some wide-angle photos that can capture your eclipse experience.

NASA photographer Bill Ingalls recommends focusing on the human experience of watching the eclipse. “The real pictures are going to be of the people around you pointing, gawking, and watching it,” Ingalls noted. “Those are going to be some great moments to capture to show the emotion of the whole thing.”

#4 – Practice

Be sure you know the capabilities of your camera before eclipse day. Most cameras, and even many camera phones, have adjustable exposures, which can help you darken or lighten your image during the tricky eclipse lighting. Make sure you know how to manually focus the camera for crisp shots.

For DSLR cameras, the best way to determine the correct exposure is to test settings on the uneclipsed Sun beforehand. Using a fixed aperture of f/8 to f/16, try shutter speeds between 1/1000 to 1/4 second to find the optimal setting, which you can then use to take images during the partial or annular stages of the eclipse.

#5 – Share!

Share your eclipse experience with friends and family afterwards. Tag @NASA to connect your photos on social media to those taken around the country and share them with NASA. 

While you’re out perfecting your perfect eclipse shot, don’t forget to stop and look at the eclipse with your own eyes. Just remember to wear your solar viewing glasses (or “eclipse glasses”) throughout the entire eclipse!

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International Space Station Operations Update

International Space Station Operations Update

At approximately 1 p.m. EDT Oct. 9, NASA flight controllers in mission control at the agency’s Johnson Space Center in Houston, using cameras on the International Space Station exterior, observed flakes emanating from one of two radiators on the Roscosmos Nauka Multipurpose Laboratory Module (MLM) at the orbital complex. The flight control team informed the crew aboard the space station of the potential leak, and NASA astronaut Jasmin Moghbeli confirmed the presence of the flakes from the cupola windows, after which the crew was asked to close the shutters on U.S. segment windows as a precaution against contamination.

The crew aboard station was never in any danger.

Roscosmos confirmed that the observed leak is on Nauka’s backup radiator, which is mounted to the outside of the module. The radiator was delivered to the space station on the Rassvet module during space shuttle mission STS-132 in 2010. It was transferred to the Nauka during a Roscosmos spacewalk in April. The primary radiator on Nauka is working normally, providing full cooling to the module with no impacts to the crew or to space station operations.

Teams on the ground will continue to investigate the cause of the leak, and additional updates will be made as available.

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Victoria Ugalde