Giant Batteries Deliver Renewable Energy When It’s Needed

Giant Batteries Deliver Renewable Energy When It’s Needed

2 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

A scientist standing next to a demonstration unit of a redox flow battery
In developing its flow battery, ESS drew from groundbreaking research and development conducted by the space agency more than 40 years ago. Pictured here, a 200-watt demonstration unit of the flow battery NASA built in the 1970s and 1980s.
Credit: NASA

Solar power is abundant – when the Sun is shining. Wind power is steady – when the wind is blowing. However, creating a steady electricity supply from intermittent power sources is a challenge. NASA was focused on this problem more than 45 years ago when the agency designed a new type of liquid battery during the energy price shocks of the 1970s. While engineers continued over the following decades to develop flow batteries, as they’re now called, the technology has drawn even more attention in recent years, with the urgency of climate change powering a larger-scale transition to renewables like solar and wind.

It’s fair to say that flow batteries today owe something to the major push the technology received in the 1970s when a NASA team of chemical, electrical, and mechanical engineers developed an iron-chromium flow battery at Lewis Research Center – now Glenn Research Center – in Cleveland.

The NASA system involved two tanks of liquid electrolyte solutions, one infused with iron chloride and the other with chromium chloride. These electrolytes were pumped through the battery cell, triggering a chemical reaction through a membrane that separated the two solutions inside the battery. During charge, electrical energy was converted to chemical energy and stored in the electrolyte liquid. To discharge the energy, the process was reversed.

ESS Flow batteries built into a shipping container being moved with a crane.
ESS flow batteries enable a steady supply of electricity from intermittent energy sources, such as wind and solar. They store up to 12 hours of energy and discharge it when needed. They can be built in shipping containers, like the one being installed in the picture here, or larger installations can be housed in a building.
Credit: ESS Inc.

Wilsonville, Oregon-based ESS Inc. built on NASA’s early work as the company developed its own flow batteries using only iron, salt, and water.  When the ESS team began developing its battery in 2011, the company founders wanted to use iron as NASA had. They found they could pair iron with a simple salt solution, which was cheaper to obtain and easier to work with than the chromium mixture NASA had used.

ESS flow batteries are designed for power grids that are increasingly powered by intermittent wind and solar generation. The company’s systems store up to 12 hours of energy and are used to provide backup power to critical community facilities.

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Andrew Wagner

A Bright New Abrasion

A Bright New Abrasion

2 min read

A Bright New Abrasion

Images of large rocks on Mars. NASA's Mars Perseverance rover acquired this image using its Right Mastcam-Z camera. Mastcam-Z is a pair of cameras located high on the rover's mast.
This image was acquired by the Front Right Hazard Avoidance Camera A on June 16, 2024 (Sol 1181) at the local mean solar time of 14:20:10. The image shows the area in front of the rover at Bright Angel with the arm extended as the PIXL instrument investigates the surface.
NASA/JPL-Caltech

Last week, Perseverance arrived at the long-awaited site of Bright Angel, named for being a light-toned rock that stands out in orbital data. The unique color here, as well as the surface characteristics and location on the edge of the ancient river channel Neretva Vallis, made Bright Angel a location of interest for the Mars 2020 Science Team.

After capturing some stunning long-distance images of Bright Angel, Perseverance made the approach to the rocks. Closer camera images, Mastcam-Z, and SuperCam data showed intriguing surface textures on these light-toned rocks that the Science Team is actively working to understand.

After a few days to process the beautiful images and exciting location, Perseverance executed a planned abrasion on the rocks in front of the rover, which can be seen in the above image if you look closely underneath the rover’s arm. This abrasion patch is named “Walhalla Glades” after an ancient archeological site in the Grand Canyon along the Colorado River, a tribute to Bright Angel’s location on the edge of the ancient Neretva Vallis river channel.

Proximity science instruments were deployed to look at the abrasion patch in detail and provide high-resolution geochemical data of these rocks. In the Hazard Avoidance Camera image above, the PIXL instrument is pointed down at the abrasion patch on the rock surface as it performs a scan.

The Science Team will take time to understand all the new data obtained at Bright Angel, comparing it to the past rocks Perseverance has investigated and determining if the area should be included in the sample cache onboard Perseverance. Characterizing the rocks of Bright Angel, connecting them to the surrounding rocks and sediment of Neretva Vallis, and placing them in context with the Crater Rim and Margin units should write an exciting chapter of the history of Jezero crater!

Written by Eleanor Moreland, Ph.D. Student Collaborator at Rice University

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Jun 20, 2024

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NASA Engineer Honored as Girl Scouts ‘Woman of Distinction’

NASA Engineer Honored as Girl Scouts ‘Woman of Distinction’

4 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

A woman wearing glasses and a blue patterned shirt and green sweater smiles at the camera as she stands in front of a green banner that says, “Girl Scouts of North East Ohio.”
Danielle Koch, an aerospace engineer at NASA’s Glenn Research Center in Cleveland, was honored by the Girl Scouts of North East Ohio as a 2024 Woman of Distinction. She accepted the award during a ceremony on May 16.
Credit: Girl Scouts of North East Ohio/Andrew Jordan

You’d think a NASA aerospace engineer who spends her days inside a giant dome researching how to make plane engines quieter and spacecraft systems more efficient would have a pretty booked schedule. Still, advocacy and mentoring, especially for women and girls in STEM, is something Danielle Koch always tries to say yes to.

For decades, Koch has tutored students, volunteered as a mentor for engineering challenges, and engaged Pre-K through Ph.D. classes with stories from her career at NASA’s Glenn Research Center in Cleveland. Koch also works to recruit women and others from underrepresented groups to the field and find ways to remove barriers to their advancement.

For her efforts, Koch was recently recognized by the Girl Scouts of North East Ohio as a 2024 Woman of Distinction. The award, presented to Koch during a ceremony on May 16, celebrates women whose leadership contributes to the community, providing girls with positive role models. Koch says that diverse people and programs have similarly shaped her own career path.

“None of this is anything I’ve done myself; there are huge groups of people who are making change and making things better for all of us,” Koch said. “Every story I tell about me being a woman at NASA is really a story about them.”

: A man and a woman wearing masks work on equipment inside a NASA acoustic facility. Large tan fiberglass wedges line the walls of the facility.
Danielle Koch (right) is an aerospace engineer in the Acoustics Branch at NASA’s Glenn Research Center in Cleveland, where she works to make flight quieter and spacecraft systems more efficient.
Credit: NASA/Jef Janis

A Pittsburgh native and graduate of Case Western Reserve University, Koch began her career as a test engineer at NASA Glenn in 1990 as the only woman in her work group. While there were women around her, Koch says she did not see many senior-level female engineers or scientists “working ahead of her.” With determination and the “rock-solid” support of colleagues, family, and friends, Koch forged ahead, becoming a research aerospace engineer in NASA Glenn’s Acoustics Branch in 1998.

“She’s somebody that goes above and beyond almost all of the time, while using her knowledge and career to bring others up to her level,” said John Lucero, Koch’s supervisor and the chief of the Acoustics Branch at NASA Glenn.

Koch realized the landscape around her was evolving in 2016 when she sat down in one of NASA Glenn’s biggest conference rooms for the center’s annual Women Ignite workshop. It was the first time she’d seen the space entirely filled with women.

“It was striking,” Koch said. “Learning from each other and being visible to each other, it’s so huge.”

Koch points to insights gleaned from these workshops — which are focused on networking, skill-building, and empowerment — as propelling her forward, along with the center’s Women in STEM Leadership Development Program, launched to help the women of NASA Glenn connect and grow as leaders.

NASA Glenn Research Center aerospace engineer Danielle Koch gives a tour of the Aero-Acoustic Propulsion Laboratory to a group of students in 2017.
Credit: NASA/Marvin Smith

Koch also spotlights the value of the Women at Glenn employee resource group, which organizes events and panels, shares job and volunteer opportunities, and provides a platform for addressing issues in the workplace.

“The employee resource group offers a great sense of community for women at the center,” said Women at Glenn co-chair and aerospace engineer Christine Pastor-Barsi. “When you feel like you’re unique, it’s good to know that there are others out there like you, even if you don’t always see them in the room.”

Koch says she’ll continue working as a mentor in the community and advocating for the diverse range of people who choose to take the leap into the STEM fields.

“It’s difficult to be the only one that’s visibly different in a room; it changes the way you communicate, the way you’re perceived,” Koch said. “It’s really important to reach out to people who are different from us and invite them to consider engineering as a career. We all benefit when we work with someone who’s different from ourselves.”

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Ellen Bausback

NASA’s Chandra Peers Into Densest and Weirdest Stars

NASA’s Chandra Peers Into Densest and Weirdest Stars

This is an image of the leftovers from an exploded star called 3C 58, shown in X-ray and optical light. At the center of the remnant is a rapidly spinning neutron star, called a pulsar, that presents itself as a bright white object that's somewhat elongated in shape.
Supernova remnant 3C 58.
X-ray: NASA/CXC/ICE-CSIC/A. Marino et al.; Optical: SDSS; Image Processing: NASA/CXC/SAO/J. Major

The supernova remnant 3C 58 contains a spinning neutron star, known as PSR J0205+6449, at its center. Astronomers studied this neutron star and others like it to probe the nature of matter inside these very dense objects. A new study, made using NASA’s Chandra X-ray Observatory and ESA’s XMM-Newton, reveals that the interiors of neutron stars may contain a type of ultra-dense matter not found anywhere else in the Universe.

In this image of 3C 58, low-energy X-rays are colored red, medium-energy X-rays are green, and the high-energy band of X-rays is shown in blue. The X-ray data have been combined with an optical image in yellow from the Digitized Sky Survey. The Chandra data show that the rapidly rotating neutron star (also known as a “pulsar”) at the center is surrounded by a torus of X-ray emission and a jet that extends for several light-years. The optical data shows stars in the field.

The team in this new study analyzed previously released data from neutron stars to determine the so-called equation of state. This refers to the basic properties of the neutron stars including the pressures and temperatures in different parts of their interiors.

The authors used machine learning, a type of artificial intelligence, to compare the data to different equations of state. Their results imply that a significant fraction of the equations of state — the ones that do not include the capability for rapid cooling at higher masses — can be ruled out.

The researchers capitalized on some neutron stars in the study being located in supernova remnants, including 3C 58. Since astronomers have age estimates of the supernova remnants, they also have the ages of the neutron stars that were created during the explosions that created both the remnants and the neutron stars. The astronomers found that the neutron star in 3C 58 and two others were much cooler than the rest of the neutron stars in the study.

The team thinks that part of the explanation for the rapid cooling is that these neutron stars are more massive than most of the rest. Because more massive neutron stars have more particles, special processes that cause neutron stars to cool more rapidly might be triggered.

One possibility for what is inside these neutron stars is a type of radioactive decay near their centers where neutrinos — low mass particles that easily travel through matter — carry away much of the energy and heat, causing rapid cooling.

Another possibility is that there are types of exotic matter found in the centers of these more rapidly cooling neutron stars.

The Nature Astronomy paper describing these results is available here. The authors of the paper are Alessio Marino (Institute of Space Sciences (ICE) in Barcelona, Spain), Clara Dehman (ICE), Konstantinos Kovlakas (ICE), Nanda Rea (ICE), J. A. Pons (University of Alicante in Spain), and Daniele Viganò (ICE).

NASA’s Marshall Space Flight Center manages the Chandra program. The Smithsonian Astrophysical Observatory’s Chandra X-ray Center controls science from Cambridge Massachusetts and flight operations from Burlington, Massachusetts.

Read more from NASA’s Chandra X-ray Observatory.

For more Chandra images, multimedia and related materials, visit:

https://www.nasa.gov/mission/chandra-x-ray-observatory/

Visual Description

This is an image of the leftovers from an exploded star called 3C 58, shown in X-ray and optical light. At the center of the remnant is a rapidly spinning neutron star, called a pulsar, that presents itself as a bright white object that’s somewhat elongated in shape.

Loops and swirls of material, in shades of blue and purple, extend outward from the neutron star in many directions, resembling the shape of an octopus and its arms.

Surrounding the octopus-like structure is a cloud of material in shades of red that is wider horizontally than it is vertically. A ribbon of purple material extends to the left edge of the red cloud, curling upward at its conclusion. Another purple ribbon extends to the right edge of the red cloud, though it is less defined than the one on the other side. Stars of many shapes and sizes dot the entire image.

News Media Contact

Megan Watzke
Chandra X-ray Center
Cambridge, Mass.
617-496-7998

Jonathan Deal
Marshall Space Flight Center
Huntsville, Ala.
256-544-0034

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Lee Mohon

Next Generation NASA Technologies Tested in Flight

Next Generation NASA Technologies Tested in Flight

4 Min Read

Next Generation NASA Technologies Tested in Flight

Five people in flight suits work on an experiment while floating in a simulated lunar gravity environment.

Erin Rezich, Ian Haskin, QuynhGiao Nguyen, Jason Hill (Zero-G staff), and George Butt experience Lunar gravity while running test operations on the UBER payload.

Credits:
Zero-G

Teams of NASA researchers put their next-generation technologies to the microgravity test in a series of parabolic flights that aim to advance innovations supporting the agency’s space exploration goals.

These parabolic flights provide a gateway to weightlessness, allowing research teams to interact with their hardware in reduced gravity conditions for intervals of approximately 22 seconds. The flights, which ran from February to April, took place aboard Zero Gravity Corporation’s G-FORCE ONE aircraft and helped to advance several promising space technologies.

Under the Fundamental Regolith Properties, Handling, and Water Capture (FLEET) project, researchers tested an ultrasonic blade technology in a regolith simulant at lunar and Martian gravities. On Earth, vibratory tools reduce the forces between the tool and the soil, which also lowers the reaction forces experienced by the system. Such reductions indicate the potential for mass savings for tool systems used in space. 

This flight test aims to establish the magnitude of force reduction achieved by an ultrasonic tool on the Moon and Mars. Regolith interaction, including excavation, will be important to NASA’s resources to support long-duration lunar and Martian missions.

This experiment represents the success of an international effort three years in the making between NASA and Concordia University in Montreal, Quebec.

Erin Rezich

Erin Rezich

Project Principal Investigator

“This experiment represents the success of an international effort three years in the making between NASA and Concordia University in Montreal, Quebec. It was a NASA bucket list item for me to conduct a parabolic flight experiment, and it was even more special to do it for my doctoral thesis work. I’m very proud of my team and everyone’s effort to make this a reality,” said Erin Rezich, project principal investigator at NASA’s Glenn Research Center in Cleveland, Ohio. 

The FLEET project also has a separate payload planned for a future flight test on a suborbital rocket. The Vibratory Lunar Regolith Conveyor will demonstrate a granular material (regolith) transport system to study the vertical transport of lunar regolith simulants (soil) in a vacuum under a reduced gravity environment.

These two FLEET payloads increase the understanding of excavation behavior and how the excavated soil will be transported in a reduced gravity environment.

QuynhGiao Nguyen takes experiment notes while Pierre-Lucas Aubin-Fournier and George Butt oversee experiment operations during a soil reset period between parabolas.
Zero-G

3D Printed Technologies Take on Microgravity 

Under the agency’s On-Demand Manufacturing of Electronics (ODME) project, researchers tested 3D printing technologies to ease the use of electronics and tools aboard the International Space Station.

Flying its first microgravity environment test, the ODME Advanced Toolplate team evaluated a new set of substantially smaller 3D printed tools that provide more capabilities and reduce tool changeouts. The toolplate offers eight swappable toolheads so that new technologies can be integrated after it is sent up to the space station. The 3D printer component enables in-space manufacturing of electronics and sensors for structural and crew-monitoring systems and multi-material 3D printing of metals.

“The development of these critical 3D printing technologies for microelectronics and semiconductors will advance the technology readiness of these processes and reduce the risk for planned future orbital demonstrations on the International Space Station.

curtis hill

curtis hill

ODME Project Principal Investigator

Left to Right: Pengyu Zhang, Rayne Wolfe, and Jacob Kocemba (University of Wisconsin at Madison) control the Electrohydrodynamic (EHD) ink jet printer testing manufacturing processes that are relevant to semiconductors for the NASA On Demand Manufacturing of Electronics (ODME) project.
Zero-G

NASA researchers tested another 3D printing technology developed under the agency’s ODME project for manufacturing flexible electronics in space. The Space Enabled Advanced Devices and Semiconductors team is developing electrohydrodynamic inkjet printer technology for semiconductor device manufacturing aboard the space station. The printer will allow for printing electronics and semiconductors with a single development cartridge, which could be updated in the future for various materials systems.

NASA’s Flight Opportunities program supported testing various technologies in a series of parabolic flights earlier this year. These technologies are managed under NASA’s Game Changing Development program within the Space Technology Mission Directorate. Space Enabled Advanced Devices and Semiconductors technology collaborators included Intel Corp., Tokyo Electron America, the University of Wisconsin-Madison, Arizona State University, and Iowa State University. The Space Operations Mission Directorate’s In-Space Production Applications also supports this technology. Advanced Toolplate Technology collaborated with Redwire and Sciperio. The Ultrasonic Blade technology is a partnership with NASA’s Glenn Research Center in Cleveland, Ohio, and Concordia University in Montreal, Quebec, through an International Space Act Agreement.

For more information about the Game Changing Development program, visit: nasa.gov/stmd-game-changing-development/

For more information about the Flight Opportunities program, visit: nasa.gov/stmd-flight-opportunities/ 

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Jun 20, 2024

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Ivry Artis

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Marina Guerges