Sols 4259-4260: Kings Canyon Go Again!

Sols 4259-4260: Kings Canyon Go Again!

3 min read

Sols 4259-4260: Kings Canyon Go Again!

MAHLI image of the brushed “Kings Canyon” target
MAHLI image of the brushed “Kings Canyon” target
NASA/JPL-Caltech/MSSS

Earth planning date: Monday, July 29, 2024

Our weekend drill preload test on the target “Kings Canyon” (shown in the accompanying MAHLI image) didn’t give us the full range of data we need to move forward with the full drilling process. This coming Wednesday, we hope to rerun our preload test on Kings Canyon or somewhere very similar on the same bedrock, and to get APXS and ChemCam analyses in order to determine scientific suitability for drilling. As a result, this plan focused on getting the arm ready to fulfill those diagnostic activities, described by our Science Operations Team Chief Elena in last Friday’s blog

In the meantime, we are in such an interesting area that we have a very long liens list (our wish list). Our problem today and probably for the foreseeable future will be a good one – trying to keep below our upper limits on how much of that wish list we are going to try to get in on a given day! 

We have recently seen examples of bedrock slabs or outcrops with a flat, paler toned centre and a rim of darker, greyer material which surrounds the main slab. We saw this about 50 sols ago at the Mammoth Lakes drill site and we see it here too. The relationships between the centre of the slab and the rim are very intriguing and we are keen to understand the interplay between the two textures. Mastcam will take two large mosaics in this area. “Sam Mack Meadow” is a 7×4 mosaic (i.e., 4 rows of 7 images) on an area of crushed grey material, and “Merced Grove” is a 7×6 mosaic on more intact rim material. ChemCam have also planned a LIBS analysis of Merced Grove and one at “Clinch Pass” in the centre of the block. Together these activities will help us to look at relationships here and to compare with previous examples, such as at the Mammoth Lakes drill site.

ChemCam will acquire a passive measurement on “Wilts Col,” a small dark toned float rock about 4 metres away from the rover as part of a continuing campaign to assess the nature of the floats (loose rocks) which are strewn around this part of the crater. ChemCam will also acquire 2 RMI (long distance images) 10×1 mosaics, looking at the stratigraphy and layering of the distant hills – getting a head start on the science assessment before we even get close!

The atmosphere and environment science theme group (ENV) also crammed their section of the plan full of activities. Since landing (almost 12 years ago now!!), the ENV group has been reporting on environmental conditions in Gale, and this plan was no exception. We have some regular DAN passives, REMS activities and a Navcam dust devil movie, and a single Mastcam “Tau” measurement, which looks at dust in the atmosphere.

Written by Catherine O’Connell-Cooper, Planetary Geologist at University of New Brunswick

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Last Updated
Jul 30, 2024

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GLOBE Alumna and Youth for Habitat Program Lead Named Scientist of the Month in Alaska

GLOBE Alumna and Youth for Habitat Program Lead Named Scientist of the Month in Alaska

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GLOBE Alumna and Youth for Habitat Program Lead Named Scientist of the Month in Alaska

As a 16-year old high school graduate, Maggie House decided to leave the military base in Germany where she lived with her family and go to college close to nature in Fairbanks, Alaska. She had lived in many countries and US states and knew she was ready. At the University of Alaska Fairbanks Troth Yeddha’ campus in Fall 2022, Maggie enrolled in a 300-level Watershed Management course, which required all students to implement a Global Learning and Observations to Benefit the Environment (GLOBE) project and poster. Maggie’s project focused on using the GLOBE Observer App to monitor the erosion of nearby Cripple Creek, which had a history of mining and made Fairbanks famous for its gold. She and a classmate wrote a funded mini-grant proposal to study how ice was related to erosion. While not on the frozen creek, Maggie worked as a student employee with the NASA Science Activation Program’s Arctic and Earth STEM Integrating GLOBE and NASA (SIGNs) team at the International Arctic Research Center, during which she trained teachers and mentored students at Alaska’s first-ever Student Research Symposium in 2022. Maggie also wrote an article about the symposium, published on the University of Alaska Fairbanks News page: https://www.uaf.edu/news/alaskan-youth-present-research-earth-day-symposium.php

When the ice melted and the symposium ended, Maggie wanted to study the freshwater habitats of the Creek using GLOBE hydrosphere protocols, so she wrote another proposal. Maggie got a full scholarship and grant funding through Biomedical Learning and Student Training (BLaST), supported by the National Institutes of Health. Her work earned recognition in the US Fish and Wildlife Service story, “Natural Flows Return to Cripple Creek” and honors as the December 2023/January 2024 BLaST Scientist of the Month. The story does not stop there. In May, 2024, Maggie House graduated with a Bachelor of Science degree and received the first-ever GLOBE internship at the Fairbanks Soil and Water Conservation District, where Maggie House leads the summer Youth for Habitat program for middle school students. Today, you can find Maggie in Cripple Creek near Fairbanks, Alaska, teaching students to learn science by doing science.

“I have a firm belief that the health of our environment is intertwined with the health of humans. I am interested in making science-related issues more understandable, for everyone to be a part of their local community. In my future, I see myself continuing to work towards strengthening the relationship between humans and nature and promoting the conservation of our dependence on one another.” – Maggie House

Arctic and Earth SIGNs created the conditions for Maggie as an undergraduate student to collect OpenSource GLOBE data that contributed to local solutions, to be awarded funding to pursue actionable research, and to be a leader for educators and future learners. Maggie’s data on ice conditions informed the engineering redesign of the Cripple Creek stream restoration project. Her success in using GLOBE protocols and culturally responsive research methods modeled by Arctic and Earth SIGNs gave her the confidence to write a research proposal and be awarded a full undergraduate research scholarship. Maggie was the first person in the world to monitor aquatic invertebrates in Cripple Creek just three weeks after flow was restored to the creek after 85 years. In Arctic and Earth SIGNs, environmental stewardship is a culminating part of the Learning Framework. Now, Maggie leads the stewardship of salmon habitat in Cripple Creek and mentors middle school youth to pursue STEM fields as a GLOBE trainer and mentor. Maggie’s story matters because one person, with a Science Activation support network and a focus on real-world environmental issues, can make a difference.

Arctic & Earth SIGNs is supported by NASA under cooperative agreement award number NNX16AC52A and is part of NASA’s Science Activation Portfolio. Learn more about how Science Activation connects NASA science experts, real content, and experiences with community leaders to do science in ways that activate minds and promote deeper understanding of our world and beyond: https://science.nasa.gov/learn

Two young students and their mentor, an intern, identify bugs using a microscope.
NASA Science Activation Program participant alumna Maggie House leads youth in GLOBE macroinvertebrate identification at an intergenerational workshop in June, 2024, using a microscope she purchased with her grant funds.
Christi Buffington

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NASA’s DART Mission Sheds New Light on Target Binary Asteroid System

NASA’s DART Mission Sheds New Light on Target Binary Asteroid System

5 min read

NASA’s DART Mission Sheds New Light on Target Binary Asteroid System

The asteroid’s triangular ridge (first panel from left), and the so-called smooth region, and its likely older, rougher “highland” region (second panel from left) can be explained through a combination of slope processes controlled by elevation (third panel from left). The fourth panel shows the effects of spin-up disruption that Didymos likely underwent to form Dimorphos.
The various geological features observed on Didymos helped researchers tell the story of Didymos’ origins. The asteroid’s triangular ridge (first panel from left), and the so-called smooth region, and its likely older, rougher “highland” region (second panel from left) can be explained through a combination of slope processes controlled by elevation (third panel from left). The fourth panel shows the effects of spin-up disruption that Didymos likely underwent to form Dimorphos.
Credit: Johns Hopkins APL/Olivier Barnouin

In studying data collected from NASA’s DART (Double Asteroid Redirection Test) mission, which in 2022 sent a spacecraft to intentionally collide with the asteroid moonlet Dimorphos, the mission’s science team has discovered new information on the origins of the target binary asteroid system and why the DART spacecraft was so effective in shifting Dimorphos’ orbit. 

In five recently published papers in Nature Communications, the team explored the geology of the binary asteroid system, comprising moonlet Dimorphos and parent asteroid Didymos, to characterize its origin and evolution and constrain its physical characteristics. 

“These findings give us new insights into the ways that asteroids can change over time,” said Thomas Statler, lead scientist for Solar System Small Bodies at NASA Headquarters in Washington. “This is important not just for understanding the near-Earth objects that are the focus of planetary defense, but also for our ability to read the history of our Solar System from these remnants of planet formation. This is just part of the wealth of new knowledge we’ve gained from DART.”

Olivier Barnouin and Ronald-Louis Ballouz of Johns Hopkins Applied Physics Laboratory (APL) in Laurel, Maryland, led a paper that analyzed the geology of both asteroids and drew conclusions about their surface materials and interior properties. From images captured by DART and its accompanying LICIACube cubesat – contributed by the Italian Space Agency (ASI), the team observed the smaller asteroid Dimorphos’ topography, which featured boulders of varying sizes. In comparison, the larger asteroid Didymos was smoother at lower elevations, though rocky at higher elevations, with more craters than Dimorphos. The authors inferred that Dimorphos likely spun off from Didymos in a large mass shedding event.

There are natural processes that can accelerate the spins of small asteroids, and there is growing evidence that these processes may be responsible for re-shaping these bodies or even forcing material to be spun off their surfaces.

Analysis suggested that both Didymos and Dimorphos have weak surface characteristics, which led the team to posit that Didymos has a surface age 40–130 times older than Dimorphos, with the former estimated to be 12.5 million years and the latter less than 300,000 years old. The low surface strength of Dimorphos likely contributed to DART’s significant impact on its orbit.

“The images and data that DART collected at the Didymos system provided a unique opportunity for a close-up geological look of a near-Earth asteroid binary system,” said Barnouin. “From these images alone, we were able to infer a great deal of information on geophysical properties of both Didymos and Dimorphos and expand our understanding on the formation of these two asteroids. We also better understand why DART was so effective in moving Dimorphos.”

Based on the internal and surface properties described in Barnouin et al. (2024), this video demonstrates how the spin-up of asteroid Didymos could have led to the growth of its equatorial ridge and the formation of the smaller asteroid Dimorphos, seen orbiting the former near the end of the clip. Particles are colored according to their speeds, with the scale shown at the top, along with the continually changing spin period of Didymos.
Credit: University of Michigan/Yun Zhang and Johns Hopkins APL/Olivier Barnouin

Maurizio Pajola, of the National Institute for Astrophysics (INAF) in Rome, and co-authors led a paper comparing the shapes and sizes of the various boulders and their distribution patterns on the two asteroids’ surfaces. They determined the physical characteristics of Dimorphos indicate it formed in stages, likely of material inherited from its parent asteroid Didymos. That conclusion reinforces the prevailing theory that some binary asteroid systems arise from shed remnants of a larger primary asteroid accumulating into a new asteroid moonlet.  

Alice Lucchetti, also of INAF, and colleagues found that thermal fatigue — the gradual weakening and cracking of a material caused by heat — could rapidly break up boulders on the surface of Dimorphos, generating surface lines and altering the physical characteristics of this type of asteroid more quickly than previously thought. The DART mission was likely the first observation of such a phenomenon on this type of asteroid. 

Supervised by researcher Naomi Murdoch of ISAE-SUPAERO in Toulouse, France, and colleagues, a paper led by students Jeanne Bigot and Pauline Lombardo determined Didymos’ bearing capacity — the surface’s ability to support applied loads — to be at least 1,000 times lower than that of dry sand on Earth or lunar soil. This is considered an important parameter for understanding and predicting the response of a surface, including for the purposes of displacing an asteroid.  

Colas Robin, also of ISAE-SUPAERO, and co-authors analyzed the surface boulders on Dimorphos, comparing them with those on other rubble pile asteroids, including ItokawaRyugu and Bennu. The researchers found the boulders shared similar characteristics, suggesting all these types of asteroids formed and evolved in a similar fashion. The team also noted that the elongated nature of the boulders around the DART impact site implies that they were likely formed through impact processing.

These latest findings form a more robust overview of the origins of the Didymos system and add to the understanding of how such planetary bodies were formed. As ESA’s (European Space Agency) Hera mission prepares to revisit DART’s collision site in 2026 to further analyze the aftermath of the first-ever planetary defense test, this research provides a series of tests for what Hera will find and contributes to current and future exploration missions while bolstering planetary defense capabilities. 

Johns Hopkins APL managed the DART mission for NASA’s Planetary Defense Coordination Office as a project of the agency’s Planetary Missions Program Office. NASA provided support for the mission from several centers, including the Jet Propulsion Laboratory in Southern California, Goddard Space Flight Center in Greenbelt, Maryland, Johnson Space Center in Houston, Glenn Research Center in Cleveland, and Langley Research Center in Hampton, Virginia. 

For more information about the DART mission:
https://science.nasa.gov/planetary-defense-dart

News Media Contacts

Karen Fox / Alana Johnson
Headquarters, Washington
202-358-1600 
karen.c.fox@nasa.gov / alana.r.johnson@nasa.gov

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NASA, Boeing Complete Second Docked Starliner Hot Fire Test

NASA, Boeing Complete Second Docked Starliner Hot Fire Test

Image shows Boeing's Starliner crew capsule docked to the Harmony module's forward port at the International Space Station
Boeing’s Starliner crew capsule docked to the Harmony module’s forward port at the International Space Station on July 3, 2024.
Photo credit: NASA

Engineering teams with NASA and Boeing completed a hot fire test of the Starliner spacecraft’s reaction control system jets on July 27 to evaluate the spacecraft’s propulsion system. NASA astronauts Butch Wilmore and Suni Williams, assigned to the agency’s Boeing Crew Flight Test, were seated inside the docked spacecraft during the test as part of preparations before their return aboard Starliner from the International Space Station.

The test involved firing 27 of the spacecraft’s 28 jets for short bursts, moving through them one at a time to check thruster performance and helium leak rates. Preliminary results show all the tested thrusters are back to preflight levels based on thrust and chamber pressure.

As part of the test configuration, all helium manifolds, which control and direct the flow of helium, were opened allowing engineers to continue evaluation of Starliner’s helium supply and leak rates. The teams verified Starliner continues to show the margin needed to support a return trip from the station. Following the test, the helium manifolds were closed and will remain closed until Starliner activates its propulsion system ahead of undocking. Teams also will verify the helium leak rate before Starliner undocks.

Teams are reviewing data from the docked hot fire test and the recent ground testing of a Starliner thruster at NASA’s White Sands Test Facility in New Mexico before holding an agency return readiness review. Following this agency-level review, NASA and Boeing will select a target return date.

While ground teams work to finalize Starliner’s return to Earth, Wilmore and Williams continue to work alongside the Expedition 71 crew, assisting with science investigations and maintenance activities. On July 29, Wilmore and Williams entered their spacecraft and checked its water systems, called down to Boeing mission personnel for a conference, and put on their space suits long enough to perform a pressure test. Wilmore started his morning in the Harmony module, assembling the BioServe centrifuge as Williams reviewed procedures for operating the Astrobee free-flying robotic assistants.

For the latest mission updates, follow the commercial crew blog, @commercial_crew on X, and commercial crew on Facebook.

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Danielle Sempsrott

Crews Prep for Cargo Mission and Checks Out Starliner Systems

Crews Prep for Cargo Mission and Checks Out Starliner Systems

Boeing's Starliner spacecraft is pictured docked to the Harmony module's forward port as the International Space Station orbited above Egypt's Mediterranean coast.
Boeing’s Starliner spacecraft is pictured docked to the Harmony module’s forward port as the International Space Station orbited above Egypt’s Mediterranean coast.

The Expedition 71 crew turned its attention to an upcoming U. S. cargo mission, spacesuit work, and a variety of life science on Monday. NASA’s Boeing Crew Flight Test members began the week servicing their Starliner flight suits and the spacecraft’s life support systems following a morning of light research duties.

The next cargo mission to resupply the residents living and working aboard the International Space Station is counting down to a launch at 11:28 a.m. EDT on Saturday from Kennedy Space Center in Florida. Northrop Grumman’s Cygnus space freighter will launch atop a SpaceX Falcon 9 rocket carrying 8,200 pounds of science, supplies, and hardware for the station. Cygnus will orbit Earth for just over a day-and-a-half before approaching the orbital outpost where the Canadarm2 robotic arm will be waiting to capture the spacecraft.

NASA Flight Engineers Matthew Dominick and Jeanette Epps spent Monday preparing for Cygnus’ arrival reviewing its mission profile and practicing robotic capture maneuvers on a computer. Dominick will command the Canadarm2 to capture Cygnus at 5 a.m. on Aug. 5 while Epps backs him up and monitors the approach and rendezvous activities. Afterward, robotics controllers on the ground will remotely take over Canadarm2 and guide Cygnus toward the Unity module’s Earth-facing port where it will be mated for five-and-a-half months.

NASA Flight Engineer Mike Barratt kicked off his day checking on plumbing hardware stowed in the Zarya module before swapping components and configuring a U.S. spacesuit in the Quest airlock. NASA astronaut Tracy C. Dyson spent her morning in the Columbus laboratory module troubleshooting the MARES rack, or Muscle Atrophy Research and Exercise System, then spent the afternoon installing drawer handle brackets on a pair of Human Research Facility racks.

Starliner Commander Butch Wilmore and Pilot Suni Williams entered their spacecraft Monday afternoon and checked its water systems, called down to Boeing mission personnel for a conference, then wore their flight suits momentarily for a pressure test. Wilmore started his morning in the station’s Harmony module assembling the BioServe centrifuge as Williams reviewed procedures for operating the Astrobee free-flying robotic assistants.

The orbiting lab’s three cosmonauts refocused their activities on Monday to standard space research and lab maintenance duties following a week of inspection tasks in the orbital outpost’s Roscosmos segment. Flight Engineer Nikolai Chub worked all day on science first studying a 3D printer’s ability to manufacture tools in microgravity, then explored how magnetic and electrical fields affect fluid physics, before finally installing hardware to image Earth’s nighttime atmosphere in near-ultraviolet wavelengths. Flight Engineer Alexander Grebenkin attached sensors to himself during the morning for a 24-session measuring his heart rate and blood pressure. Afterward, he pointed a camera outside a station window taking pictures for a pair of Earth observation studies. At the beginning of his shift, station Commander Oleg Kononenko installed radiation detection hardware cables then inventoried food rations.


Learn more about station activities by following the space station blog@space_station and @ISS_Research on X, as well as the ISS Facebook and ISS Instagram accounts.

Get weekly video highlights at: https://roundupreads.jsc.nasa.gov/videoupdate/

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Mark Garcia