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Mice that exercised soon after waking up had stronger and longer bones than those that exercised later in the day  

India's Agnikul Cosmos successfully launched a test vehicle powered by a homegrown 3D printed rocket engine.

The Chang’e 6 mission is China’s second to touch down on the lunar far side and will retrieve samples for analysis on Earth

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Preparations for Next Moonwalk Simulations Underway (and Underwater) Team “Rumble Ready” from California State Polytechnic University, Pomona, comprised of (from left to right) Professor Mark Gonda, Nicole Xie, Junaid Bodla, Jordan Ragsac, Krishi Gajjar, Gerald McAllister III, and Leara Dominguez, took home first place at the 2024 Gateways to Blue Skies Forum held May 30-31 at NASA Ames Research Center.National Institute of Aerospace

The California State Polytechnic University, Pomona, team, with their project titled “Aero-Quake Emergency Response Network,” took first place at the third annual Gateways to Blue Skies Competition. Competing among eight finalist teams that presented their ideas for aviation-related systems for natural disasters, the California State Polytechnic University, Pomona team earned the top award at the 2024 Blue Skies Forum, hosted at NASA’s Ames Research Center May 30-31. The Forum was judged by subject matter experts from NASA and industry. 

In addition to the first-place recognition, team members were awarded an opportunity to intern at any of the four NASA Aeronautics Centers — Langley Research Center (Hampton, VA), Glenn Research Center (Cleveland, OH), Ames Research Center (Mountain View, CA), and Armstrong Flight Research Center (Edwards, CA) —across the country during the 2024-25 Academic Year.   

“We truly enjoyed the NASA Blue Skies competition,” said team lead Krishi Gajjar. “We are honored that our efforts have been awarded by the experienced and diverse judging panel. This would not have been possible without the guidance from our advisor, professor Mark Gonda, and our rigorous engineering program at Cal Poly Pomona. We are proud to have grown together as a team and are excited to continue advancing aviation in our future careers as aerospace engineers!” 

Second place went to Columbia University with their project, “AVATARS: Aerial Vehicles for Avalanche Terrain Assessment and Reporting Systems.”  

Other awards included:  

• Future Game-Changer Award: Cerritos College | F.I.R.E (Fire Intervention Retardant Expeller) 
• Most Innovative Award: North Carolina State University | Reconnaissance and Emergency Aircraft for Critical Hurricane Relief (REACHR) 

Sponsored by NASA’s Aeronautics Research Mission Directorate’s University Innovation Project, the Gateways to Blue Skies Competition is an initiative to engage college students in researching climate-friendly technologies and applications related to the future of aviation. Because of the increase in natural disasters compounded by climate change, the 2024 theme, “Advancing Aviation for Natural Disaster,” asked students to investigate and conceptualize, in terms of feasibility and viability, aviation-related systems that can be applied by 2035 to one phase of management of a chosen type of natural disaster to improve capabilities. 

Because many emergency response professionals believe there is no one proposed concept that will be applicable for all different natural disasters or can be applied to all phases of management, this competition welcomed a wide range of potential solutions. New technologies and applications gained from this crowdsourced competition may be developed further by NASA for use in coordinating and facilitating disaster management. 

At the Forum, finalist teams presented concepts of systems that addressed responses to natural disasters such as earthquakes, avalanches, volcanic eruptions, hurricanes, floods, and wildfires.   

“Whenever NASA engages with students, it’s such a rewarding experience,” said Steven Holz, NASA Aeronautics University Innovation Assistant Project Manager and Blue Skies judge and co-chair. “This competition encourages students to imagine, expand, and tackle the challenges and opportunities that await in the future of aeronautics. The students bring unique concepts and ideas to the table along with a wealth of knowledge and professionalism. It’s always exciting to have the chance to see firsthand what they come up with next.” 

Students also had the opportunity to network with NASA and industry experts, tour NASA’s Ames Research Center, and gain insight into potential careers and applications that will further the Agency’s mission toward a climate-friendly aviation future. 

“Because natural disasters are so far-reaching and impactful to so many, we had a lot of interest in this year’s competition,” added Marcus Johnson, project manager in the Aeronautics Directorate at NASA Ames Research Center and 2024 Blue Skies co-chair. “Each of the eight finalist teams that presented at this year’s Forum were passionate about their concepts and each offered compelling ideas.  This competition is about so much more than just “awards,” it’s about connecting, networking and identifying the future leaders in aeronautics.” 

The 2024 Gateways to Blue Skies Competition is sponsored by NASA’s Aeronautics Research Mission Directorate and administered by the National Institute of Aerospace.  

**** 

View the livestream of the competition presentations: https://vimeo.com/showcase/blueskies

View the competition finalists: https://blueskies.nianet.org/finalists/ 

To learn more about the 2024 Gateways to Blue Skies: Advancing Aviation for Natural Disasters Competition, visit: https://blueskies.nianet.org/competition/ 

For more information about NASA Aeronautics, visit: https://www.nasa.gov/topics/aeronautics/index.html 

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Details Last Updated Jun 03, 2024 Related Terms

• Aeronautics
• Langley Research Center

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Comicpalooza, the largest annual pop culture festival in the southern United States, is home to thousands of comic book, science, anime, and gaming fanatics in Houston. Guests have the opportunity to celebrate their passions through a variety of entertainment, panels, and meet and greets.

NASA’s Johnson Space Center has participated in Comicpalooza’s festivities for the last decade, giving attendees the chance to interact with NASA experts and learn more about human space exploration and the agency’s mission.

Comicpalooza guests listen to a presentation by NASA astronaut Marcos Berríos at the agency’s exclusive booth and stage area.NASA/Robert Markowitz

Over 52,000 fans attended this year’s Comicpalooza, held May 24-26 at Houston’s George R. Brown Convention Center. NASA shared with them the exhilarating future of the Artemis campaign that will take humans further in space exploration than ever before, plans for human exploration of the Moon and Mars, and showcased innovative spacesuits, lunar terrain vehicles, and spacewalk tools. Fans also had an opportunity to meet and take photos with NASA astronaut Marcos Berríos.

NASA astronaut Marcos Berríos talks about his journey to becoming an astronaut and experiences to date during a presentation at 2024 Comicpalooza. NASA/Robert Markowitz

The NASA exhibit featured immersive experiences with the Extravehicular Activity and Human Surface Mobility Program; Exploration Architecture, Integration, and Science Directorate; Human Health and Performance Directorate; and STEM engagement programs. These unique exhibits provided guests with insight into the exciting opportunities and discoveries ahead for human spaceflight. NASA’s presence at Comicpalooza also caught the attention of legendary Hollywood actor Christopher Lloyd, who met NASA officials and participated in a tour of Johnson Space Center after the event concluded.

Johnson Space Center volunteers and NASA experts who led interactive exhibits and panel discussions as part of the agency’s presence at 2024 Comicpalooza.NASA/Robert Markowitz

NASA’s exclusive Comicpalooza stage featured 13 unique panels and discussions from agency experts, programs, and Berríos. These panels included:

• The Development of Lunar Base Camp: NASA scientists discussed how future robotic and human explorers will put in place infrastructure for a long-term sustainable presence on the Moon.
• Driving on the Moon One Day: A discussion about the latest technology and partnerships that will develop the next mobility systems on the Moon.
• Another One Bites the Dust: Lunar Dust, Hardware Damage, and Why It Matters on the Moon: Lunar dust mitigation engineers and scientists talked about some of the risks of working on the Moon, what happened during Apollo, and what they plan to do about hardware damage, which threatens their efforts to keep astronauts safe and ensure mission success.
• Meet an Astronaut: NASA astronaut Marcos Berríos hosted a panel about his journey to becoming an astronaut, what he is doing at NASA during his training period, and what is next for him in the future. A Q&A session followed the presentation and guests had the opportunity to learn more about Marcos.
• Why It’s Hard to get to Mars: A discussion on why it is so difficult to get to the “Red Planet” and what technologies and strategies NASA is developing to accomplish this goal.
• Landing on the Moon: A panel onwhy landing on the Moon remains a challenge and what the future looks like for additional lunar landings and activities.
• International Space Station Mimic: Engineers and educators talked about a 3D printed, robotic model that syncs to live telemetry streaming from the real International Space Station in real-time.
• My NASA Story: An early career perspective on launching a career at Johnson Space Center. Panelists discussed how they got to where they are, and what their jobs look like on a daily basis.
• Artemis Overview: An overview on the Artemis campaign and its future, which includes landing the first woman and first person of color on the Moon. Through the Artemis missions, NASA will use new technology to study the Moon in new and better ways and prepare for human missions to Mars.
• Draw Artemis: A panel of experts hosted a “draw along” as they discussed humanity’s voyage back to the Moon, the key role art plays in exploration, and the otherworldly environment of the Moon’s South Pole.

NASA’s participation in Comicpalooza educates and excites the public about the agency’s mission and inspires people who want to be a part of space exploration in their own unique ways.

Enjoy more images of the NASA exhibit booth at Comicpalooza below.

Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz Actor Christopher Lloyd visited the Mission Control Center at NASA’s Johnson Space Center following Comicpalooza.NASA Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage.NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage.NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz Comicpalooza guests enjoyed interactive exhibits, photo ops, and compelling panel discussions at NASA’s booth and exclusive event stage. NASA/Robert Markowitz

A team from Iowa accepts the Artemis grand prize award during NASA’s Lunabotics competition on Friday, May 17, 2024, at the Center for Space Education near the Kennedy Space Center Visitor Complex in Florida. Photo credit: NASA/Derrol NailPhoto credit: NASA/Derrol Nail

Members of the Artemis Generation kicked up some simulated lunar dust as part of NASA’s 2024 Lunabotics Challenge, held at The Astronauts Memorial Foundation’s Center for Space Education at the agency’s Kennedy Space Center Visitor Complex in Florida. When the dust settled, two teams emerged from Artemis Arena as the grand prize winners of this year’s competition. 

Teams from Iowa State University and the University of Alabama shared the Artemis grand prize award for scoring the most cumulative points during the annual competition. Judges scored competing teams on project management plans, presentations and demonstrations, systems engineering papers, robotic berm building, and science, technology, engineering, and math (STEM) engagement.  

This is the first time in Lunabotics’ 15-year history that the competition ended in a tie for the top prize, and most likely the last time.  

“Both teams earned their win, but a tie was never on the table,” said Rich Johanboeke, project manager at NASA’s Kennedy Space Center in Florida. “These students work hard and sacrifice much throughout the year to be a part of this challenge and to come to Kennedy, so our team will look into creating a tie-breaking event for future events.” 

Alabama’s team lead, Ben Gulledge, is pictured with the team’s winning rover during NASA’s Lunabotics competition on Friday, May 17, 2024, at the Center for Space Education near the Kennedy Space Center Visitor Complex in Florida.Photo credit: NASA/Derrol Nail

While previous Lunabotics competitions focused on lunar mining, this year’s competition reflected the current needs of NASA’s Artemis missions. Teams designed, built, and operated autonomous robotic rovers capable of building a berm structure from lunar regolith. Among other uses, berms on the Moon could provide protection against blast and material ejected during lunar landings and launches, shade cryogenic propellant tank farms, or shield a nuclear power plant from space radiation. 

Of the 58 college teams across the country that applied to the challenge, 42 were invited to demonstrate their robotic rovers during the qualifying round held in the Exolith Lab at the University of Central Florida in Orlando. From there, 10 finalist teams made the short trip to Kennedy for the two-day final round, where their robots attempted to construct berms from simulated lunar regolith inside Artemis Arena.  

“During the competition we had over 150 berm construction runs in the arena,” said Robert Mueller, senior technologist for Advanced Products Development in NASA’s Exploration Research and Technology Programs Directorate, as well as lead judge and co-founder of the original Lunabotics robotic mining challenge. “So, teams went into the arena 150 times and created berms – that’s pretty impressive. And 28 teams, which is 65% of the teams that attended, achieved berm construction points, which is the highest we have ever had. That speaks to the quality of this competition.”  

Teams competing in this year’s Lunabotics applied the NASA Systems Engineering Process to create their prototype robots and spent upwards of nine months focused on making their designs realities.  

“We really put a lot of work in this year,” said Vivian Molina Sunda, team and electrical lead for University of Illinois at Chicago. “Our team of 10 put in about 3,400 hours, so it’s really exciting to get to Kennedy Space Center and know we made the top 10.”  

The University of Illinois team received two awards for its efforts – the Mission Control “Failure is Not an Option” Award for Team Persistence and the Innovation Technology Award for best design based on creative construction, innovative technology, and overall architecture. 

Lunabotics teams prepare robots to compete inside the Artemis Arena during NASA’s Lunabotics competition on Friday, May 17, 2024, at the Center for Space Education near the Kennedy Space Center Visitor Complex in Florida.Photo credit: NASA/Derrol Nail

For the hundreds of Artemis Generation members who took part in this year’s competition, Lunabotics was an opportunity to connect to NASA’s mission, work, and people, while also using classroom skills and theories in ways that will benefit them in future STEM careers.  

“We go into engineering because we want to do stuff, we want to make things,” said Ben Gulledge, team and mechanical lead for the University of Alabama’s Artemis grand prize co-winning team. “This competition gives you the opportunity to take all your classroom theory and put it into practice and learn where your gaps in knowledge are. So, you learn to be a better designer and learn where you can improve in the future.” 

Coordinated by NASA’s Office of STEM Engagement, the Lunabotics competition is one of NASA’s Artemis Student Challenges, designed to engage and retain students in STEM fields. These challenges are designed to provide students with opportunities to research and design in the areas of science, technology, engineering, and math, while fostering innovative ideas and solutions to challenges likely to be faced during the agency’s Artemis missions.  

To view the complete list of NASA’s 2024 Lunabotics Challenge winners, or for more information visit:  

https://www.nasa.gov/learning-resources/lunabotics-challenge/

Winners List 
 

Artemis Grand Prize 

Iowa State University, The University of Alabama 

Robotic Construction Award  

First Place – Iowa State University  

Second Place – The University of Alabama  

Third Place – University of Utah  

Systems Engineering Paper Award 
First Place – College of DuPage 
Second Place – The University of Alabama 
Third Place – Purdue University-Main Campus 

Leaps and Bounds Award 
New York University 

Nova Award for Stellar Systems Engineering by a First Year Team 

Ohio State University 

STEM Engagement Award 
First Place – University of North Florida 
Second Place – Auburn University 
Third Place – Iowa State University 

Honorable Mention – Harrisburg University of Science and Technology 

Presentation and Demonstration 
First Place – University of North Carolina at Charlotte 
Second Place – Purdue University-Main Campus 
Third Place – University of Utah 

First Steps Award – Best Presentation by a First Year Team  

Harrisburg University of Science and Technology 

Innovation Technology Award 

University of Illinois at Chicago  

The Mission Control “Failure is Not an Option” Award for Team Persistence 

University of Illinois at Chicago 

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Summary of the 2023 Precipitation Measurement Mission Science Team Meeting

Andrea Portier, NASA’s Goddard Space Flight Center/Science Systems and Applications, Inc., andrea.m.portier@nasa.gov

Introduction

The annual Precipitation Measurement Mission (PMM) Science Team Meeting (STM) took place September 18–22, 2023, in Minneapolis, MN. The PMM program supports scientific research and applications, algorithm development, and ground-based validation activities for the completed Tropical Rainfall Measuring Mission (TRMM) and current Global Precipitation Measurement (GPM) mission, including the GPM Core Observatory. Participants (including 137 in person and 22 virtual attendees) joined the meeting from a variety of affiliations including NASA, the Japan Aerospace Exploration Agency (JAXA), universities, and other partner agencies—see Photo.

The meeting included 46 plenary presentations spread across 7 thematically focused sessions and 77 poster presentations split between 2 sessions, with both oral and poster sessions covering mission and program status, partner reports, GPM algorithm development, and scientific results using GPM data.

The meeting also included a series of splinter sessions for precipitation working groups. The working groups included NASA–JAXA Joint Precipitation Science Team, the Committee on Earth Observation Satellites–Precipitation Virtual Constellation, GPM Mentorship Program, and topically focused groups on Applications, Hydrology, Land Surface, Latent Heating, Multisatellite, GPM Intersatellite Calibration (XCAL), Ground Validation (GV), Particle Size Distribution (PSD), and Oceanic Areas. These working groups were a combination of invitation-only, in-person, and hybrid meetings. Owing to the distributed nature of these meetings, summaries of their proceedings are not included in this article.

This article highlights current updates on the GPM mission and summarizes scientific results conveyed during the 2023 PMM STM. The meeting agenda and full presentations can be accessed through the 2023 PMM Science Team Meeting Files. Note that this is a password protected page; readers interested in accessing these files will need to reach out via the GPM Contact Form on the website to receive the access code.

Photo. Attendees of the 2023 PMM STM in front of the McNamara Alumni Center in Minneapolis, MN. Photo credit: Chris Kidd/GSFC and University of Maryland, College Park (UMD)

Status Report and Updates on PMM: Perspectives from NASA and JAXA

The PMM missions are the fruit of long partnerships between NASA and JAXA. The PMM Science Team (ST) includes more than 20 international partners. The subsections that follow highlight the status of the PMM program and related activities that were conveyed by NASA and JAXA PMM Science Program Management Teams.

NASA

Will McCarty [NASA Headquarters (HQ)—GPM Program Scientist] presented the NASA HQ perspective regarding PMMs – present and future. He explained that current missions continue to drive the focus for precipitation science, and that future missions will continue to link the thermodynamic and dynamic factors of precipitation science by targeting additional temporal information. McCarty introduced several current and upcoming missions and programs, including satellite launches [e.g., NASA’s Time-Resolved Observations of Precipitation structure and storm Intensity with a Constellation of Smallsats (TROPICS), an Earth Venture Instrument (EVI), and the Investigation of Convective Updrafts (INCUS), an Earth Venture Mission], instruments [e.g., NASA’s Polarized Submillimeter Ice-cloud Imager (POLSIR), also an EVI, which will be deployed on two CubeSats], and field campaigns [e.g., NASA’s Investigation of Microphysics and Precipitation for Atlantic Coast-Threatening Snowstorms (IMPACTS) and Convective Processes Experiment Cabo Verde (CPEX-CV) experiments]. He then briefly discussed the second (2017) Earth Science Decadal Survey and provided an overview of the future Earth System Observatory (ESO), which will have interconnected core missions (e.g., the Atmosphere Observing System (AOS)). He also discussed the Planetary Boundary Layer (PBL), which the Decadal Survey classifies incubation targeted observable. McCarty concluded by noting that the future PMM ST call may be integrated by combining mission science from multiple satellites.

George Huffman [NASA’s Goddard Space Flight Center (GSFC)—GPM Project Scientist and PMM ST Lead] provided an update on the projected lifetime for GPM. Based on fuel usage alone, GPM should continue to December 2027. However, the amount of solar activity has an impact on that calculation. The Sun is expected to be quite active over the next few years as we approach the Solar Maximum for Solar Cycle 25—which could shorten GPM’s lifetime by as much as four years. He noted that a controlled reentry of the GPM Core spacecraft is planned—and enough fuel has to be kept in reserve to allow this to happen. Huffman discussed a recently developed plan for boosting the orbit of the GPM core satellite—for more details on the plan, see the subsection, “GPM Core Observatory Boost,” later in this article. He added that NASA and JAXA have both approved the plan and deemed its implementation critical for overlap with AOS for instrument intercomparison. The boosting is currently scheduled for November 7–9, 2023.(Update: Since the meeting in September, the GPM orbit boost was executed successfully on the scheduled dates.) The impact of the boosting on radiometer algorithms (e.g., for the GPM Microwave Imager (GMI)) is expected to be less than the impact on the radar algorithms (e.g., for the GPM Dual-Frequency Precipitation Radar, (DPR)). The potential impact on the combined algorithms (i.e., algorithms used to combine data from GMI and DPR) is still being assessed.

Huffman also discussed the status of the GPM data products. He reported that all GPM core data products are using Version 7 (V07). He mentioned that V07 of the Integrated Multi-Satellite Retrievals for GPM (IMERG) Final is out, but IMERG Early and Late data products are pending other actions in the NASA Precipitation Processing System (PPS). (IMERG has 3 classifications of data products: Early (latency of 4 hours), late (latency of 12–14 hours), and final (latency of 3 months).) He noted that the GPM orbit boost requires modifications to V07 core algorithms, and this accentuates the importance of a timely release of V08 algorithms (anticipated early 2026).

Erich Stocker [GSFC—GPM Deputy Project Scientist for Data and Precipitation Processing System Project Manager] discussed the status of GPM data products. He mentioned that radar/combined/IMERG products have transitioned from V06 to V07—but all radiometer products, Level-1 to Level-3, went from V05 to V07 to ensure the version is consistent on all of the products. Stocker continued that the GPM core satellite boost in November 2023 will lead to an outage of radar products for about five months for research and 2–3 months for near real-time (NRT) data products. NRT radiometer products will continue through the boost with only 2–3 days of outage while the satellite reaches its new altitude. He concluded that the initial NRT V07 IMERG processing and V07 retroprocessing of Early and Late IMERG products will start in January 2024.

David Wolff [NASA’s Wallops Flight Facility (WFF)—GPM Deputy Project Scientist for Ground Validation and Ground Validation System Manager] provided an overview of the GPM Ground Validation program and current activities. He stated that the ground validation (GV) program has state-of-the-art ground and remote sensing instruments to acquire precipitation and microphysics data to validate GPM retrievals. He described the ground validation site at NASA’s Wallops Flight Facility (WFF), which includes several radars, disdrometers (an instrument that measures drop-size distribution), and a Precipitation Imaging Processor (PIP) package. Wolff discussed the gauge-only systems, Platforms for In situ Estimation of Rainfall Systems (PIERS), activities for Increasing Participation of Minority Serving Institutions in Earth Science Division Surface-Based Measurement Networks, and pySIMBA – the GPM GV Support Software, an Open-Source Python Package to integrate and Analyze Precipitation Datasets that is available from GitHub. Wolff also provided a brief overview of the successful GPM GV Workshop that was held at Wallops Flight Facility on March 23–25, 2023. He continued by providing GPM Ground Validation Network (VN) updates and discussing VN captures of three-dimensional (3D) polarimetric information within DPR and GMI.

Wolff also noted that the GV program includes field campaigns (e.g., IMPACTS and Marquette, a five-year mini campaign conducted in collaboration with the National Oceanic and Atmospheric Administration’s (NOAA) National Weather Service (NWS)­). He also discussed the new S-band radar network in Canada that offers access to high-quality radar data at relatively high latitudes over both land and sea. This data will be used as part of the VN for evaluation of GPM products. He concluded by discussing the Global Hydrometeorology Resource Center (GHRC) that archives past and current field campaign data and provides data quality control, metadata, campaign descriptions, and digital object identifier (DOI) assignments for each instrument/sensor.

Andrea Portier [GSFC—GPM Mission Applications Lead] and Dorian Janney [GSFC—GPM Outreach Coordinator] reflected on the 2022–2023 applications and outreach efforts and also discussed upcoming activities, including the – at the time of the meeting – upcoming tenth anniversary of the GPM Mission in February 2024. The applications team continues its focus on increasing awareness and use of GPM data and products across communities through user-engagement activities, including workshops (e.g., Applying Earth Observation Data for Research and Applications in Sustainable Development held at the 2022 Fall Meeting of the American Geophysical Union (AGU) in San Francisco, CA), trainings (e.g., 2023 GPM Mentorship Program), GPM application case studies, and GPM visualizations. A continuing and integral part of GPM outreach efforts is the numerous activities that reach hundreds of students and adults in a variety of formal and informal settings. This includes cooperative efforts with NASA’s Global Learning and Observations to Benefit the Environment (GLOBE) and hands-on activities at events (e.g., the Earth Day celebration at the Washington, DC’s Union Station). (To read more about the 2023 Earth Day celebration at Union Station, see A Pale Blue Dot in Washington: NASA’s Earth Day Celebration at Union Station, in the July–August 2023 issue of The Earth Observer [Volume 35, Issue 4, pp. 4–12].)

Many of these efforts will be highlighted and amplified during GPM’s tenth anniversary celebration. The GPM Applications and Outreach Team’s planning for the anniversary is underway. The intent is to highlight the vast capabilities of the GPM Mission and how GPM data can be used to address societal applications and improve the understanding of Earth’s water and energy cycles through a series of activities and resources starting in February 2024. These efforts include a reception at GSFC Visitor’s Center, a year-long monthly webinar series, feature articles, applications eBook, and a GPM video, among others. Details of these efforts will be posted through the GPM website.

JAXA

Takuji Kubota [JAXA—JAXA GPM Program Scientist] provided an update and a review of the PMM program status and mission objectives. He emphasized that this update included the perspectives of the Japanese PMM Science Program Management Team, including their roles in the development of DPR and its algorithms, GV, GPM data processing, and GPM data distribution systems. He also gave an update on current activities related to GPM data utilization and application across Japan and Asia. Kubota continued by describing the potential impacts on the DPR instrument because of the proposed orbit boost, noting that the instrument footprints and swath widths will increase proportionately with altitude change accompanied by a slight reduction in radar sensitivity. JAXA is preparing for these impacts with revised codes for L1 algorithms and planning for external calibrations before and after the orbit boost to examine calibrations of the DPR. Kubota also discussed the reprocessing of JAXA’s Global Satellite Mapping of Precipitation (GSMaP) data product (essentially the JAXA equivalent of IMERG) to enable a longer-term precipitation dataset, highlighting its completion in September 2023. GSMaP data is now available back to January 1998. Kubota discussed the future of Japanese precipitation measurements including: Earth Cloud, Aerosol and Radiation Explorer (EarthCARE), scheduled for launch in 2024; Global Observing SATellite for Greenhouse gases and Water cycle (OSAT-GW), planned for launch NET 2024; Advanced Microwave Scanning Radiometer (AMSR) series, which currently includes AMSR2 on the (GCOM-W) and will include AMSR3 on GOSAT-GW; and the previously discussed ESO AOS mission. He concluded with a discussion of JAXA’s plan for observing and celebrating GPM’s tenth anniversary.

Yukari Takayabu [University of Tokyo—JAXA GPM Project Scientist] highlighted results from recent science studies using DPR and GSMaP data products from the JAXA assembled GPM Program Science Team. She noted the use of DPR for extracting high-altitude precipitation information over Africa, capturing low-level precipitation statistics near the center of typhoons, narrowing the blind zone of the DPR to improve shallow precipitation detection in mountainous areas, validation studies of DPR, and retrieving frozen precipitation data using DPR. She concluded her presentation with highlights of GSMaP use for several applications, including the new GSMaP validation work in Japan to observe extreme rainfall, improvements to GSMaP through data-driven approaches, and data assimilation of GSMaP into the JAXA Realtime Weather Watch system.

Nobuhiro Takahashi [Nagoya University] presented an overview of significant updates to the DPM algorithm since the last PMM ST meeting, including changes in the latest V07 processing to accommodate the full-swath Ka-band operations – see Figure 1. He emphasized the impacts on the planning and development of V08 DPR algorithm with respect to the GPM orbit boost (described in George Huffman’s presentation). He noted that the major impacts to the performance of DPR include a degradation of measurement sensitivity and the “rain/no rain” classification. Takahashi concluded by saying that the release of V08 is expected in January 2026.

Figure 1. Evaluation of DPR product improvements from V06 to V07. Dual frequency product has smaller bias than KuPR product. The correlation coefficient improved from V06 to V07.Figure credit: Nobuhiro Takahashi/Nagoya University

Kosuke Yamamoto [Earth Observation Research Center (EORC) and JAXA] summarized application activities initiated by the JAXA GPM Program Science Team. He discussed the use of GSMaP precipitation data to support and enhance several application areas, e.g., the operational use of GSMaP for flood and severe weather forecasting as well as the use of GSMaP in operational systems, including the JAXA Agro-meteorology Information Provision System (JASMIN), ASEAN Food Security Information System (AFSIS), and the Japanese’ Coast Guard’s Maritime Domain Awareness (MDA) initiative. Yamamoto also discussed the 2022 Japan–Australia–India–U.S. (QUAD) Joint Leaders’ Meeting Tackling Extreme Precipitation Events Workshop, an online event that took place March 1–3, 2023, and associated workshop reports focusing on the utilization of satellite observations across Pacific Islands.

GPM Algorithm Updates

Presenters during this session provided information and updates on various aspects of the five major algorithms of GPM. Full documentation and detailed updates for each algorithm are available at the Precipitation Data Directory.

Dual Frequency Radar Algorithm

The DPR algorithm team provided updates on DPR-related work, including the further refinement of the path-integrated attenuation (PIA) estimates used in the surface reference technique (SRT). They examined the effects of using the new AutoSnow algorithm – which uses satellite snowfall observations to create snowfall maps – on PIA estimations and changes in the surface type classification. Overall, the changes were small on the estimated precipitation profiles. Other algorithm refinements include the addition of a dry and wet snow category and wind speed. The team is currently examining how to recover Ka-band attenuation from the Ku-band. They stressed that results from this analysis are preliminary, and more work is needed to assess the utility of this technique. Finally, the team is discussing the implications of the GPM orbit boost on the DPR algorithm.

GPM Combined Radar–Radiometer Algorithm

The GPM Combined Radar–Radiometer Algorithm (CORRA) team discussed the changes and improvements to the CORRA V07 algorithm over the previous version. They highlighted the new AutoSnow algorithm and its impacts within CORRA V07. The team also examined the impact of the precipitation particle size distribution (PSD) initial assumptions on the estimation of snowfall as well as a machine-learning based initialization approach that improves the agreement between CORRA and NOAA’s Multi-Radar/Multi-Sensor System (MRMS) snow estimates. In addition, the team continues to examine a radiometer-only module to estimate light precipitation over oceans. This module will be included in the next version (V08) of CORRA. The team is also looking at the consequences of the GPM orbit boost.

Goddard Profiling Algorithm for GMI

The Goddard Profiling Algorithm (GPROF) team continues to work on well-known issues. The V07 update includes improvements in the a priori database to help constrain outputs from GPM constellation radiometers as well as inclusion of the radiometers on TROPICS and NASA’s Temporal Experiment for Storms and Tropical Systems–Demonstration (TEMPEST-D). The two new neural network-based implementations of GPROF in V08 are anticipated in roughly a year. The team reported that they have no issues with the GPM orbit boost.

Integrated Multi-Satellite Retrievals for GPM Algorithm

The IMERG algorithm team reported on V07, which includes a wide range of algorithm changes from V06. V07 includes retrospective reprocessing of the entire TRMM–GPM record and thus supersedes all previous versions. The team also reported that the algorithm changes improve the performance of IMERG estimates both in terms of its precipitation detection and systematic and random bias. The presenters noted improvements over frozen, orographic, and coastal surfaces. The team is now working on priority items that need completing in order to implement V08.

Convective–Stratiform Heating Algorithm

The GSFC Convective–Stratiform Heating (CSH) algorithm team provided an overview on latent heating (LH) retrievals. The presentation highlighted some of the details in updating to V07, including more accurate cloud-resolving model (CRM) simulations (using 3D domain rather than two-dimensional) and new detailed radiation retrievals. V07 is also “terrain aware,” meaning that the algorithm includes added details of radiative heating profiles and eddy transport terms. For V08, the CSH team plans to have a new 3D CRM database with a grid size of 250 m (820 ft) and look-up tables (LUTs) for non-surface raining columns for the tropical/summertime part of the algorithm as well as LUTs for terrain. These V08 improvements are still in development as of this meeting.

Science Results and Data Quality

A large component of the meeting was dedicated to presentations by NASA PMM-funded Principal Investigator (PI) teams on the science research and applications being achieved using PMM data. PI oral presentations were divided into four thematically focused topical sessions: Precipitation Microphysics, Snow and Hail, Storm Analysis, and Data Uncertainty. The subsections that follow highlight scientific results from each of these sessions. The reader is referred to the full reports online for more details.

Precipitation Microphysics

Presenters during this session described various techniques and new methodologies to study microphysical properties of precipitation including shape and size of precipitation particles (e.g., drop size distribution (DSD)), phase identification (e.g., liquid, solid, and mixed phase/melting), scattering properties, and precipitation rate, using both radar and radiometer observations. These property measurements play a pivotal role in improving precipitation retrieval algorithms, allowing scientists and decision makers to better understand and forecast storms.

One presenter in this session discussed new methods for classifying different types of precipitation (e.g., rain, graupel, hail, and dry and wet snow) using DPR precipitation retrievals. The new technique will be implemented into the V08 DPR algorithm. The discussion also covered a technique to establish relationships between GMI brightness temperature and hydrometeor type (e.g., rain, snow, graupel, and hail), leveraging the GPM validation network to construct LUTs of hydrometeor type likelihood – see Figure 2. Another presenter introduced a model to understand how DSD changes near the surface can be used to estimate rainfall rate. The last presenter in this session discussed the development of a precipitation scattering property database—which includes scattering characteristics of about 10,000 different types of ice particles. The database includes scattering cross sections calculated in thousands of orientations for each type of particle. This database is accessible to the public, which helps support the development of physically based scattering calculations and improvement of precipitation retrieval algorithms for both radar and radiometers.

Figure 2. A technique for retrieving hydrometeor information from GMI brightness temperature. In these RGB plots, snow and rain are combined into one category (green), while the individual probabilities are retained in the lookup tables.Figure credit: Dan Cecil/NASA’s Marshall Space Flight Center (MSFC)

Snow and Hail

In this session, speakers discussed a broad move toward satellite retrievals for frozen hydrometeors, not just to identify bulk effects (e.g. snow or hail accumulation at the surface), but also to gather information on physical properties of frozen hydrometeors (e.g., where hailstones reside within clouds or what shapes snowflakes take). Understanding frozen hydrometeor properties can significantly improve precipitation and latent heat estimates that are essential for numerical weather forecasting and climate model development.

One speaker applied a method that used DPR and GMI observations to estimate frozen precipitation particle properties for an Olympic Mountain Experiment (OLYMPEX) field campaign case. The results he showed indicated a significant difference in the shapes of snowflakes between land and sea. Another speaker detailed the use of a simple machine learning framework trained on measurements of the use of snowfall and cloud type observations from the CloudSat Cloud Profiling Radar (CPR) to infer surface snowfall from GMI microwave measurements. Other presenters conveyed the results of a study examining different potential indicators of hail within the GPM database. These hail indicators were mapped, and the mean vertical profiles of radar reflectivity and storm structure were contrasted. The final pair of presentations focused on detecting hail in South America and Africa. In South America, hail-producing storms were shown to be strongly linked to local topography – in contrast to hotspots of hail in the U.S. Meanwhile, in Africa, new algorithms for identifying hail in GPM data suggest hail should be common – but this outcome is at odds with ground truth observations. This test case is being used to develop new methods for retrieving hail that include analyzing horizontal profile information within the data.

Storm Analysis

Presenters in this session discussed a variety of applications and assessments of PMM products for analyzing a variety of storms, particularly their cloud, precipitation, and kinematic structures and their structural evolution. The first speaker compared precipitation events simulated in IMERG to the same event with rain gauge observations. They found that while IMERG missed many winter precipitation events in mountainous regions –which rain gauges typically can measure – IMERG also captured summer virga events – which rain gauges typically miss. Another presenter compared IMERG to river catchment and integrated watershed observations and found that IMERG overestimated small precipitation events but underestimated large events. The next presenter showed a comparison IMERG simulations to the multi-instrument MRMS dataset during the lifecycle of precipitation events. The results shown suggest that IMERG errors in precipitation intensity could be improved by inputting other variables (e.g., ice water path or vertical velocity) into the precipitation retrievals. The discussions during this session also covered other plans to use PMM products to study convection in atmospheric river events, in combination with a modeling analysis using different convection schemes. The final pair of presenters spoke about understanding convective-scale drivers of the Inter Tropical Convergence Zone ascent and widening the use of a simple prognostic model that will use PMM data for filling terms in the model. One model weakness is the decay term for the convection cloud shield, which, if determined, could reduce error in climate models, particularly with radiative processes. The final speaker used TRMM Visible and Infrared Scanner (VIRS) data to develop and test a method for identifying and classifying cloud areas (i.e., core, midrange extent, and outer bound split window testing) and determine their relationships to other environmental variables, such as sea surface temperatures and column water vapor.

Data Uncertainty

Presenters during this session discussed new methodologies to address data uncertainties and bias in precipitation retrievals to improve precipitation estimates for science and applications research. Two of the presenters delved into the details of how the GPROF algorithm has inherent precipitation biases due to different hydrometeor characteristics captured by GMI passive microwave brightness temperature – which may be related to thermodynamic environments. Another PI presented updates for improving uncertainty estimates to enhance hydrological prediction. Specifically, he discussed multiscale precipitation uncertainties in precipitation products, including a new product that combines the Space-Time Rainfall Error and Autocorrelation Model (STREAM) with single-orbit rainfall estimates from the combined GPM data product, called STREAM-Sat. He explained how the uncertainties in these products can influence hydrologic prediction. The session concluded with a discussion of machine learning methods to estimate the probability distribution of uncertainties in passive microwave precipitation retrievals at different temporal and spatial scales.

Discussion of Future Missions, Observations, and Activities Relevant to GPM

This session featured presentations on several other existing and upcoming missions in various stages of development, as well presentations covering the future of precipitation instruments and observations, each with applications relevant to GPM. Each presentation included information on plans to advance and support precipitation science in the near term and the coming decade, as described below.

TROPICS

The TROPICS Pathfinder CubeSat mission provides microwave observations of tropical cyclones with less than a 60-minute revisit time to capture better storm dynamics and improve forecasting. The Pathfinder has demonstrated all mission elements and provided new tropical cyclone imagery (12,000+ orbits and counting). The Cal/Val team hopes to release the data to the public in Fall 2023. (UPDATE: Provisional TROPICS data was released in January 2024.) The TROPICS pathfinder satellite showed that the compact TROPICS design performs comparably to the state-of-the-art sounders. Lessons learned will help the TROPICS Team as they work to improve efforts and operate the TROPICS constellation, which now holds a total of five satellites.

AOS

As discussed in Will McCarty’s remarks, AOS is a key component of the Earth System Observatory that was recommended in the 2017 Decadal Survey. The mission will deliver transformative observations fundamental to understanding coupled aerosol– and cloud–precipitation processes that profoundly impact weather, climate, and air quality. Two AOS projects are in the mission concept and technology development phase (Phase-A): AOS-Storm (to launch late 2020s), with a Ku Doppler radar, microwave radiometers, and backscatter lidar in a 55° inclined orbit; and AOS-Sky (to launch early 2030s) with cloud-profiling Doppler radar, backscatter lidar, microwave radiometer, polarimeter, far infrared (IR) radiometer, and aerosol and moisture limb sounders in polar orbit. (This paragraph reflects what was discussed during the meeting, however, AOS is undergoing changes that will be reflected on the website at a later date.)

GPM Microwave Radiometer Constellation in the Next Decade

The future passive microwave radiometer constellation looks robust, with multiple sensors to be launched in the next decade. Small/CubeSat constellations are becoming a reality, and a plan to incorporate them quickly into the overall precipitation constellation is needed. A point of emphasis was that a sensor in an inclined orbit is a necessity when it comes to providing a reference measurement to support this effort – see Figure 3.

Figure 3. Evaluation of passive microwave (PMW) frequencies and coverage to assess data gaps and needs for the future of precipitation constellation.Figure credit: Rachael Kroodsma/GSFC

JAXA Precipitation Measuring Mission (JAXA PMM) Radar

Plans call for JAXA’s next generation of precipitation radar to be deployed as part of the agency’s future Precipitating Measuring Mission (PMM – yes, the same acronym as the Precipitation Measurement Mission). Objectives for this next-generation precipitation radar include Doppler observations, higher sensitivity measurements, and scanning capability. JAXA has collaborated with a Japanese science team and user community to explore the feasibility of a next-generation, dual-frequency precipitation radar. The discussion focused on the importance of measuring convection through Doppler velocities from spaceborne radar. The EarthCARE mission will feature the first Cloud Profiling Radar (CPR) with Doppler capability in space. JAXA has participated in NASA’s AOS Pre-Phase A activities. The synergy between the GPM DPR and PMM/KuDPR is expected to contribute to the construction of a longer-term precipitation dataset by providing overlapping observations.

Update on Cloud Services at NASA GES DISC

NASA’s Goddard Earth Sciences Data and Information Services Center (GES DISC), one of two data archive centers for GPM, is moving its data archive to the cloud – with all GES DISC data and services remaining free to all users. This will offer quick access to and subsetting capability for a large volume of data through multiple data access methods (e.g., Amazon Simple Storage Service) and cloud services. Multidisciplinary NASA data will be in one place – the Earthdata Cloud – and available for online analysis and in the cloud environment. Expanded services (e.g., access to the Common Metadata Repository–SpatioTemporal Asset Catalog (CMR-STAC), Harmony – a collective Earth Observing System Data and Information System (EOSDIS) effort to make data access more consistent and easier across all DAACs and Zarr – a data format designed to store compressed multidimensional arrays and thus well suited to cloud computing) are expected to be implemented in the near future. With the migration of GES DISC data to the cloud, some services may look different with details on the exact changes to services coming soon.

GPM Core Observatory Boost

As George Huffman discussed in his presentation, based on forecasted solar activity, the GPM Core Observatory could run out of fuel as early as October 2025 if the current orbit altitude is maintained. To prolong its operations, NASA and JAXA have decided to boost the GPM Core Observatory orbit by ~35 km (~22 mi), which places GPM at an altitude of ~435 km (~270 mi)) – placing it above the International Space Station orbital altitude. The post-boost operations of the satellite are expected to continue through the early 2030s. The boost is expected to last only 2–4 days and occur in the time window between November 2023 and March 2024 (likely November 7–9, 2023, as stated above), the boost will permanently change the sensors’ Field of Views (FOVs) and likely cause a gap of several months in DPR product delivery.

Precipitation in 2040

Sarah Ringerud [GSFC] and George Huffman led this plenary discussion that explored two questions: What comes next? and What does the cutting edge of precipitation science look like 20 years from now? CubeSats, reduced volume of low-frequency-channel observations, shorter sensor lifetimes, increased sampling, and calibration challenges are recognized as inevitable. Exciting new developments are seen in the opportunity for data fusion and interdisciplinary work. Interagency and private sector collaborations are foreseen as critical points for maintaining optimal monitoring of Earth precipitation.

Conclusion

The 2023 PMM STM brought together scientists from around the world to engage on a range of topics that advance the understanding of precipitation science, algorithms, and contributions to applications. The STM highlighted updates and activities enabled by the PMM scientific community. The closing session provided an opportunity for quick updates from precipitation working group members, who held splinter sessions. These updates were followed by an open discussion and review of PMM action items led by George Huffman. He reminded PMM STM participants of several important and noteworthy items, including updates on the orbit boost and subsequent algorithm adjustments, which will be available on the GPM website and be at the forefront for the project for the next six months; V08 of GPM data products are anticipated by early 2026; the budget reduction for the project – but not for current ROSES projects – will impact activities, including next year’s PMM STM; and the next NASA ROSES call might have a different package of opportunities, not strictly focused on PMM/GPM. He concluded by encouraging the PMM ST to share highlights and publications with the GPM Science Program Management Team as well as to continue to initiate collaborations with other colleagues to keep pushing the boundaries of science and outreach.

The next PMM STM will likely be held in September 2024. Details will be posted on the GPM website once they become available.

Acknowledgements The author would like to recognize the following individuals, all of whom made contributions to this article: Ali Behrangi [University of Arizona], Anthony Didlake [Penn State University], Gerry Heymsfield [GSFC], George Huffman [GSFC], Matthew Igel [University of California Davis], Toshio Iguchi [Osaka University], Dorian Janney [GSFC/ADNET Systems], Chuntao Liu [Texas A&M Corpus Christi], Veljko Petkovic [UMD], Courtney Schumacher [Texas A&M Corpus Christi], and Joe Turk [NASA/Jet Propulsion Laboratory].

9 Min Read Lagniappe for June 2024 Explore the June 2024 issue, featuring an innovative approach to infrastructure upgrades, how NASA Stennis has helped one family build a generational legacy and more! Explore Lagniappe for June 2024 featuring:

• NASA Employs Innovative Approach for Key Test Infrastructure Upgrade
• NASA Stennis Helps Family Build a Generational Legacy
• Employees Receive Awards and Recognitions

Gator Speaks Gator SpeaksNASA/Stennis

Gator is certain you have heard the saying, “Together, Everyone Achieves More” when referencing a benefit that comes with being part of a team.

Whether you are a high school or college student graduating at this time of year, or an employee at NASA’s Stennis Space Center receiving a NASA Honor Award or Space Flight Awareness Honoree Award last month, we all reach a point where we recognize the positive impact others have had on where we are in life.  

Since NASA’s founding in 1958, the agency has pushed the boundaries of scientific and technical limits to explore the unknown.

NASA has accomplished great things benefiting all of humanity because of people from all backgrounds coming together to contribute their skills as one team to further understanding of the universe.

This month’s Lagniappe features multiple pieces of evidence where teamwork is the underpinning to success, including the ongoing High Pressure Water Industrial Facility project at NASA Stennis and a story highlighting one family’s role as part of larger team contributing to the successful engine testing that has taken place for decades at the south Mississippi site.

If you need one last example of the benefit of coming together to achieve more, look no further than the Artemis Accords. A milestone was reached in May when Lithuania became the 40th nation to join NASA and the international coalition pursuing a safer space exploration by signing the Artemis Accords.

Whether graduating high school or college, working at NASA, or joining the Artemis Accords with NASA, there is a good chance we all eventually arrive at a similar conclusion. While we can accomplish great things individually, being part of a team ultimately means that together, everyone achieves more.

NASA Stennis Top News NASA Employs Innovative Approach for Key Test Infrastructure Upgrade

Crews are using an innovative engineering approach to upgrade an essential test complex water system that will help ensure the future of large propulsion testing at NASA’s Stennis Space Center near Bay St. Louis, Mississippi.

Read More About the Infrastructure Upgrades Center Activities NASA Stennis Helps Family Build a Generational Legacy

For Lee English Jr., the sound of a ringing phone probably sounds a lot like the roar of a rocket engine test at NASA’s Stennis Space Center near Bay St. Louis, Mississippi.

Read More About the English Family's Multi-Generational Legacy NASA’s Stennis Space Center Employees Receive NASA Honor Awards

NASA Stennis Space Center Director John Bailey and NASA Associate Administrator for Space Operations Kenneth Bowersox presented NASA Honor Awards to Stennis employees during an onsite ceremony May 15.

Read More About the NASA Stennis Award Recipients NASA Employee Earns Senior Executive Service Status Eli OuderNASA

Longtime NASA employee Eli Ouder has achieved federal Senior Executive Service (SES) status and has been chosen director for the Office of Procurement for NASA’s Stennis Space Center and the NASA Shared Services Center, both located near Bay St. Louis, Mississippi.

Created in 1979, SES classification is designed for federal employees who use well-developed executive skills to administer programs at the highest levels of government. The leadership program requires candidates to demonstrate skills in five key areas – leading change, leading people, results driven, business acumen, and building coalitions.

Ouder has served as procurement officer since 2022 for NASA Stennis and the NASA Shared Services Center. During this time, he has led a combined 177-person procurement office responsible for managing a diverse and complex procurement portfolio valued at over $7 billion.

This broad and high-volume portfolio includes the responsibility of overseeing local Center Support Contracts, Grants and Cooperative Agreements, Small Business Innovative Research contracts, Small Business Technology Transfer program support, Enterprise Software Procurements, agencywide Enterprise Contracts, Simplified Acquisition Threshold Purchases, Government Purchase Card Program management, and other activities in support of the NASA enterprise. 

During more than 18 years with NASA, Ouder has served in numerous roles while managing and leading the NASA Shared Services Center, including as chief of the Simplified Acquisition Threshold Branch. In that role, Ouder led a major transition of approximately 4,000 Simplified Acquisitions annually from 10 NASA centers to the NASA Shared Services Center. He continued to serve in the role until January 2022 when he became procurement officer for the services center. In December 2022, Ouder was assigned as procurement officer at NASA Stennis as well. 

2024 Hurricane Guide

Explore essential information for employees at NASA’s Stennis Space Center to navigate the 2024 hurricane season.

Download the New Hurricane Guide NASA Space Flight Awareness Program Recognizes Stennis Employees NASA astronaut and Artemis II crew member Victor Glover stands with Honoree Award recipients from NASA’s Stennis Space Center following presentation of the awards during NASA’s Space Flight Awareness Program ceremony on May 4 in Orlando, Florida. Recipients (and their companies), along with ceremony presenters were: (left to right) NASA Stennis Associate Director Rodney McKellip, Shelly Lunsford (SaiTech Inc.), Odie Ladner (Aerojet Rocketdyne, an L3 Harris Technologies company), Rachel Deschamp (Alutiiq Essential Services), Peyton Pinson (NASA), Jack Conley (NASA), Ronnie Good (NASA), and Glover. NASA/Kennedy Space Center

NASA’s Stennis Space Center employees were recognized with Honoree Awards from NASA’s Space Flight Awareness Program during a May 4 ceremony in Orlando, Florida, for outstanding support of human spaceflight.

Jack Conley of Biloxi, Mississippi, is a NASA engineer in the Mechanical Operations Branch of the Engineering and Test Directorate at NASA’s Stennis Space Center near Bay St. Louis, Mississippi. He was honored for his performance in test operations support of NASA’s core spaceflight mission. As backup test conductor, his work was instrumental in the successful Green Run testing of NASA’s SLS (Space Launch System) core stage at NASA Stennis prior to its use on the Artemis I mission.

Rachel Deschamp of Pass Christian, Mississippi, is an order clerk for Alutiiq Essential Services at NASA Stennis. She was recognized for attention to detail and commitment to success in enabling Alutiiq’s ability to meet and support NASA Stennis’ requirements.

Ronnie Good of Waveland, Mississippi, is a NASA engineer in the Safety, Quality and Management Systems Division of the Safety and Mission Assurance Directorate at NASA Stennis. He was recognized for contributions in leading a year-long systems transition used to record facility safety inspections and manage safety findings for NASA Stennis’ test and institutional facilities.

Odie Ladner of Poplarville, Mississippi, is a lead welder and test technician for Aerojet Rocketdyne, an L3 Harris Technologies company, at NASA Stennis. Ladner was recognized for his commitment and support of human spaceflight initiatives and programs and performance of weld repairs to RS-25 nozzle tubes in support of certification testing at NASA Stennis.

Shelly Lunsford of Long Beach, Mississippi, is a senior forms designer for SaiTech Inc. at NASA Stennis. She was honored for her professionalism and dedication in consolidating NASA Stennis and NASA Shared Services Center’s forms to enable customers and users to increase efficiency and create valid data and reports.

Peyton Pinson of Madison, Mississippi, is a NASA engineer in the Mechanical Operations Branch of the Engineering and Test Directorate at NASA Stennis. He was honored for his performance in test operations support to NASA’s core mission of spaceflight. As a mechanical test operations engineer, Pinson supports propulsion activities across the NASA Stennis test complexes.

NASA astronaut Victor Glover, Space Operations Mission Directorate Associate Administrator Kenneth Bowersox, Exploration Systems Development Mission Directorate Associate Administrator Catherine Koerner, and NASA Stennis Associate Director Rodney McKellip presented the Honoree Awards.

Glover was selected as a NASA astronaut in 2013 and is currently assigned as the pilot of NASA’s Artemis II mission to the Moon. He previously served as the pilot of NASA’s SpaceX Crew-1 mission to the International Space Station as part of Expedition 64.

In recognition of flight program contributions, the Stennis employees toured NASA’s Kennedy Space Center in Florida and participated in activities in conjunction with the first launch attempt of NASA’s Boeing Crew Flight Test of the Starliner spacecraft. The Crew Flight Test will launch Starliner and NASA astronauts Butch Wilmore and Suni Williams on a United Launch Atlas V rocket to the International Space Station as part of the agency’s Commercial Crew Program.

NASA’s Space Flight Awareness Program recognizes outstanding job performances and contributions by civil service and contract employees throughout the year and focuses on excellence in quality and safety in support of human spaceflight. The Honoree Award is one of the highest honors presented to employees for their dedication to quality work and flight safety. Recipients must have contributed beyond their normal work requirements toward achieving a particular human spaceflight program goal; contributed to a major cost savings; been instrumental in developing material that increases reliability, efficiency or performance; assisted in operational improvements; or been a key player in developing a beneficial process improvement.

For information about Space Flight Awareness awards, visit:

Spaceflight Awareness Awards and Criteria – NASA

For information about NASA’s Stennis Space Center, visit:

Stennis Space Center – NASA

NASA Stennis Leaders Attend Aerospace and Defense Symposium NASA Stennis Center Director John Bailey, right, is shown at the Mississippi Enterprise for Technology’s Mississippi Aerospace and Defense Symposium in Oxford, Mississippi. Bailey and Strategic Business Development Office Manager Duane Armstrong joined fellow aerospace and defense industry leaders and experts to explore opportunities and challenges facing the sector in the state during the event April 29 through May 2. Ole Miss Digital Imaging Services/Thomas Graning NASA Stennis Leaders Recognize Employees for Working Safely Rodney McKellip, associate director of NASA’s Stennis Space Center, and Gary Benton, director of the NASA Stennis Safety and Mission Assurance Directorate, are shown, from right to left, with employees working on the High Pressure Industrial Water Facility project near the Fred Haise Test Stand. The NASA Stennis leaders visited work sites on May 8 to recognize employees with NASA SHAKERS (Smart Human Actions Keep Everyone Really Safe) Awards for conducting work in a safe manner. NASA’s constant attention to safety, one of the agency’s five core values, is the cornerstone for mission success. Gary Parker, an employee with Healtheon, Inc., is presented a NASA SHAKERS (Smart Human Actions Keep Everyone Really Safe) Award from NASA Stennis Associate Director Rodney McKellip on May 8. Parker, left, received the award for leadership and dedication to safety of the crew working to upgrade an essential test complex water system at NASA Stennis. As one of the crew leaders, Parker ensured all took the safest approach for each task, even as the scale of the project increased. NASA’s constant attention to safety, one of the agency’s five core values, is the cornerstone for mission success. Matt Roberts, an employee with Healtheon, Inc., is presented a NASA SHAKERS (Smart Human Actions Keep Everyone Really Safe) Award from NASA Stennis Associate Director Rodney McKellip on May 8. Roberts, left, received the award for leadership and dedication to safety of the crew working to upgrade an essential test complex water system at NASA Stennis. As one of the crew leaders, Roberts ensured all took the safest approach for each task, even as the scale of the project increased. NASA’s constant attention to safety, one of the agency’s five core values, is the cornerstone for mission success. Joshua Laurent, an employee with Civil Works Contracting, is presented a NASA SHAKERS (Smart Human Actions Keep Everyone Really Safe) Award from NASA Stennis Associate Director Rodney McKellip on May 8. Laurent, left, received the award for continuously demonstrating safe work habits, utilizing the proper personal protective equipment for each task, and always considering environmental factors and hazards within the work area while working on the NASA Stennis potable water system. NASA’s constant attention to safety, one of the agency’s five core values, is the cornerstone for mission success. NASA in the News

• NASA Earns Best Place to Work in Government for 12 Straight Years – NASA
• X-59 Passes Milestone (nasa.gov)
• Artemis Accords Reach 40 Signatories as NASA Welcomes Lithuania – NASA
• NASA Tests Technology, Practices Artemis Moonwalks in Arizona Desert – NASA

Employee Profile Cassi Meyer, attorney-adviser for the NASA Office of the General Counsel, is pictured at her home office in Cleveland, where she supports NASA’s efforts to collaborate with commercial industry at NASA’s Stennis Space Center near Bay St. Louis, Mississippi. NASA/Cassi Meyer

Cassi Meyer can certainly testify that the nontraditional path taken from law school to NASA has landed her in the right place to work with the diverse workforce at NASA’s Stennis Space Center near Bay St. Louis, Mississippi.

Read More About Cassi Meyer Looking Back: Seeing the Engine Up Close NASA Administrator Robert Frosch (left), along with astronaut candidates Sally Ride and Terry Hart, get a close look at a space shuttle main engine installed on the B-2 Test Stand at Stennis Space Center, then known as National Space Technology Laboratories, during a visit on June 1, 1979. A space agency filled with trailblazers, the late Sally Ride was a pioneer of a different sort. The soft-spoken California physicist broke the gender barrier on June 18, 1983, when she became the first American woman in space. Meanwhile, Hart flew as a mission specialist on STS-41C (April 6-13, 1984) and logged a total of 168 hours in space.NASA Additional Resources

• NASA Stennis Overview – Going Further
• Certifying Artemis Rocket Engines – NASA

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Lagniappe is published monthly by the Office of Communications at NASA’s Stennis Space Center. The NASA Stennis office may be contacted by at 228-688-3333 (phone); ssc-office-of-communications@mail.nasa.gov (email); or NASA OFFICE OF COMMUNICATIONS, Attn: LAGNIAPPE, Mail code IA00, Building 1111 Room 173, Stennis Space Center, MS 39529 (mail).

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To subscribe to the monthly publication, please email the following to ssc-office-of-communications@mail.nasa.gov – name, location (city/state), email address.

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Explore the NASA Stennis newsletter, Lagniappe for May 2024. This issue features NASA’s announcement of…

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NASA/NICER

Esta imagen de todo el cielo muestra 22 meses de datos de rayos X registrados por la carga útil del Explorador de la Composición Interior de las Estrellas de Neutrones (NICER, por sus siglas en inglés) de la NASA —que viaja a bordo de la Estación Espacial Internacional— durante sus barridos nocturnos entre los diferentes objetivos a los que apunta.

Las principales metas de NICER requieren que esté apunte hacia las fuentes de energía cósmica y siga su recorrido, a medida que la estación espacial hace su órbita alrededor de la Tierra cada 93 minutos. Pero cuando el Sol se pone y la noche cae en este puesto de avanzada orbital, el equipo de NICER mantiene activos sus detectores mientras el instrumento pasa de un objetivo a otro, lo que puede ocurrir ocho veces durante cada órbita.

Cada arco marca el recorrido de los rayos X, así como los impactos ocasionales de partículas energéticas, que son captados durante estos movimientos nocturnos. El brillo de cada punto de la imagen es el resultado de estas contribuciones, así como del tiempo que NICER ha dedicado a mirar en esa dirección. Un resplandor difuso satura de rayos X el cielo, incluso lejos de las fuentes donde se origina el brillo.

Vista del telescopio NICER, sujeto a la plataforma externa de alojamiento de carga útil de la estación espacial.NASA Descubre más temas de la NASA

Ciencia en la estación

NASA en español

Explora el universo y descubre tu planeta natal con nosotros, en tu idioma.

Aeronáutica en español

Space Station Research and Technology

A Russian military satellite with a "history of unusual maneuvering" was spotted as it approached a satellite in geostationary orbit in April 2024.

Cassi Meyer, attorney-adviser for the NASA Office of the General Counsel, is pictured at her home office in Cleveland, where she supports NASA’s efforts to collaborate with commercial industry at NASA’s Stennis Space Center near Bay St. Louis, Mississippi. NASA/Cassi Meyer

Cassi Meyer can certainly testify that the nontraditional path taken from law school to NASA has landed her in the right place to work with the diverse workforce at NASA’s Stennis Space Center near Bay St. Louis, Mississippi.

The attorney-adviser is part of the General Law practice group for the NASA Office of the General Counsel, supporting NASA Stennis and the NASA Shared Services Center.  Meyer’s responsibilities include advising and counseling in areas such as commercial partnerships, FOIA, environmental law, safety and security, export control, ethics, and memoranda of understanding and other agreements in furtherance of NASA’s strategic goals.

NASA Stennis truly exemplifies how the agency works together for the benefit of all…It is where NASA collaborates with commercial industry and federal city tenants to achieve success and build a place the Gulf Coast area can unite and thrive around for years to come.

Cassi Meyer

Attorney-adviser, NASA Office of the General Counsel

A large part of Meyer’s work with NASA Stennis focuses on the agency’s collaboration with commercial industry at the largest propulsion test site in the United States.

“Everything NASA is doing is so incredibly interesting and inspiring to me as a legal professional,” she said. “We are really here to work with our innovative clients and advise them as to risks and courses of action so that we can get the job done right and efficiently.”

Meyer enjoys her role as a legal counselor, which she describes as a way to “help our clients help NASA achieve the agency’s goals, projects, and missions while the next era of space exploration bounds forward.”

The Macedonia, Ohio, native first supported NASA as a contractor paralegal in the Office of the General Counsel at NASA’s Glenn Research Center in Cleveland, while taking night classes at the University of Akron School of Law to earn her juris doctorate degree. She continued as a legal honors intern at NASA Glenn for eight months before graduating magna cum laude and taking the bar exam.

Meyer started as a law clerk with NASA Stennis in a teleworking capacity around the time she received news about passing the bar. Shortly after, she was hired in her current role of attorney-adviser working with the Center. To date, Meyer has visited seven of the 10 NASA centers to gain a better understanding of NASA culture and operations, including NASA Stennis multiple times in the past year. 

“Stennis goes the extra mile, and the workforce has been so kind, courteous, and competent,” she said. “There is always someone happy to jump in to teach you something if you do not understand. That’s important in my role as there is a lot of technical expertise needed at times for us lawyers to give the best and most comprehensive counsel we can.”

Meyer has embraced the continuous learning experience, which includes building relationships with those that are part of the federal city at the south Mississippi site.

 “NASA Stennis truly exemplifies how the agency works together for the benefit of all,” she said. “It is where NASA collaborates with commercial industry and federal city tenants to achieve success and build a place the Gulf Coast area can unite and thrive around for years to come.”

For information about NASA’s Stennis Space Center, visit:
Stennis Space Center – NASA

Learn more about the people who work at NASA Stennis

NASA Associate Administrator for Space Operations Kenneth Bowersox speaks to NASA Stennis employees during the onsite NASA Honor Awards ceremony on May 15. NASA/Danny Nowlin NASA Stennis Space Center Director John Bailey speaks to NASA Stennis employees during the onsite NASA Honor Awards ceremony on May 15.NASA/Danny Nowlin NASA Stennis Space Center Director John Bailey receives the Meritorious Senior Executive Presidential Rank Award from NASA Associate Administrator for Space Operations Kenneth Bowersox during the NASA Honor Awards on May 15 at NASA Stennis. Bailey is pictured, from left, with his wife, Lori; daughter, Isabella; and Bowersox. NASA/Danny Nowlin

NASA Stennis Space Center Director John Bailey and NASA Associate Administrator for Space Operations Kenneth Bowersox presented NASA Honor Awards to Stennis employees during an onsite ceremony May 15.

Prior to presenting NASA Honor Awards to Stennis employees, Bailey received the Meritorious Senior Executive Presidential Rank Award. The award from the President of the United States is one of the highest awards given to career Senior Executive Service employees.

Since joining NASA in 1999, Bailey has served in various management and leadership roles. He was named NASA Stennis center director in April. As director, Bailey is responsible for implementing NASA’s mission in rocket propulsion testing and developing and maintaining NASA’s world-class rocket propulsion test facilities. He has provided leadership and managed critical rocket propulsion test assets exceeding $2 billion in replacement value and managed projects over $221 million.

One NASA Stennis employee received NASA’s Outstanding Leadership Medal. The medal is awarded to government employees for notable leadership accomplishments that have significantly influenced the NASA mission.

NASA Honor Awards Recipients MIchael TubbsNASA/Stennis

Michael Tubbs of Diamondhead, Mississippi, received the NASA Outstanding Leadership Medal for his work as deputy director of the Office of Strategic Infrastructure within the Center Operations Directorate at NASA Stennis. The Yorktown, Virginia, native ushered in improvements and new initiatives that have helped achieve a cultural transformation and millions in cost-saving measures. His accomplishments also include leading the efforts to complete lease agreements between NASA and Rocket Lab of America for use of the A-3 Test Stand and between NASA and Relativity Space for use of the A-2 Test Stand.

Five NASA Stennis employees received NASA’s Exceptional Service Medal. The medal is awarded to government employees for sustained performance that embodies multiple contributions to NASA projects, programs, or initiatives.

David LoranceNASA/Stennis

David Lorance of Slidell, Louisiana, received the NASA Exceptional Service Medal for his efforts in furthering the NASA mission through leadership of the Environmental and Health Services Office Division in the Center Operations Directorate at NASA Stennis. Lorance has been responsible for ensuring compliance with numerous environmental programs, managing resources to ensure requirements are met with no impact to mission projects, managing hundreds of regulatory reports for submission on time, and ensuring environmental permits are maintained.

Bradley MesserNASA/Stennis

Brad Messer of Santa Rosa Beach, Florida, received the NASA Exceptional Service Medal for more than 32 years of service to NASA. Since joining NASA in 1991, Messer has contributed to a variety of propulsion test and engineering projects. As assistant director of the NASA Stennis Engineering and Test Directorate in charge of the Office of Project Management, Planning and Control, he has been responsible for the day-to-day business operations and project activities across the test complex. Messer has also made significant contributions to the strategic planning and execution of activities essential to the future state of the test complex.

Kevin PowerNASA/Stennis

Kevin Power of Mandeville, Louisiana, received the NASA Exceptional Service Medal for more than 34 years of service to NASA. As deputy assistant director for the Office of Project Management, Planning and Control in the Engineering and Test Directorate at NASA Stennis, the Port Sulphur, Louisiana, native has consistently delivered support to the NASA Stennis vision and mission. He has helped accomplish center, NASA, and national goals by providing management and engineering leadership, expertise, resources, and guidance to multiple NASA and commercial propulsion test projects, including some of the center’s most critical test infrastructure efforts.

Cecile SaltzmanNASA/Stennis

Cecile Saltzman of Pass Christian, Mississippi, received the NASA Exceptional Service Medal for more than 20 years of service to the NASA Stennis Engineering and Test Directorate. Saltzman’s work has included management of the directorate document process control function, ensuring NASA Stennis test complex assets and support facilities are operated, utilized, and continually improved in providing premier testing services to NASA and commercial customers. The Thibodaux, Louisiana, native has consistently exceeded the agency’s timeline for editing fiscal year accomplishments of all NASA Stennis senior executive service and senior level personnel.

John StealeyNASA/Stennis

John Stealey of Diamondhead, Mississippi, received the NASA Exceptional Service Medal for more than 35 years of service to NASA, including 26 years at NASA Stennis. The Granville, Tennessee, native has contributed to a range of agency and center projects. Among his accomplishments, Stealey has assisted in overseeing strategic planning for NASA Stennis propulsion test facilities and workforce. He has served in various center roles, including as deputy of the Safety and Mission Assurance Directorate and assistant director of the Engineering and Test Directorate. He also served on the agency-level Exploration System Directorate Standing Review Board, providing expert advice on systems engineering and project management.

One NASA Stennis employee received NASA’s Exceptional Public Service Medal. The medal is awarded to non-government individuals or to an individual who was not a government employee during the period in which the service was performed for sustained performance that embodies multiple contributions on NASA projects, programs, or initiatives.

Rodney KingNASA/Stennis

Rodney King of Picayune, Mississippi, received the NASA Exceptional Public Service Medal for efforts as the facility maintenance supervisor on the Synergy-Achieving Consolidated Operations and Maintenance contract at NASA Stennis. In that role, King has been responsible for electrical and high voltage work at the site. King’s service-centered approach has rendered him successful in technical work activities and how he relates to customers, management, peers, and direct reports. He has been recognized by organizations throughout the NASA Stennis federal city for his quick response to outages or calls within their facilities.

Four NASA Stennis employees received NASA’s Exceptional Bravery Medal. The medal is awarded to both government and non-government individuals for exemplary and courageous handling of an emergency by an individual who, independent of personal danger, has acted to prevent the loss of human life and/or government property.

Barry HodaNASA/Stennis

Barry Hoda of Kiln, Mississippi, received the NASA Exceptional Bravery Medal for exemplary and courageous actions while responding to a medical emergency at NASA Stennis to prevent the loss of human life on Dec. 7, 2022. An officer with Chenega Global Protection, Hoda noted the employee was unresponsive, and no pulse or respiration were detected. Hoda immediately began cardiopulmonary resuscitation (CPR) and then synchronized CPR chest compressions with other respondents, ensuring a continuous, uninterrupted blood supply to the employee’s brain. The rapid response and coordinated effort were directly responsible for saving a life.

Leeanna Dunigan of Diamondhead, Mississippi, received the NASA Exceptional Bravery Medal for exemplary and courageous actions while responding to a medical emergency at NASA Stennis to prevent the loss of human life on Dec. 7, 2022. A captain with Chenega Global Protection, Dunigan helped provide cardiopulmonary resuscitation (CPR) to the employee in distress by synchronizing CPR chest compressions with other respondents, ensuring a continuous, uninterrupted blood supply to the employee’s brain. The rapid response and coordinated effort were directly responsible for saving a life.

Brenden Burns of Gulfport, Mississippi, received the NASA Exceptional Bravery Medal for exemplary and courageous actions while responding to a medical emergency at NASA Stennis to prevent the loss of human life on Dec. 7, 2022. An officer with Chenega Global Protection, Burns utilized an automated external defibrillator on an employee in distress. The rapid response and coordinated effort with others were directly responsible for saving a life.

Issac DelanceyNASA/Stennis

Issac Delancey of Picayune, Mississippi, received the NASA Exceptional Bravery Medal for exemplary and courageous actions while responding to a medical emergency at NASA Stennis to prevent the loss of human life on Dec. 7, 2022. An officer with Chenega Global Protection, Delancey provided the automated external defibrillator while responding to an incident of an employee in distress. Upon arrival, Delancey provided the employee with artificial respiration and coordinated effort with others to maximize the effect of chest compressions. The rapid response and coordinated effort were directly responsible for saving a life.

One NASA Stennis employee received the NASA Exceptional Technology Achievement Medal. The medal is awarded to government or non-government individuals for exceptional technology contributions.

Richard SmithNASA/Stennis

Richard Smith of Picayune, Mississippi, received NASA’s Exceptional Technology Achievement Medal for efforts that led to significant advances to the data acquisition and thrust vector control systems that provide critical support to propulsion testing onsite. Among his contributions, Smith, a contractor on the operations and maintenance contract at NASA Stennis, was the primary software system architect for the thrust vector control work to enable rocket engine gimbal testing. He also worked to ensure safe hydraulic operation of the system. His efforts enabled the NASA Stennis test team to perform successful certification testing of the new RS-25 production engine.

Four NASA Stennis employees received the NASA Exceptional Achievement Medal. The medal is awarded to any government employee for a significant specific achievement or substantial improvement in operations, efficiency, service, financial savings, science, or technology which contributes to the mission of NASA.

John BoffenmyerNASA/Stennis

John Boffenmyer of Slidell, Louisiana, received NASA’s Exceptional Achievement Medal for maintaining the highest levels of performance in his remediation responsibilities within the NASA Stennis Center Operations Directorate, resulting in substantial benefits to the agency. As NASA Remediation Program manager for NASA Stennis, Boffenmyer’s work is integral to the Environmental and Health Services Office achieving the NASA Stennis and NASA missions. In conjunction with management of field operations, the Pottsville, Pennsylvania, native has demonstrated outstanding program management, with all audits of the NASA Stennis program proving successful.

Thomas MeredithNASA/Stennis

Thomas Meredith of Slidell, Louisiana, received NASA’s Exceptional Achievement Medal for his efforts as deputy chief engineer at NASA Stennis. During his tenure, the Enterprise, Alabama native has made substantial improvements to the management of test facility hardware in support of the center’s rocket propulsion test operations. Meredith’s leadership and dedication in the management of rocket propulsion test hardware have contributed to two areas of agency emphasis, the sustainment and modernization of mission-critical facilities and the employment of digital technologies to change and improve a process, product, or capability.

Kris Mobbs

Kris Mobbs of Woolmarket, Mississippi, received NASA’s Exceptional Achievement Medal for his efforts as software engineer in the NASA Stennis Engineering and Test Directorate to lead development of the NASA Data Acquisition Software suite for the acquisition, displaying, and recording of critical data during daily and test activities. Mobbs has led in identifying and implementing new capabilities of the software suite and in development of software packages to help increase the reliability of test data and performance of the test team. As a direct outcome of his leadership, use of the software has expanded to all the NASA Stennis-operated test facilities.

Ryan SealsNASA/Stennis

Ryan Seals of Carriere, Mississippi, received NASA’s Exceptional Achievement Medal for his contributions to the NASA Stennis propulsion test mission. Since beginning his career with NASA in 2016, the Poplarville, Mississippi, native has proven his expertise regarding test stand components and systems, contributing to the team responsible for testing the RS-25 engine that powers NASA’s SLS (Space Launch System) rocket. Seals also provided depth for the Thad Cochran Test Stand (B-2) team in preparation for hot fire testing of the SLS core stage. He also has supported commercial partner testing at the E Test Complex.

Four NASA Stennis employees received NASA’s Early Career Achievement Medal. The medal is awarded to government employees for unusual and significant performance during the first 10 years of an individual’s career in support of the agency.

Huy NguyenNASA/Stennis

Huy Nguyen of Slidell, Louisana, received the NASA Early Career Achievement Medal for his contributions as the facility controls engineer in the Electrical Test Operations Branch in the NASA Stennis Engineering and Test Directorate. In that role, Nguyen has supported the daily operations of the High Pressure Gas Facility and High Pressure Industrial Water Facility, which provide critical support to test complex propulsion activities. Among his contributions, Nguyen was instrumental to the success of upgrades, analysis, and practice runs to mitigate any risks during Green Run testing of the SLS (Space Launch System) core stage at NASA Stennis.

Kevin OramousNASA/Stennis

Kevin Oramous of Slidell, Louisiana, received the NASA Early Career Achievement Medal for his contributions to propulsion test activities and support facilities to directly advance NASA’s rocket propulsion test mission. The New Orleans native began his career at NASA Stennis in 2019 in the Mechanical Operations Branch of the NASA Stennis engineering and Test Directorate, working in the site’s E Test Complex and High Pressure Gas Facility, using his expertise to support operation and systems projects and activities. Oramous also has supported RS-25 testing, propellant and commodity management, and the Thad Cochran Test Stand (B-2) during the SLS (Space Launch System) core stage testing.

Jason RichardNASA/Stennis

Jason Richard of Mandeville, Louisiana, received the NASA Early Career Achievement Medal for contributions to NASA’s support of commercial propulsion test partners at NASA Stennis. As project engineer at the E-1 Test Facility, Richard ensured completion of facility design, construction, and activation phases for the Relativity Space Aeon-R Thrust Chamber Assembly test project, while maintaining rigorous quality and safety standards. Working with the NASA Stennis Strategic Business Development Office, Richard has helped bridge the propulsion testing and business development teams and worked to implement the office’s information technology strategy.

Bradley TyreeNASA/Stennis

Bradley Tyree of Picayune, Mississippi, received the NASA Early Career Achievement Medal for his work in the Mechanical Operations Branch in the NASA Stennis Engineering and Test Directorate. Tyree has provided leadership and technical expertise to key projects, including E Test Complex support of SLS (Space Launch System) core stage testing at NASA Stennis. Since being assigned to support RS-25 testing, his knowledge of propellant handling techniques, technical system maintenance, and test processes have proved invaluable and enabled his progression as a propellant transfer engineer and RS-25 test conductor.

One NASA Stennis employee received NASA’s Silver Achievement Medal. The medal is awarded to any government or non-government employee for a stellar achievement that supports one or more of NASA’s core values, when it is deemed to be extraordinarily important and appropriate to recognize such achievement in a timely and personalized manner.

Gregg De FelicibusNASA/Stennis

Gregg De Felicibus of Pass Christian, Mississippi, received the NASA Silver Achievement Medal for displaying NASA’s core values of safety, integrity, teamwork, excellence, and inclusion while carrying out his work as a contracting officer in the Office of Procurement in support of advancing Space Exploration and NASA’s strategic goals. He has been responsible for the award and management of five critical services contracts valued at over $18.6 million. He has served as an advisor and mentor, has supported the NASA Stennis Small Business Office in achieving its socio-economic goals, has administered over $43 million in contracts, and has negotiated over $5.7 million in cost savings.

Download Stennis Space Center 2023 Agency Honor Awards Ceremony Program

For information about NASA’s Stennis Space Center, visit:

Stennis Space Center – NASA

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"Twisted Tatooine" binary star systems could be a major player in ejecting rogue planets that go on to drift through the Milky Way without a stellar parent to heat or illuminate them.

As we discover more and more exoplanets – and the current total is in excess of 5,200 – we continue to try to learn more about them. Astrobiologists busy themselves analysing their atmospheres searching for anything that provides a sign of life. It is quite conceivable of course that the Universe is teeming with life based on very different chemistry to ours but we often look to life on Earth to know what to look for. On Earth for example, ozone forms through photolysis of molecular oxygen and is an indicator of life. Using the James Webb Space Telescope astronomers are searching stars in the habitable zone of their star for the presence of ozone and how it impacts their climate.

It’s tantalising that 425 of the exoplanets detected so far, exist in their stars habitable zone. It is in this region where the climate on the planet may well be suitable to sustain life. A significant subset of those planets are Earth-like in nature and will therefore have a fairly temperate climate. In addition, they all seem to orbit M-dwarf type stars which means they are likely to be impacted by tidal spin-synchronisation (due to the effects of the tides, one face of the planet may well be kept facing the star). One impact of this is the potential for large contrast in daytime and night-time irradiation which can drive strong convection on the day side of the planet.  

The strong convection can drive winds around the equatorial region that are persistently higher faster than the rotation of the planet. It can also create Rosby Waves which naturally occur in the Earth’s ocean and atmosphere – in any rotating fluids or gas. Together these can control the distribution of chemicals in the atmosphere, in particular ozone. 

In Earth’s atmosphere the presence of molecular oxygen is an indicator of life since it is produced largely from photosynthesis in plants. The molecular oxygen collides with nitrogen in the atmosphere to produce ozone so the presence of the latter is an indicator of biological processes. There is a chance though that the molecular oxygen in exoplanet atmospheres are the result of different ratios of near and far UV that can drive a non-biological build up. 

In a new piece of research reported in a paper by lead author Paolo De Luca and team, they report their findings having leveraged climate model simulations on Proxima Centauri b. The Earth-sized exoplanet orbits the red dwarf star Proxima Centauri, the closest star to our own at a distance of 4,.2 light years. 

An artist’s conception of a violent flare erupting from the red dwarf star Proxima Centauri. Such flares can obliterate atmospheres of nearby planets. Credit: NRAO/S. Dagnello.

They report that the analysis of atmospheres of tidally locked Earth-like exoplanets received a massive boost as a result of the development of the James Webb Telescope. The team reveal that their climate modelling (including the use of interactive ozone) globally increases temperature in the stratosphere. This in turn induces regional variations of surface temperature and also reduces the temperature contrast between day and night side. 

Whilst the team have not been able to identify life on exoplanets, that was not their intention. What they have achieved is the ability to understand the exoplanet atmospheres using the James Webb Space Telescope, some of the processes that lead to atmospheric ozone and the impacts on temperatures. 

Source : The impact of Ozone on Earth-like exoplanet climate dynamics: the case of Proxima Centauri b

The post What Impact Does Ozone Have on an Exoplanet? appeared first on Universe Today.

Strange solids called temporal metamaterials finally make it possible to investigate the controversial idea of quantum friction – and push special relativity to its limits

Strange solids called temporal metamaterials finally make it possible to investigate the controversial idea of quantum friction – and push special relativity to its limits