NASA astronaut Jonny Kim poses inside the International Space Station’s cupola as it orbits 265 miles above the Indian Ocean near Madagascar.
Credit: NASA
NASA astronaut Jonny Kim will recap his recent mission aboard the International Space Station during a news conference at 3:30 p.m. EST Friday, Dec. 19, from the agency’s Johnson Space Center in Houston.
Media interested in participating in person must contact the NASA Johnson newsroom no later than 5 p.m. Thursday, Dec. 18, at 281-483-5111 or jsccommu@mail.nasa.gov.
Media wishing to participate by phone must contact the Johnson newsroom no later than two hours before the start of the event. To ask questions by phone, media must dial into the news conference no later than 15 minutes prior to the start of the call. NASA’s media accreditation policy is available online.
Kim returned to Earth on Dec. 9, along with Roscosmos cosmonauts Sergey Ryzhikov and Alexey Zubritsky. He logged 245 days as an Expedition 72/73 flight engineer during his first spaceflight. The trio completed 3,920 orbits of the Earth over the course of their nearly 104-million-mile journey. They also saw the arrival of nine visiting spacecraft and the departure of six.
During his mission, Kim contributed to a wide range of scientific investigations and technology demonstrations. He studied the behavior of bioprinted tissues containing blood vessels in microgravity for an experiment helping advance space-based tissue production to treat patients on Earth. He also evaluated the remote command of multiple robots in space for the Surface Avatar study, which could support the development of robotic assistants for future exploration missions. Additionally, Kim worked on developing in-space manufacturing of DNA-mimicking nanomaterials, which could improve drug delivery technologies and support emerging therapeutics and regenerative medicine.
Learn more about International Space Station research and operations at:
Two icons of discovery, NASA’s James Webb Space Telescope and NASA’s Curiosity rover, have earned places in TIME’s “Best Inventions Hall of Fame,” which recognizes the 25 groundbreaking inventions of the past quarter century that have had the most global impact, since TIME began its annual Best Inventions list in 2000. The inventions are celebrated in TIME’s December print issue.
“NASA does the impossible every day, and it starts with the visionary science that propels humanity farther than ever before,” said Nicky Fox, associate administrator, Science Mission Directorate, NASA Headquarters in Washington. “Congratulations to the teams who made the world’s great engineering feats, the James Webb Space Telescope and the Mars Curiosity Rover, a reality. Through their work, distant galaxies feel closer, and the red sands of Mars are more familiar, as they expanded and redefined the bounds of human achievement in the cosmos for the benefit of all.”
Decades in the making and operating a million miles from Earth, Webb is the most powerful space telescope ever built, giving humanity breathtaking views of newborn stars, distant galaxies, and even planets orbiting other stars. The new technologies developed to enable Webb’s science goals – from optics to detectors to thermal control systems – now also touch Americans’ everyday lives, improving manufacturing for everything from high-end cameras and contact lenses to advanced semiconductors and inspections of aircraft engine components.
This landscape of “mountains” and “valleys” speckled with glittering stars is actually the edge of a nearby, young, star-forming region called NGC 3324 in the Carina Nebula. Captured in infrared light by NASA’s James Webb Space Telescope, this image reveals for the first time previously invisible areas of star birth.
NASA, ESA, CSA, and STScI
Meanwhile on Mars, the unstoppable Curiosity rover, NASA’s car-size science lab, has spent more than a decade uncovering clues that the Red Planet once could have supported life, transforming our understanding of our planetary neighbor. These NASA missions continue to make breakthroughs that have reshaped our understanding of the universe and our place in it. Curiosity has also paved the way for future astronauts: Its Radiation Assessment Detector has studied the Martian radiation environment for nearly 14 years, and its unforgettable landing by robotic jetpack allowed heavier spacecraft to touch down on the surface — a capability that will be needed to send cargo and humans to Mars.
NASA’s Curiosity Mars rover used two different cameras to create this selfie in front of Mont Mercou, a rock outcrop that stands 20 feet (6 meters) tall. The panorama is made up of 60 images taken by the Mars Hand Lens Imager (MAHLI) on the rover’s robotic arm on March 26, 2021, the 3,070th Martian day, or sol, of the mission. These were combined with 11 images taken by the Mastcam on the mast, or “head,” of the rover on March 16, 2021, the 3,060th Martian day of the mission.
NASA/JPL-Caltech/MSSS
To compile this “Hall of Fame” list, TIME solicited nominations from TIME editors and correspondents around the world, paying special attention to high-impact fields, such as health care and technology. TIME then evaluated each contender on a number of key factors, including originality, continued efficacy, ambition, and impact.
The James Webb Space Telescope is the world’s premier space science observatory. Webb is solving mysteries in our solar system, looking beyond to distant worlds around other stars, and probing the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and CSA (Canadian Space Agency).
The Curiosity rover was built by NASA’s Jet Propulsion Laboratory, which is managed by Caltech in Pasadena, California. JPL leads the mission on behalf of NASA’s Science Mission Directorate in Washington as part of NASA’s Mars Exploration Program portfolio.
To learn more about NASA’s science missions, visit:
The Global Learning and Observations to Benefit the Environment (GLOBE) Program has launched a new feature that connects citizen scientists directly to Landsat observations. Through GLOBE, volunteers around the world collect environmental data in support of Earth system science, including land observations. GLOBE land cover observations may include photos of the landscape and a classification of the land cover, providing a valuable dataset of ground-truth observations.
GLOBE Land Cover is an app-based tool where users can document land cover through photographs. Users can classify their observations, compare them to a satellite image, and note any differences.
GLOBE Observer
As of September, when volunteers submit land cover observations to GLOBE, they will receive an email comparing their findings to Landsat and Sentinel-2 satellite observations of the same location in the same timeframe. This direct comparison helps bridge the gap between space-based remote sensing and ground-based observations, building on the successful legacy of GLOBE cloud observations that have been matched with satellite data for years.
Why Is GLOBE Including Land Cover?
Land cover classification plays a crucial role in understanding and managing our environment. This information is essential for risk analysis related to natural disasters such as floods, wildfires, and landslides. It also enables scientists to track the impacts of land use changes over time and create detailed maps of wildlife habitats. Landsat is a key dataset in many national and global land cover classification products such as the National Land Cover Database (NLCD).
GLOBE land cover allows anyone, from a highschooler to a university professor, to contribute to our understanding of Earth’s changing surface.
For more information about Landsat’s new role in GLOBE, read GLOBE’s feature or explore GLOBE Land Cover.
NASA, ESA, CSA, STScI, Yu Cheng (NAOJ); Image Processing: Joseph DePasquale (STScI)
NASA’s James Webb Space Telescope captured a blowtorch of seething gasses erupting from a volcanically growing monster star in this image released on Sept. 10, 2025. Stellar jets, which are powered by the gravitational energy released as a star grows in mass, encode the formation history of the protostar. This image provides evidence that protostellar jets scale with the mass of their parent stars—the more massive the stellar engine driving the plasma, the larger the resulting jet.
Image credit: NASA, ESA, CSA, STScI, Yu Cheng (NAOJ); Image Processing: Joseph DePasquale (STScI)
Preparations for Next Moonwalk Simulations Underway (and Underwater)
This video highlights the Rover Operations Center at NASA’s Jet Propulsion Laboratory. A center of excellence for current and future rover, aerial, and other surface missions, the ROC will support partnerships and technology transfer to catalyze the next generation of Moon and Mars surface missions. Credit: NASA/JPL-Caltech
The center leverages AI along with JPL’s unique infrastructure, unrivaled tools, and years of operations expertise to support industry partners developing future planetary surface missions.
NASA’s Jet Propulsion Laboratory in Southern California on Wednesday inaugurated its Rover Operations Center (ROC), a center of excellence for current and future surface missions to the Moon and Mars. During the launch event, leaders from the commercial space and AI industries toured the facilities, participated in working sessions with JPL mission teams, and learned more about the first-ever use of generative AI by NASA’s Perseverance Mars rover team to create future routes for the robotic explorer.
The center was established to integrate and innovate across JPL’s planetary surface missions while simultaneously forging strategic partnerships with industry and academia to advance U.S. interests in the burgeoning space economy. The center builds on JPL’s 30-plus years of experience developing and operating Mars surface missions, including humanity’s only helicopter to fly at Mars as well as the only two active planetary surface missions.
“The Rover Operations Center is a force multiplier,” said JPL Director Dave Gallagher. “It integrates decades of specialized knowledge with powerful new tools, and exports that knowledge through partnerships to catalyze the next generation of Moon and Mars surface missions. As NASA’s federally funded research and development center, we are chartered to do exactly this type of work — to increase the cadence, the efficiency, and the impact for our transformative NASA missions and to support the commercial space market as they take their own giant leaps.”
Rover prototype ERNEST (Exploration Rover for Navigating Extreme Sloped Terrain) demonstrates some of its advanced mobility and autonomy capabilities in JPL’s Mars Yard.
NASA/JPL-Caltech
Genesis of ROC
Through decades of successful Mars rover missions, JPL has continuously improved the unique autonomy, robotic capabilities, and best practices that have been demanded by increasingly complex robotic explorers. The ROC offers an accessible centralized structure to facilitate future exploration efforts.
“Our rovers are lasting longer and are more sophisticated than ever before. The scientific stakes are high, as we have just witnessed with the discovery of a potential biosignature in Jezero Crater by the Perseverance mission. We are starting down a decade of unprecedented civil and commercial exploration at the Moon, which will require robotic systems to assist astronauts and support lunar infrastructure,” said Matt Wallace, who heads JPL’s Exploration Systems Office. “Mobile vehicles like rovers, helicopters, and drones are the most dynamic and challenging assets we operate. It’s time to take our game up a notch and bring everybody we can with us.”
Michael Thelen of JPL’s Exploration Systems Office discusses the newly inaugurated Rover Operations Center in JPL’s historic Space Flight Operations Facility on Dec. 10.
NASA/JPL-Caltech
Future forward
A key focus of the ROC is on the more rapid infusion of higher-level autonomy into surface missions through partnerships with the AI and commercial space industries. The objective is to catalyze change to deliver next-generation science and exploration capabilities for the nation and NASA.
As NASA’s only federally funded research and development center, JPL has been evolving vehicle autonomy since the 1990s, when JPL began developing Sojourner, the first rover on another planet. Improvements to vehicle independence over the years have included the evolution of autonomy in sampling activities, driving, and science-target selection. Most recently, those improvements have extended to the development of Perseverance’s ability to autonomously schedule and execute many commanded energy-intensive activities, like keeping warm at night, as it sees fit. This capability allows the rover to conserve power, which it can reallocate in real time to perform more science or longer drives.
With the explosion of AI capabilities, the ROC rover team is leaving no Mars stone unturned in the hunt for future efficiencies.
“We had a small team complete a ‘three-week challenge,’ applying generative AI to a few of our operational use cases. During this challenge, it became clear there are many opportunities for AI infusion that can supercharge our capabilities,” said Jennifer Trosper, ROC program manager at JPL. “With these new partnerships, together we will infuse AI into operations to path-find the next generation of capabilities for science and exploration.”
HÃ¥vard Grip, chief pilot of NASA’s Mars Ingenuity Helicopter — the only aircraft to fly on another planet — offers insights into aerial exploration of the Red Planet at the lab’s 25-Foot Space Simulator, which subjects spacecraft to the harsh conditions of space.
During the ROC’s inauguration, attendees toured JPL operations facilities, including where the rover drivers plan their next routes. They also visited JPL’s historic Mars Yard, which reproduces Martian terrain to test rover capabilities, and the massive 25-Foot Space Simulator that has tested spacecraft from Voyagers 1 and 2 to Perseverance to America’s next generation of lunar landers. A panel discussion explored the historical value of rovers and aerial systems like the Ingenuity Mars Helicopter in planetary surface exploration. Also discussed was the promise of a new public-private partnership opportunity across a virtual network of operational missions.
Attendees were briefed on tiered engagement options for partners, from mission architecture support to autonomy integration, testing, and operations. These opportunities extend to science and human precursor robotic missions, as well as to human-robotic interaction and spacewalks for astronauts on the Moon and Mars.
A highlight for event participants came when the Perseverance team showcased how the ROC’s generative AI can assist rover planners in creating future routes for the rover. The AI analyzed high-resolution orbital images of Jezero Crater and other relevant data and then generated waypoints that kept Perseverance away from hazardous terrain.
Managed for NASA by Caltech, JPL is the home of the Rover Operations Center (ROC).
NASA and its partners have supported humans continuously living and working in space since November 2000. After 25 years of habitation, the International Space Station continues to be a proving ground for technology that powers NASA’s Artemis campaign, future lunar missions, and human exploration of Mars.
Take a look at key technology advancements made possible by research aboard the orbiting laboratory.
Robots at work in orbit
NASA astronaut Suni Williams checks out the Astrobee robotic free-flyer inside the International Space Station’s Kibo laboratory module during a demonstration of satellite capture techniques. This technology could help extend the life of satellites and reduce space debris.
NASA
Robots have been critical to the space station’s success. From the Canadian-built Canadarm2, which assembled large portions of the orbiting laboratory and continues to support ongoing operations, especially during spacewalks, robotic technology on station has evolved to include free-flying assistants and humanoid robots that have extended crew capabilities and opened new paths for exploration.
The station’s first robotic helpers arrived in 2003. The SPHERES robots – short for Synchronized Position Hold, Engage, Reorient, Experimental Satellite – served on station for over a decade, supporting environmental monitoring, data collection and transfer, and materials testing in microgravity.
NASA’s subsequent free-flying robotic system, Astrobee, built on the lessons learned from SPHERES. Known affectionately as Honey, Queen, and Bumble, the three Astrobees work autonomously or via remote control by astronauts, flight controllers, or researchers on the ground. They are designed to complete tasks such as inventory, documenting experiments conducted by astronauts, or moving cargo throughout the station, and they can be outfitted and programmed to carry out experiments.
NASA and partners have also tested dexterous humanoid robots aboard the space station. Robonaut 1 and its more advanced successor, Robonaut 2, were designed to use the same tools as humans, so they could work safely with crew with the potential to take over routine tasks and high-risk activities.
Advanced robotic technologies will play a significant role in NASA’s mission to return to the Moon and continue on to Mars and beyond. Robots like Astrobee and Robonaut 2 have the capacity to become caretakers for future spacecraft, complete precursor missions to new destinations, and support crew safety by tackling hazardous tasks.
Closing the loop: recycling air and water in space
ESA (European Space Agency) astronaut Samantha Cristoforetti works on a Regenerative Environmental Control and Life Support System (ECLSS) recycle tank remove-and-replace task aboard the International Space Station.
ESA
Living and working in space for more than two decades requires technology that makes the most of limited resources. The space station’s life support systems recycle air and water to keep astronauts healthy and reduce the need for resupply from Earth.
The station’s Environmental Control and Life Support System (ECLSS) removes carbon dioxide from the air, supplies oxygen for breathing, and recycles wastewater—turning yesterday’s coffee into tomorrow’s coffee. It is built around three key components: the Water Recovery System, Air Revitalization System, and Oxygen Generation System. The water processor reclaims wastewater from crew members’ urine, cabin humidity, and the hydration systems inside spacesuits for spacewalks, converting it into clean, drinkable water.
NASA astronaut Kjell Lindgren celebrates International Coffee Day aboard the orbital laboratory with a hand-brewed cup of coffee in space, brewed using the Capillary Beverage Cup.
NASA
The air revitalization system filters carbon dioxide and trace contaminants from the cabin atmosphere, ensuring the air stays safe to breathe. The oxygen generation system uses electrolysis to split water into hydrogen and oxygen, providing a steady supply of breathable air. Today, these systems can recover around 98% of the water brought to the station, a vital step toward achieving long-duration missions where resupply will not be possible.
The lessons learned aboard the space station will help keep Artemis crews healthy on the Moon and shape the closed-loop systems needed for future expeditions to Mars.
Advancing 3D printing technology for deep space exploration
The first metal part 3D printed in space.
ESA
Additive manufacturing, also known as 3D printing, is regularly used on Earth to quickly produce a variety of devices. Adapting this process for space could let crew members create tools and parts for maintenance and repair as needed and save valuable cargo space.
The space station’s first 3D printer was installed in November 2014. That device produced more than a dozen plastic tools and parts, demonstrating that the process could work in low Earth orbit. Subsequent devices tested different printer designs and functionality, including the production of parts from recycled materials and simulated lunar regolith. In August 2024, a device supplied by ESA produced the first metal 3D-printed product.
The space station also has hosted studies of a form of 3D printing called biological printing or bioprinting. This process uses living cells, proteins, and nutrients as raw materials to potentially produce human tissues for treating injury and disease. So far, a knee meniscus and live human heart tissue have been printed onboard.
The ability to manufacture things in space is especially important in planning for future missions to the Moon and Mars because additional supplies cannot quickly be sent from Earth and cargo capacity is limited.
We have the solar power
NASA astronaut and Expedition 72 flight engineer Anne McClain is pictured near one of the space station’s main solar arrays during a spacewalk to upgrade the orbital outpost’s power generation system and relocate a communications antenna.
NASA/Nichole Ayers
As the space station orbits Earth, its four pairs of solar arrays soak up the sun’s energy to provide electrical power for the numerous research and science investigations conducted every day, as well as the continued operations of the orbiting laboratory.
In addition to harnessing the Sun’s energy for its operations, the space station has provided a platform for innovative solar power research. At least two dozen investigations have tested advanced solar cell technology – evaluating the cells’ on-orbit performance and monitoring degradation caused by exposure to the extreme environment of space. These investigations have demonstrated technologies that could enable lighter, less expensive, and more efficient solar power that could improve the design of future spacecraft and support sustainable energy generation on Earth.
One investigation – the Roll-Out Solar Array – has already led to improvements aboard the space station. The successful test of a new type of solar panel that rolls open like a party favor and is more compact than current rigid panel designs informed development of the ISS Roll-Out Solar Arrays (iROSAs). The six iROSAs were installed during a series of spacewalks between 2021 and 2023 and provided a 20% to 30% increase in space station power.
Connecting students to station science
The Kibo Robot Programming Challenge students watch in real time as the free-flying robot Astrobee performs maneuvers aboard the space station, executing tasks based on their input to test its capabilities.
NASA/Helen Arase Vargas
For 25 years, the orbital outpost has served as a global learning platform, advancing STEM education and connecting people on Earth to life in space. Every experiment, in-flight downlink, and student-designed payload helps students see science in action and share humanity’s pursuit of discovery.
The first and longest-running education program on the space station is ISS Ham Radio, known as Amateur Radio on the International Space Station (ARISS), where students can ask questions directly to crew members aboard the space station. Since 2000, ARISS has connected more than 100 astronauts with over 1 million students across 49 U.S. states, 63 countries, and every continent.
Through Learn with NASA, students and teachers can explore hands-on activities and astronaut-led experiments that demonstrate how physics, biology, and chemistry unfold in microgravity.
Students worldwide also take part in research inspired by the space station. Programs like Genes in Space and Cubes in Space let learners design experiments for orbit, while coding and robotics competitions such as the Kibo Robot Programming Challenge allows students to program Astrobee free-flying robots aboard the orbiting laboratory.
As NASA prepares for Artemis missions to the Moon, the space station continues to spark curiosity and inspire the next generation of explorers.
What a Blast! NASA Langley Begins Plume-Surface Interaction Tests
Views of the 60-foot vacuum sphere in the which the plume-surface interaction testing is happening.
Credits:NASA/Joe Atkinson
In March as Firefly Aerospace’s Blue Ghost Mission-1 landed on the Moon, researchers from NASA’s Langley Research Center in Hampton, Virginia, employed a novel camera system to capture first-of-its-kind data imagery of the interaction between the lander’s engine plumes and the lunar surface.
That kind of data is critical, because as the United States returns to the Moon, both through NASA’s Artemis campaign and the commercialization of space, researchers need to understand the hazards that may occur when a lander’s engine plumes blast away at the lunar dust, soil, and rocks.
These data will be valuable to NASA’s commercial partners as they develop their human landing systems that will safely transport astronauts from lunar orbit to the Moon’s surface and back for Artemis, beginning with Artemis III in 2027.
A team at NASA Langley has initiated a series of plume-surface interaction tests inside a massive 60-foot vacuum.
This plume-surface interaction ground test is the most complex test of its kind to be undertaken in a vacuum chamber
Ashley Korzun
PSI Testing Lead at NASA Langley
“This plume-surface interaction ground test is the most complex test of its kind to be undertaken in a vacuum chamber,” said Ashley Korzun, testing lead at NASA Langley. “If I’m in a spacecraft and I’m going to move all that regolith while landing, some of that’s going to hit my vehicle. Some of it’s going to go out toward other things — payloads, science experiments, eventually rovers and other assets. Understanding those physics is pivotal to ensuring crew safety and mission success.”
The campaign, which will run through spring of 2026, should provide an absolute treasure trove of data that researchers will be able to use to improve predictive models and influence the design of space hardware. As Korzun mentioned, it’s a big undertaking, and it involves multiple NASA centers, academic institutions, and commercial entities both small and large.
Korzun’s team will test two types of propulsion systems in the vacuum sphere. For the first round of tests this fall, they’ll use an ethane plume simulation system designed by NASA’s Stennis Space Center near Bay St. Louis, Mississippi, and built and operated by Purdue University in West Lafayette, Indiana. The ethane system generates a maximum of about 100 pounds of thrust — imagine the force necessary to lift or support a 100-pound person. It heats up but doesn’t burn.
A view of the PSI testing platform and instrumentation inside the vacuum sphere.
NASA
NASA
The data from these tests at NASA Langley will be critical in developing and validating models to predict the effects of plume surface interaction for landing on the Moon and even Mars, ensuring mission success for the HLS landers and the safety of our astronauts
Daniel Stubbs
Engineer with HLS Plume and Aero Environments Team at NASA Marshall
After completing the ethane tests, the second round of tests will involve a 14-inch, 3D-printed hybrid rocket motor developed at Utah State University in Logan, Utah, and recently tested at NASA’s Marshall Space Flight Center in Huntsville, Alabama. It produces around 35 pounds of thrust, but ignites both solid propellant and a stream of gaseous oxygen to create a hot, powerful stream of rocket exhaust, simulating a real rocket engine but at smaller scale for this test series.
Researchers will test both propulsion systems at various heights, firing them into a roughly six-and-a-half-foot diameter, one-foot-deep bin of simulated lunar regolith, called Black Point-1 that has jagged, cohesive properties similar to lunar regolith.
“It gives us a huge range of test conditions,” Korzun said, “to be able to talk about vehicles of all different kinds going to the Moon, and for us to understand what they’re going to do as they land or try to take back off from the surface.”
This 4-inch hybrid rocket motor tested at NASA Marshall earlier this year will be part of the testing at NASA Langley.
A number of different instruments, including a version of the SCALPSS camera system that imaged the plume-surface interaction during the Blue Ghost landing, will capture data and imagery from the tests, which will only last about six seconds each. The instruments will measure everything from crater formation, to the speed and angle of ejecta particles, to the shapes of the engine plumes.
Korzun sees this test campaign as more than a one-shot, Moon-specific thing. The entire operation is modular by design. There’s Mars to consider, after all. The lunar regolith simulant can be replaced with a Mars simulant that’s more like sand. Pieces of hardware and instrumentation can be unbolted and replaced to represent future Mars landers. Rather than take the vacuum sphere down to really low pressure like on the Moon, it can be adjusted to a not-as-low, Mars-relevant pressure.
“Mars has always been in our road maps,” Korzun said.
But for now, the Moon looms large.
A number of instruments, including SCALPSS cameras similar to the ones that captured imagery of the plume-surface interaction between Firefly Aerospace’s Blue Ghost lander and the Moon in March, will capture data on the sphere tests.
NASA/Ryan Hill
“This test campaign is one of the most flight-relevant and highly instrumented plume surface interaction test series NASA has ever conducted,” said Daniel Stubbs, an engineer with the HLS plume and aero environments team at NASA Marshall. “The data from these tests at NASA Langley will be critical in developing and validating models to predict the effects of plume surface interaction for landing on the Moon and even Mars, ensuring mission success for the HLS landers and the safety of our astronauts.”
Through the Artemis campaign, NASA will send astronauts to explore the Moon for scientific discovery, economic benefits, and to build the foundation for the first crewed missions to Mars – for the benefit of all.
