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Explore Hubble Hubble Home Overview About Hubble The History of Hubble Hubble Timeline Why Have a Telescope in Space? Hubble by the Numbers At the Museum FAQs Impact & Benefits Hubble’s Impact & Benefits Science Impacts Cultural Impact Technology Benefits Impact on Human Spaceflight Astro Community Impacts Science Hubble Science Science Themes Science Highlights Science Behind Discoveries Universe Uncovered Hubble’s Partners in Science Hubble & Citizen Science AI & Hubble Science Explore the Night Sky Observatory Hubble Observatory Hubble Design Mission Operations Science Operations Astronaut Missions to Hubble Hubble vs Webb Team Hubble Team Career Aspirations Hubble Astronauts Multimedia Images Videos Sonifications Podcasts e-Books Online Activities 3D Hubble Models Lithographs Fact Sheets Posters Hubble on the NASA App Glossary News Hubble News Social Media Media Resources More 35th Anniversary Online Activities 3 min read Hubble Snaps Stellar Baby Pictures The Cepheus A region is home to a number of infant stars, including a protostar that is responsible for much of the region’s illumination. NASA, ESA, and R. Fedriani (Instituto de Astrofisica de Andalucia); Processing: Gladys Kober (NASA/Catholic University of America) Star-forming region G033.91+0.11 is home to a protostar hidden within a reflection nebula. NASA, ESA, and R. Fedriani (Instituto de Astrofisica de Andalucia); Processing: Gladys Kober (NASA/Catholic University of America) A protostar is swathed in the gas of an emission nebula within star-forming region GAL-305.20+00.21. NASA, ESA, and R. Fedriani (Instituto de Astrofisica de Andalucia); Processing: Gladys Kober (NASA/Catholic University of America) A protostar’s jets of high-speed particles are responsible for the bright region of excited, glowing hydrogen in this Hubble image. NASA, ESA, and R. Fedriani (Instituto de Astrofisica de Andalucia); Processing: Gladys Kober (NASA/Catholic University of America) Newly developing stars shrouded in thick dust get their first baby pictures in these images from NASA’s Hubble Space Telescope. Hubble took these infant star snapshots in an effort to learn how massive stars form. Protostars are shrouded in thick dust that blocks light, but Hubble can detect the near-infrared emission that shines through holes formed by the protostar’s jets of gas and dust. The radiating energy can provide information about these “outflow cavities,” like their structure, radiation fields, and dust content. Researchers look for connections between the properties of these young stars – like outflows, environment, mass, brightness – and their evolutionary stage to test massive star formation theories. These images were taken as part of the SOFIA Massive (SOMA) Star Formation Survey, which investigates how stars form, especially massive stars with more than eight times the mass of our Sun. The Cepheus A region is home to a number of infant stars, including a protostar that is responsible for much of the region’s illumination. NASA, ESA, and R. Fedriani (Instituto de Astrofisica de Andalucia); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (5.7 MB) The high-mass star-forming region Cepheus A hosts a collection of baby stars, including one large and luminous protostar, which accounts for about half of the region’s brightness. While much of the region is shrouded in opaque dust, light from hidden stars breaks through outflow cavities to illuminate and energize areas of gas and dust, creating pink and white nebulae. The pink area is an HII region, where the intense ultraviolet radiation of the nearby stars has converted the surrounding clouds of gas into glowing, ionized hydrogen. Cepheus A lies about 2,400 light-years away in the constellation Cepheus. Star-forming region G033.91+0.11 is home to a protostar hidden within a reflection nebula. NASA, ESA, and R. Fedriani (Instituto de Astrofisica de Andalucia); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (5.8 MB) Glittering much closer to home, this Hubble image depicts the star-forming region G033.91+0.11 in our Milky Way galaxy. The light patch in the center of the image is a reflection nebula, in which light from a hidden protostar bounces off gas and dust. A protostar is swathed in the gas of an emission nebula within star-forming region GAL-305.20+00.21. NASA, ESA, and R. Fedriani (Instituto de Astrofisica de Andalucia); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (5.8 MB) This Hubble image showcases the star-forming region GAL-305.20+00.21. The bright spot in the center-right of the image is an emission nebula, glowing gas that is ionized by a protostar buried within the larger complex of gas and dust clouds. A protostar’s jets of high-speed particles are responsible for the bright region of excited, glowing hydrogen in this Hubble image. NASA, ESA, and R. Fedriani (Instituto de Astrofisica de Andalucia); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (5.7 MB) Shrouded in gas and dust, the massive protostar IRAS 20126+4104 lies within a high-mass star-forming region about 5,300 light-years away in the constellation Cygnus. This actively forming star is a B-type protostar, characterized by its high luminosity, bluish-white color, and very high temperature. The bright region of ionized hydrogen at the center of the image is energized by jets emerging from the poles of the protostar, which ground-based observatories previously observed. New images added every day between January 12-17, 2026! Follow @NASAHubble on social media for the latest Hubble images and news and see Hubble’s Stellar Construction Zones for more images of young stellar objects. Facebook logo @NASAHubble @NASAHubble Instagram logo @NASAHubble Explore More Exploring the Birth of Stars Hubble’s Nebulae Media Contact: Claire Andreoli NASA’s Goddard Space Flight Center, Greenbelt, MD *****@*****.tld Share Details Last Updated Jan 17, 2026 Location NASA Goddard Space Flight Center Related Terms Hubble Space Telescope Astrophysics Astrophysics Division Goddard Space Flight Center Protostars Stars The Universe Keep Exploring Discover More Topics From Hubble Hubble Space Telescope Since its 1990 launch, the Hubble Space Telescope has changed our fundamental understanding of the universe. Hubble’s Stellar Construction Zones Hubble’s Night Sky Challenge Hubble’s 35th Anniversary View the full article
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NASA’s SpaceX Crew-11 crew returns to Ellington Field’s Guppy Hangar in Houston on Jan. 16, 2026, from left to right is Roscosmos cosmonaut Oleg Platonov, NASA astronauts Mike Fincke, and Zena Cardman, and JAXA (Japan Aerospace Exploration Agency) astronaut Kimya Yui.NASA After 167 days in space, the crew members of NASA’s SpaceX Crew-11 mission will hold a news conference at 2:15 p.m. EST, Wednesday, Jan. 21, at the agency’s Johnson Space Center in Houston to discuss their science expedition aboard the International Space Station. NASA astronauts Zena Cardman and Mike Fincke, JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui, and Roscosmos cosmonaut Oleg Platonov will answer questions about their mission. The crew members returned to Earth on Jan. 15, splashing down off the coast of San Diego, and arrived in Houston on Friday, where they will undergo standard postflight reconditioning and evaluations. NASA will provide live coverage on the agency’s YouTube channel. Learn how to watch NASA content through a variety of additional online platforms, including social media. Media are invited to attend in person or virtually. For in-person attendance, contact the NASA Johnson newsroom no later than 5 p.m. CST, Tuesday, Jan. 20, at *****@*****.tld or 281-483-5111. Media participating by phone must dial into the news conference no later than 10 minutes prior to the start of the event to ask questions. Questions also may be submitted on social media using #AskNASA. A copy of NASA’s media accreditation policy is available on the agency’s website. The crew spent more than five months in space, including 165 days aboard the orbiting laboratory, traveling nearly 71 million miles, and completing more than 2,670 orbits around Earth. While living and working aboard the station, the crew completed hundreds of science experiments and technology demonstrations. Get the latest NASA space station news, images, and features on Instagram, Facebook, and X. NASA’s Commercial Crew Program has delivered on its goal of safe, reliable, and cost-effective transportation to and from the International Space Station from the United States through a partnership with American private industry. This partnership is opening access to low Earth orbit and the space station to more people, more science, and more commercial opportunities. For more than 25 years, people have continuously lived and worked aboard the space station, advancing scientific knowledge and demonstrating new technologies that enable us to prepare for human exploration of the Moon as we prepare for Mars. Learn more about NASA’s Commercial Crew Program at: [Hidden Content] -end- Joshua Finch / Jimi Russell Headquarters, Washington 202-358-1100 *****@*****.tld / *****@*****.tld Anna Schneider / Shaneequa Vereen Johnson Space Center, Houston 281-483-5111 *****@*****.tld / shaneequa.y*****@*****.tld Share Details Last Updated Jan 16, 2026 LocationNASA Headquarters Related TermsNASA HeadquartersCommercial CrewHumans in SpaceInternational Space Station (ISS)Johnson Space Center View the full article
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Credit: NASA For the 15th consecutive year, NASA received an unmodified, or “clean,” opinion from an external auditor on its fiscal year 2025 financial statements. The rating is the best possible audit opinion, certifying that NASA’s financial statements conform with Generally Accepted Accounting Principles for federal agencies and accurately present the agency’s financial position. “NASA has delivered a complete and reliable report of our fiscal operations, critical to our success for the Golden Age of exploration and innovation,” said NASA Administrator Jared Isaacman. “NASA’s mission drives innovation in space exploration, scientific discovery, and aeronautics, pushing the boundaries of what’s possible. Our fiscal year 2025 budget fuels economic growth, drives the growing space economy, and keeps America first amidst increasing global competition.” The 2025 Agency Financial Report provides key financial and performance information and demonstrates the agency’s commitment to transparency in the use of American taxpayers’ dollars. In addition, the 2025 report presents progress during the past year, and spotlights the array of NASA missions, objectives, and workforce advanced with these financial resources. “This achievement reflects our team’s diligent stewardship of NASA’s resources, including our commitment to responsibly managing taxpayers’ dollars entrusted to the agency,” said Sidney Schmidt, NASA’s acting chief financial officer. “Their unwavering dedication to sound financial management and robust internal controls ensures we uphold public trust. Congratulations and thank you to everyone involved for your commendable efforts and hard work.” In fiscal year 2025, NASA marked significant progress toward the Artemis II test flight. Targeted to launch no earlier than Friday, Feb. 6, the Artemis II mission will send four astronauts around the Moon and back to test the systems and hardware which will return humanity to the lunar surface. NASA and its partners landed two robotic science missions on the Moon, welcomed seven new signatory countries to the Artemis Accords, and advanced medical and technological experiments for long-duration space missions like hand-held X-ray equipment and navigation capabilities. NASA also led a variety of science discoveries, including launching a joint satellite mission with India to regularly monitor Earth’s land and ice-covered surfaces, as well as identifying and tracking the third interstellar object in our solar system; achieved 25 continuous years of human presence aboard the International Space Station; and, for the first time, flew a test flight of the agency’s X-59 supersonic plane that will help revolutionize air travel. For more information on NASA’s budget, visit: [Hidden Content] -end- Bethany Stevens / Elizabeth Shaw Headquarters, Washington 202-358-1600 *****@*****.tld / *****@*****.tld Share Details Last Updated Jan 16, 2026 EditorJennifer M. DoorenLocationNASA Headquarters Related TermsBudget & Annual ReportsOffice of the Chief Financial Officer (OCFO) View the full article
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The crew of NASA’s Artemis II mission: NASA astronauts Christina Koch, Reid Wiseman, Victor Glover, and CSA (********* Space Agency) astronaut Jeremy Hansen.Credit: NASA NASA is weeks away from sending astronauts farther than any crew has traveled before, with the agency’s second mission in its Artemis campaign. The Artemis II Press Kit now is available with information on the mission, astronauts, and other resources for media. “Artemis II will be a momentous step forward for human spaceflight. This historic mission will send humans farther from Earth than ever before and deliver the insights needed for us to return to the Moon — all with America at the helm,” said NASA Administrator Jared Isaacman. “Artemis II represents progress toward establishing a lasting lunar presence and sending Americans to Mars. I could not be more impressed by our NASA team and the Artemis II crew, and wish them well. Boldly forward.” Under the Artemis campaign, NASA is returning humans to the Moon for economic benefits, scientific discovery, and to prepare for crewed missions to Mars. To learn more about Artemis, visit: [Hidden Content] -end- Lauren Low / Rachel Kraft Headquarters, Washington 202-358-1600 lauren.e*****@*****.tld / rachel.h*****@*****.tld Share Details Last Updated Jan 16, 2026 EditorJennifer M. DoorenLocationNASA Headquarters Related TermsMissionsArtemisArtemis 2 View the full article
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3 min read Preparations for Next Moonwalk Simulations Underway (and Underwater) By Supreet Kaur In an era where data security is critical to aviation safety, NASA is exploring bold new solutions. An Alta-X drone carries a custom built simulated Unmanned Aircraft Systems environment payload for the new blockchain system tests. Credit: NASA/Brandon Torres Navarette Through a drone flight test at NASA’s Ames Research Center in California’s Silicon Valley, researchers tested a blockchain-based system for protecting flight data. The system aims to keep air traffic management safe from disruption and protect data transferred between aircraft and ground stations from being intercepted or manipulated. For aviation and airspace operations to remain safe, users need to be able to trust that data is reliable and transparent. While current systems have been able to protect flight data systems, cyberthreats continue to evolve, requiring new approaches. NASA researchers found the blockchain-based system can safely transmit and store information in real time. Blockchain operates like a decentralized database — it does not rely on a single computer or centralized system. Instead, it shares information across a vast network, recording and verifying every change to a dataset. The system ensures the data stays safe, accurate, and trustworthy. Previous cybersecurity research focused on implementing a layered security architecture — using multiple physical and digital security measures to control system access. For this test, researchers took a different approach using blockchain to address potential threats. Using drones allowed the team to show that the blockchain framework could yield benefits across several priority areas in aviation development, including autonomous air traffic management, urban air mobility, and high-altitude aircraft. Terrence D. Lewis (left), Kale Dunlap (center), and Aidan Jones monitor the flow of telemetry from both actual and simulated flights, ensuring the simulation and blockchain systems are processing and recording data accurately. Credit: NASA/Brandon Torres Navarette This NASA research explored how blockchain can secure digital transactions between multiple systems and operators. The team used an open-source blockchain framework that allows trusted users real-time sharing and storage of critical data like aircraft operator registration information, flight plans, and telemetry. This framework restricts access to this data to trusted parties and approved users only. To further examine system resilience, the team introduced a set of cybersecurity tests designed to assess, improve, and reinforce security during operations in airspace environments. During an August flight at Ames, the team demonstrated these capabilities using an Alta-X drone with a custom-built software and hardware package that included a computer, radio, GPS system, and battery. The test simulated an environment with a drone flying in real-world conditions, complete with a separate ground control station and the blockchain and security infrastructure. The underlying blockchain framework and cybersecurity protocols can be extended to support high-altitude operations at 60,000 feet and higher and Urban Air Mobility operations, paving the way for a more secure, scalable, and trusted ecosystem. NASA researchers will continue to look at the data gathered during the test and apply what they’ve learned to future work. The testing will ultimately benefit U.S. aviation stakeholders looking for new tools to improve operations. Through its Air Traffic Management and Safety project, NASA performed research to transform air traffic management systems to safely accommodate the growing demand of new air vehicles. The project falls under NASA’s Airspace Operations and Safety Program, a part the agency’s Aeronautics Research Mission Directorate that works to enable safe, efficient aviation transportation operations that benefit the flying public and industry. View the full article
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5 Min Read Out of This World Discoveries: Space Station Research in 2025 As Earth completed its orbit around the Sun to close out 2025, the International Space Station circled our planet more than 5,800 times. Serving as humanity’s unique laboratory in space, the station has hosted thousands of experiments and technology demonstrations, advancing science in ways that cannot be replicated on Earth. In 2025 alone, more than 750 experiments supported exploration missions, improved life on Earth, and opened commercial opportunities in low Earth orbit. The space station continues to drive innovation by enabling human exploration of the Moon and Mars, transforming medical research, deepening our understanding of the universe, and fostering a growing commercial economy. Read through just a handful of 2025’s innovative research achievements from the orbiting laboratory. 25 Years of humans researching in orbit The International Space Station photographed in 2000 by the Expedition 1 crew.NASA On Nov. 2, 2025, humanity reached a milestone of cosmic proportions: 25 years of continuous human presence aboard the International Space Station. Since the first crew arrived on Nov. 2, 2000, NASA and its partners from around the world have conducted more than 4,000 research investigations and technology demonstrations. More than 290 people from 26 countries have visited the space station, where continuous human presence enables research that surpasses the capabilities of satellites and autonomous platforms. The space station’s unique microgravity environment, paired with crew operations, continues to unlock discoveries and push the boundaries of humanity’s curiosity and innovation. A breakthrough ******* treatment ESA (European Space Agency) astronaut Thomas Pesquet conducts research aboard the International Space Station supporting the advancement of ******* therapeutics.NASA Research aboard the International Space Station helped inform the development of a newly FDA-approved injectable medication used to treat several types of early-stage cancers. The research yielded early insights into the structure and size of particles needed to develop the medication through protein crystal growth experiments. This new delivery method promises to lower costs and significantly reduce treatment time for patients and healthcare providers, while maintaining drug efficiency. Microgravity research can produce higher-quality, medically relevant crystals than Earth-based labs, enabling these types of medical advances. These developments showcase how space station research can drive innovation, improve lives, and foster commercial opportunities. Medical implants printed in orbit Eight medical devices for peripheral nerve repair were printed simultaneously aboard the International Space Station. Credit: Auxilium Biotechnologies. Eight medical implants designed to support nerve regeneration were successfully 3D printed aboard the International Space Station for preclinical trials on Earth. When nerve damage occurs, these types of implants are designed to improve blood flow and enable targeted drug delivery. Printing in microgravity can prevent particle settling, resulting in more uniform and stable structures. In-space manufacturing is helping to advance medical treatments and other technologies while also enabling astronauts to print devices and tools on demand during future missions. Learn more about InSPA-Auxilium Bioprinter. A new understanding of our Sun Using data from NASA’s CODEX (Coronal Diagnostic Experiment), this animated, color-coded heat map shows temperature changes of the Sun over the course of couple days, where red indicates hotter regions and purple indicates cooler ones.NASA/KASI/INAF/CODEX Dextre, attached to the International Space Station’s Canadarm2 robotic arm, carries CODEX.NASA A solar coronagraph aboard the International Space Station captured its first unique images detailing the Sun’s outer atmosphere while measuring solar wind temperature and speed. The instrument blocks the Sun’s bright light to reveal its faint outer atmosphere, or corona, where solar wind originates. Earlier experiments focused on the corona’s density, but this new device enables the study of what heats and accelerates the solar wind, offering a more complete picture of how energy moves through the Sun’s atmosphere. These observations help researchers understand how solar activity affects Earth and space-based technology, such as satellites, communications networks, and power systems. Learn more about CODEX. Hunting for microscopic space travelers NASA astronaut Butch Wilmore works outside the International Space Station on Jan. 30, 2025, during a five-hour and 26-minute spacewalk.NASA NASA astronaut Butch Wilmore collected microbiological samples during a spacewalk outside the International Space Station. Samples were taken near the life support system vents to see if the orbital complex releases microorganisms. This experiment helps researchers examine if and how these microorganisms survive and reproduce in the harsh space environment, as well as how they may behave at destinations such as the Moon and Mars. After returning to Earth, the samples underwent DNA extraction and sequencing. Another round of collections is planned for future spacewalks. The data could help determine whether changes are needed on crewed spacecraft and spacesuits to reduce biocontamination during missions to explore destinations where life may exist now or in the past. Learn more about ISS External Microorganisms. A fully docked space station Northrop Grumman’s Cygnus XL spacecraft is grappled by the International Space Station’s Canadarm2. In the background, JAXA’s (Japan Aerospace Exploration Agency) HTV-X1 cargo craft is docked to the orbital complex.NASA The International Space Station visiting spacecraft configuration on Dec.1, 2025 showing eight spacecraft parked at the orbital complex.NASA For the first time in International Space Station history, all eight docking ports of the orbiting laboratory were occupied at once. Three crew spacecraft and five cargo resupply craft were attached to station, including JAXA’s new cargo vehicle HTV-X1 and Northrup Grumman’s new Cygnus XL. The eight spacecraft delivered astronauts, cargo, and scientific experiments from around the world to be conducted in the unique microgravity environment. This milestone highlights the space station’s evolution, inviting commercial partners and international collaboration to continue expanding the orbiting laboratory’s research capabilities. Space station research meets the Moon’s surface NICER (Neutron Star Interior Composition Explorer) is shown mounted to the International Space Station in the image on the left, and LEXI (right) is shown attached to the top of Firefly Aerospace’s Blue Ghost in an artist’s concept.NASA/Firefly Aerospace Three experiments that landed on the Moon during Firefly Aerospace’s Blue Ghost Mission-1 were enabled by earlier research aboard the International Space Station. These studies help improve space weather monitoring, test computer recovery from radiation damage, and advance lunar navigation systems. The orbiting laboratory continues to lay the foundation for missions beyond low Earth orbit, driving exploration deeper into space. Learn more. The space station continues to deliver out-of-this-world achievements that cannot be replicated on Earth. Its research capabilities are a springboard for humanity’s future in innovation and testing the limits of what’s possible. Here’s to 2026 — another year of defying physics and pushing the boundaries of science and exploration. Share Details Last Updated Jan 16, 2026 Related TermsISS ResearchCoronal Diagnostic Experiment (CODEX)Human Research ProgramHumans in SpaceInternational Space Station (ISS) Keep Exploring Discover More Topics From NASA Latest News from Space Station Research Humans In Space Space Station Research Results International Space Station View the full article
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NASA/Ben Smegelsky NASA’s Crawler-transporter 2 moves toward the Vehicle Assembly Building at NASA’s Kennedy Space Center in Florida on Friday, Jan. 9, 2026. The crawler will transport NASA’s SLS (Space Launch System) rocket with the Orion spacecraft to Launch Complex 39B ahead of the Artemis II launch which will journey Commander Reid Wiseman, Pilot Victor Glover, and Mission Specialist Christina Koch from NASA, and Mission Specialist Jeremy Hansen from the CSA (********* Space Agency), around the Moon and back to Earth no later than April 2026. The crawler-transporters have carried the load of taking rockets and spacecraft to the launch pad for more than 50 years at NASA’s Kennedy Space Center in Florida. Each the size of a baseball infield and powered by locomotive and large electrical power generator engines, the crawler-transporters stand ready to keep up the work for the next generation of launch vehicles to lift astronauts into space; Crawler-transporter 2 in particular is integral to the Artemis missions. Image credit: NASA/Ben Smegelsky View the full article
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[NASA] Hubble Observes Ghostly Cloud Alive with Star Formation
SpaceMan posted a topic in World News
Explore Hubble Hubble Home Overview About Hubble The History of Hubble Hubble Timeline Why Have a Telescope in Space? Hubble by the Numbers At the Museum FAQs Impact & Benefits Hubble’s Impact & Benefits Science Impacts Cultural Impact Technology Benefits Impact on Human Spaceflight Astro Community Impacts Science Hubble Science Science Themes Science Highlights Science Behind Discoveries Universe Uncovered Hubble’s Partners in Science Hubble & Citizen Science AI & Hubble Science Explore the Night Sky Observatory Hubble Observatory Hubble Design Mission Operations Science Operations Astronaut Missions to Hubble Hubble vs Webb Team Hubble Team Career Aspirations Hubble Astronauts Multimedia Images Videos Sonifications Podcasts e-Books Online Activities 3D Hubble Models Lithographs Fact Sheets Posters Hubble on the NASA App Glossary News Hubble News Social Media Media Resources More 35th Anniversary Online Activities 2 min read Hubble Observes Ghostly Cloud Alive with Star Formation A seemingly serene landscape of gas and dust is hopping with star formation behind the scenes. NASA, ESA, and K. Stapelfeldt (Jet Propulsion Laboratory); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (84.5 MB) While this eerie NASA Hubble Space Telescope image may look ghostly, it’s actually full of new life. Lupus 3 is a star-forming cloud about 500 light-years away in the constellation Scorpius. White wisps of gas swirl throughout the region, and in the lower-left corner resides a dark dust cloud. Bright T Tauri stars shine at the left, bottom right, and upper center, while other young stellar objects dot the image. T Tauri stars are actively forming stars in a specific stage of formation. In this stage, the enveloping gas and dust dissipates from radiation and stellar winds, or outflows of particles from the emerging star. T Tauri stars are typically less than 10 million years old and vary in brightness both randomly and periodically due to the environment and nature of a forming star. The random variations may be due to instabilities in the accretion disk of dust and gas around the star, material from that disk falling onto the star and being consumed, and flares on the star’s surface. The more regular, periodic changes may be caused by giant sunspots rotating in and out of view. T Tauri stars are in the process of contracting under the force of gravity as they become main sequence stars which fuse hydrogen to helium in their cores. Studying these stars can help astronomers better understand the star formation process. New images added every day between January 12-17, 2026! Follow @NASAHubble on social media for the latest Hubble images and news and see Hubble’s Stellar Construction Zones for more images of young stellar objects. Facebook logo @NASAHubble @NASAHubble Instagram logo @NASAHubble Explore More Exploring the Birth of Stars Hubble’s Nebulae Hubble’s Star Clusters Media Contact: Claire Andreoli NASA’s Goddard Space Flight Center, Greenbelt, MD *****@*****.tld Share Details Last Updated Jan 16, 2026 Location NASA Goddard Space Flight Center Related Terms Hubble Space Telescope Astrophysics Astrophysics Division Goddard Space Flight Center Protostars Stars The Universe Keep Exploring Discover More Topics From Hubble Hubble Space Telescope Since its 1990 launch, the Hubble Space Telescope has changed our fundamental understanding of the universe. Hubble’s Stellar Construction Zones Explore the Night Sky Hubble News View the full article -
Earth Observatory Science Earth Observatory Blooming Seas Around the… Earth Earth Observatory Image of the Day EO Explorer Topics All Topics Atmosphere Land Heat & Radiation Life on Earth Human Dimensions Natural Events Oceans Remote Sensing Technology Snow & Ice Water More Content Collections Global Maps World of Change Articles Notes from the Field Blog Earth Matters Blog Blue Marble: Next Generation EO Kids Mission: Biomes About About Us Subscribe 🛜 RSS Contact Us Search January 10, 2026 At about 800 kilometers (500 miles) east of New Zealand’s South Island, the sparsely populated Chatham Islands are rugged, remote, and often inconspicuous. In January 2026, however, a ring of bright green and blue swirls in the ocean put a natural spotlight on the far-flung specks of land. A bloom of phytoplankton—tiny photosynthetic organisms that become visible to satellites when their numbers explode—encircled the Chatham Islands in austral summer. Surface currents and eddies carried the floating organisms into intricate wisps and swirls. The VIIRS (Visible Infrared Imaging Radiometer Suite) on the NOAA-20 satellite captured this image of the display on January 10, 2026. The Chatham Islands sit on the Chatham Rise, an underwater plateau that extends eastward from the South Island of New Zealand. The top of the rise is relatively shallow and separates areas of deeper water to the north and south. These seafloor contours make blooms common along the Chatham Rise, where cold, nutrient-rich currents from the Antarctic and warm, nutrient-poor water from the subtropics converge. The well-mixed water, coupled with long daylight hours, can boost phytoplankton populations. With phytoplankton at the base of the food web, the waters around the Chatham Islands support productive fisheries, with valuable species such as pāua, rock lobster, and blue cod. The region is also home to an array of marine mammals, including five seal species and 25 whale and dolphin species. Amid this abundance, however, the islands are a hotspot for whale and dolphin strandings, in which hundreds of animals are sometimes beached. NASA Earth Observatory image by Lauren Dauphin, using VIIRS data from NASA EOSDIS LANCE, GIBS/Worldview, and the Joint Polar Satellite System (JPSS). Story by Lindsey Doermann. References & Resources Murphy, R. J., et al. (2001) Phytoplankton distributions around New Zealand derived from SeaWiFS remotely‐sensed ocean colour data. New Zealand Journal of Marine and Freshwater Research, 35(2), 343–362. NASA Earth Observatory (2009, December 28) Phytoplankton Bloom Over Chatham Rise, South Pacific. Accessed January 15, 2026. NASA Earthdata Ocean Color. Accessed January 15, 2026. New Zealand Department of Conservation Chatham Islands marine mammals. Accessed January 15, 2026. Pinkerton, M.H. (2011) A balanced trophic model of the Chatham Rise, New Zealand. Unpublished NIWA report. Downloads January 10, 2026 JPEG (743.36 KB) You may also be interested in: Stay up-to-date with the latest content from NASA as we explore the universe and discover more about our home planet. Islands of Fire and Ice Veiled in Cloud 3 min read Puffs of low-level clouds mingle with the volcanic terrain of Candlemas and Vindication islands in the remote South Atlantic. Article Bloom Time in the Barents Sea 2 min read Arctic waters near Norway’s Bear Island teemed with tiny plant-like organisms that painted the seas turquoise-blue and green. Article A Sea Aswirl With Chlorophyll 4 min read One of NASA’s newest Earth-observing sensors extends and improves the continuous measurement of light-harvesting pigments in ocean surface waters. Article 1 2 3 4 Next Keep Exploring Discover More from NASA Earth Science Subscribe to Earth Observatory Newsletters Subscribe to the Earth Observatory and get the Earth in your inbox. Earth Observatory Image of the Day NASA’s Earth Observatory brings you the Earth, every day, with in-depth stories and stunning imagery. Explore Earth Science Earth Science Data View the full article
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3 min read Preparations for Next Moonwalk Simulations Underway (and Underwater) Oregon Air National Guard ground crew guides one of the NASA’s newest F-15 aircraft onto the ramp at the agency’s Armstrong Flight Research Center in Edwards, California, on Monday, Dec. 22, 2025. The retired U.S. Air Force F-15s come from the Oregon Air National Guard’s 173rd Fighter Wing and will transition from military service to support NASA’s flight research fleet. NASA/Christopher LC Clark Oregon Air National Guard and NASA flight crew look out across the desert while awaiting the arrival of the NASA’s newest F-15 aircraft from the Oregon Air National Guard’s 173rd Fighter Wing to NASA’s Armstrong Flight Research Center in Edwards, California, on Monday, Dec. 22, 2025NASA/Christopher LC Clark NASA’s newest F-15 aircraft arrive at the agency’s Armstrong Flight Research Center in Edwards, California, on Monday, Dec. 22, 2025. The two retired U.S. Air Force F-15s will support ongoing supersonic flight research for NASA’s Flight Demonstrations and Capabilities Project and the Quesst mission’s X-59 quiet supersonic research aircraft.NASA/Christopher LC Clark NASA staff and Oregon Air National Guard’s 173rd Fighter Wing crew pose for a group photo at NASA’s Armstrong Flight Research Center in Edwards, California, on Monday, Dec. 22, 2025. The group stands in front of one of two F-15 aircraft added to the agency’s flight research fleet.NASA/Christopher LC Clark Oregon Air National Guard pilots deliver NASA’s newest F-15 aircraft from the Oregon Air National Guard’s 173rd Fighter Wing at Kingsley Field to NASA’s Armstrong Flight Research Center in Edwards, California, on Monday, Dec. 22, 2025. After completing their final flights with the Air Force, the two aircraft begin their new role supporting NASA’s flight research.NASA/Christopher LC Clark Two retired U.S. Air Force F-15 jets have joined the flight research fleet at NASA’s Armstrong Flight Research Center in Edwards, California, transitioning from military service to a new role enabling breakthrough advancements in aerospace. The F-15s will support supersonic flight research for NASA’s Flight Demonstrations and Capabilities project, including testing for the Quesst mission’s X-59 quiet supersonic research aircraft. One of the aircraft will return to the air as an active NASA research aircraft. The second will be used for parts to support long-term fleet sustainment. “These two aircraft will enable successful data collection and chase plane capabilities for the X-59 through the life of the Low ***** Flight Demonstrator project” said Troy Asher, director for flight operations at NASA Armstrong. “They will also enable us to resume operations with various external partners, including the Department of War and commercial aviation companies.” The aircraft came from the Oregon Air National Guard’s 173rd Fighter Wing at Kingsley Field. After completing their final flights with the Air Force, the two aircraft arrived at NASA Armstrong Dec. 22, 2025. “NASA has been flying F-15s since some of the earliest models came out in the early 1970s,” Asher said. “Dozens of scientific experiments have been flown over the decades on NASA’s F-15s and have made a significant contribution to aeronautics and high-speed flight research.” The F-15s allow NASA to operate in high-speed, high-altitude flight-testing environments. The aircraft can carry experimental hardware externally – under its wings or slung under the center – and can be modified to support flight research. Now that these aircraft have joined NASA’s fleet, the team at Armstrong can modify their software, systems, and flight controls to suit mission needs. The F-15’s ground clearance allows researchers to install instruments and experiments that would not fit beneath many other aircraft. NASA has already been operating two F-15s modified so their pilots can operate more comfortably at up to 60,000 feet, the top of the flight envelop for the X-59, which will cruise at 55,000 feet. The new F-15 that will fly for NASA will receive the same modification, allowing for operations at altitudes most standard aircraft cannot reach. The combination of capability, capacity, and adaptability makes the F-15s uniquely suited for flight research at NASA Armstrong. “The priority is for them to successfully support the X-59 through completion of that mission,” Asher said. “And over the longer term, these aircraft will help position NASA to continue supporting advanced aeronautics research and partnerships.” Share Details Last Updated Jan 15, 2026 EditorDede DiniusContactNicolas Cholulanicolas.h*****@*****.tld Related TermsAeronauticsAeronautics Research Mission DirectorateAmes Research CenterArmstrong Flight Research CenterCommercial Supersonic TechnologyFlight Demos CapabilitiesGlenn Research CenterLangley Research CenterLow ***** Flight DemonstratorQuesst (X-59)Supersonic Flight Explore More 6 min read Flight Engineers Give NASA’s Dragonfly Lift Article 6 days ago 6 min read NASA’s Pandora Satellite, CubeSats to Explore Exoplanets, Beyond Editor’s Note, Jan. 13, 2026: Mission controllers received full acquisition of signal from the Pandora… Article 6 days ago 1 min read NASA Starts Up Gateway’s Power System for First Time Article 1 week ago Keep Exploring Discover More Topics From NASA Armstrong Flight Research Center Humans in Space Climate Change Solar System View the full article
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4 Min Read NASA’s SpaceX Crew-11 Wraps Up Space Station Science NASA’s SpaceX Crew-11 mission with agency astronauts Zena Cardman and Mike Fincke, JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui, and Roscosmos cosmonaut Oleg Platonov returned to Earth after a long-duration mission aboard the International Space Station. During their stay, Cardman, Fincke, and Yui contributed more than 850 hours of research to help prepare humanity for the return to the Moon and future missions to Mars, while improving life back on Earth. Here’s a glimpse into the science completed during the Crew-11 mission: Bolstering bone resilience NASA astronaut Zena Cardman works with bone stem cells aboard the International Space Station to improve our understanding of how bone loss occurs during spaceflight. Studying bone cell activity in microgravity could help researchers learn how to control bone loss to protect astronauts’ bone density during future long-duration space missions and inform treatments for diseases like osteoporosis on Earth. Learn more about MABL-B. Observing Earth and beyond JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui photographs the Earth from the International Space Station’s cupola. For more than 40 years, astronauts have used hand-held cameras to capture millions of images documenting Earth’s geographic features, weather patterns, urban growth, changes to its surface, and the impacts of natural disasters such as hurricanes and floods. Astronauts also use the cupola and other viewports aboard the space station to gaze into the cosmos without Earth’s atmospheric interference. Just as viewing Earth from 250 miles above provides a new perspective on our home planet, looking out into the stars from the orbiting laboratory offers a clearer view of our universe. Space catch NASA astronaut Mike Fincke poses aboard the International Space Station with a new device designed to test an inflatable capture bag’s ability to open, close, and stay airtight in microgravity. This technology could be used to remove space debris from orbit, protecting future spacecraft and crew members. It also may enable trapping samples during exploration missions and support the capture and mining of small asteroids. Learn more about Capture Bag Demo. Tracking internal temperature NASA astronaut Mike Fincke wears a temperature-monitoring headband that tracks how the human body regulates its core temperature during spaceflight. Adjusting to living and working aboard the International Space Station can influence human temperature regulation. This headband provides an easy, non-invasive way to collect temperature data while astronauts conduct their daily activities. The sensor is also being tested on Earth and may help prevent hyperthermia in people working in high-temperature environments. Learn more about T-Mini. A new cargo vehicle JAXA’s (Japan Aerospace Exploration Agency) new cargo resupply spacecraft, HTV-X1, is shown after being captured by the International Space Station’s Canadarm2 robotic arm during the Crew-11 mission. The spacecraft launched from Tanegashima Space Center on Oct. 26, 2025, delivering approximately 12,800 pounds of science, supplies, and hardware to the orbital complex. New cargo spacecraft expand the station’s capability to support more research and receive critical supplies. Making nutrients on demand JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui holds yogurt bags produced aboard the International Space Station that could provide important nutrients during missions far from Earth. Certain nutrients degrade when stored for long periods of time, and deficiency in even one can lead to illness. Researchers are building on previous experiments to develop a method for producing on-demand vitamins and nutrients in space using microorganisms. Learn more about BioNutrients-3. Celebrating a historic milestone The Expedition 73 crew poses for a portrait to commemorate 25 years of continuous human presence aboard the International Space Station. In the front row from left, NASA astronaut Jonny Kim, Roscosmos cosmonaut Sergey Ryzhikov, and Roscosmos cosmonaut Alexey Zubritsky. In the back row, Roscosmos cosmonaut Oleg Platonov, NASA astronauts Mike Fincke and Zena Cardman, and JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui. A truly global endeavor, the space station has been visited by more than 290 people from 26 countries, along with a variety of international and commercial spacecraft. Since the first crew arrived, NASA and its partners have conducted thousands of research investigations and technology demonstrations to advance exploration of the Moon and Mars and benefit life on Earth. Share Details Last Updated Jan 15, 2026 Related TermsISS ResearchHuman Research ProgramHumans in SpaceInternational Space Station (ISS) Keep Exploring Discover More Topics From NASA International Space Station Space Station Research and Technology Resources Space Station Research Results Latest News from Space Station Research View the full article
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Earth (ESD) Earth Explore Explore Earth Home Agriculture Air Quality Climate Change Freshwater Life on Earth Severe Storms Snow and Ice The Global Ocean Science at Work Earth Science at Work Technology and Innovation Powering Business Multimedia Image Collections Videos Data For Researchers About Us 6 Min Read NASA Data Helps Maine Oyster Farmers Choose Where to Grow The Landsat satellites are helping oyster farmers in Maine see which coves run warmer or cooler from space. Credits: NASA/Ross Walter and Allison Nussbaum When oyster farmer Luke Saindon went looking for a place to grow shellfish in Maine, he knew that picking the wrong patch of water could sink the farm before it began. So Saindon did something oyster farmers couldn’t have done a generation ago: He used NASA satellite data to view the coastline from space. “Starting a farm is a big venture,” said Saindon, the director for The World Is Your Oyster farm in Wiscasset, Maine. “If you choose the wrong spot, you can blow through a lot of money without ever bringing oysters to market.” NASA satellites had been passing over these waters for years, recording temperatures and other conditions. Using a site-selection tool created by University of Maine researchers, Saindon examined satellite maps showing where water temperatures and food levels might be best for growing oysters. The maps pointed him toward a wide, shallow bay near his home. Four years later, the farm is still there — and the oysters are thriving. Luke Saindon, director of The World Is Your Oyster farm in Wiscasset, Maine, checks oyster cages on the farm’s floating platform. © Jacqueline Clarke/The World Is Your Oyster, used with permission Saindon believes that using the satellite data to select his oyster farm site resulted in faster-than-average growth rates. “This is an example of how NASA’s Earth science program supports our nation,” said Chris Neigh, the Landsat 8 and 9 project scientist at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “We collect global data, but its value grows when it’s used locally to help communities work smarter and make their livelihoods more sustainable.” From orbit to oyster That same satellite-based approach is now the foundation of a study published Jan. 15 in the journal Aquaculture. Led by University of Maine scientists Thomas Kiffney and Damian Brady, the research demonstrates how temperature data from Landsat — the joint NASA and U.S. Geological Survey mission — combined with European Sentinel-2 satellite estimates of oyster food availability, namely plankton, can predict how quickly eastern oysters (Crassostrea virginica) reach market size. The team built a satellite data–driven model of how oysters divide their energy among growth, survival, and reproduction. Feed the model sea surface temperature and satellite estimates of chlorophyll and particulate organic matter — signals of how much plankton and other edible particles are in the water — and it predicts how fast oysters will grow, a big step beyond just spotting good or bad sites for farms. “By showing where oysters grow faster, the model can help farmers plan ahead,” Kiffney said. “That could mean better decisions about when to seed, when to harvest, and how much product to expect, all of which reduces financial risk.” That kind of insight is increasingly valuable in Maine, where oyster farming has grown rapidly over the last decade. From 2011 to 2021, the industry’s value increased 78%, rising from about $2.5 million to more than $10 million. As the sector scales up, understanding the finer details of Maine’s coastal waters has become essential — and that’s where NASA satellites come in. The stakes are considerable. “It takes two to three years of scoping in order to get your permit to grow, and then it can take two years for those oysters to reach market,” Brady said. “So if you’ve chosen the wrong site, you’re four years in the hole right off the bat.” Sharper eyes on coast Maine’s coastline measures about 3,400 miles (5,500 kilometers) if you follow the tide line. It is a coast of drowned valleys and glacier-scoured granite. Water depth, temperature, and circulation can shift dramatically within a few miles. This complexity makes oyster site selection notoriously difficult, and some satellites that see the coast in broad strokes miss the small, patchy places where oysters live. “What makes Landsat so powerful for aquaculture is its ability to see finer-scale patterns along the coast,” where farmers put oyster cages in the water, Neigh said. This false-color image from Landsat 9’s Thermal Infrared Sensor, acquired Oct. 11, 2025, shows the thermal signature of waters off the coast of Maine — revealing finer-scale temperature differences between neighboring coves. Cooler waters appear purple and blue, while warmer water shows up in orange and yellow. NASA/Ross Walter and Allison Nussbaum Landsat 8 and 9’s pixels — 98 to 328 feet (30 to 100 meters) across — are able to distinguish more subtle temperature differences between neighboring coves. For a cold-blooded oyster, those distinctions can translate into months of growth. Warm water accelerates feeding and shell development. Cold water slows both. A challenge for satellites is clouds. Maine’s sky is frequently overcast, and together Landsat 8 and 9 pass over any given point only every eight days. To work around this, the research team analyzed 10 years of Landsat data (2013–2023) and built seasonal “climatologies,” or average temperature patterns for every 98-foot (30-meter) pixel along the coast. Sentinel-2 imagery added estimates of chlorophyll and particulate organic matter, the drifting microscopic food that oysters pull from the water column with rhythmic contractions of their gills. Field tests at multiple sites showed the technique’s accuracy. “We validated the model against seven years of field data,” Brady said. “It’s a strong indication that these remotely sensed products can inform not just where to grow, but how long it will take to harvest.” Turning satellite science into tools for growers The University of Maine team is now developing an online tool to put this model into practice. A grower will be able to click on a coastal location and receive an estimate for time-to-market. The researchers also assist with workshops through Maine’s Aquaculture in Shared Waters program, teaching farmers how to interpret temperature and water clarity data and apply them to their own sites. Monique Boutin, an aquaculture technician with The World Is Your Oyster farm, sorts oysters during harvest work on the water in Maine. © Nina Boutin/The World Is Your Oyster, used with permission For farmers like Saindon, that translates into something simpler: confidence and efficiency. “Having these kinds of tools lowers the barrier for new people to get into aquaculture,” he said. “It gives you peace of mind that you’re not just guessing.” The Maine project is helping pave the way for other NASA missions. The PACE satellite (Plankton, Aerosol, Cloud, ocean Ecosystem) launched in 2024 and is now delivering hyperspectral observations of coastal waters. Where earlier sensors could estimate how much plankton was present, PACE can begin to identify the different plankton species themselves. For oysters, mussels, and other filter feeders, that specificity matters. Not all plankton are equal food: Different kinds offer different nutrition, and some plankton are harmful to oysters. A next step will be turning that richer picture of coastal life into forecasts people working on the water can use, helping farmers trade some of the coast’s mystery for evidence they can apply to their harvest. By Emily DeMarco NASA’s Goddard Space Flight Center, Greenbelt, Md. Share Details Last Updated Jan 15, 2026 Editor Christina Campen Contact Emily DeMarco emily.p*****@*****.tld Location Goddard Space Flight Center Related Terms Earth Agriculture Goddard Space Flight Center Human Dimensions Landsat Oceans PACE (Plankton, Aerosol, Cloud, Ocean Ecosystem) Water on Earth Keep Exploring Discover More Topics From NASA Earth Your home. Our Mission. And the one planet that NASA studies more than any other. Earth Observatory NASA’s Earth Observatory brings you the Earth, every day: images, stories, and discoveries about the environment, Earth systems, and climate. Explore Earth Science Earth Science in Action NASA’s unique vantage point helps us inform solutions to enhance decision-making, improve livelihoods, and protect our planet. View the full article
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Jets of ionized gas streak across a cosmic landscape from a newly forming star.NASA, ESA, and B. Reipurth (Planetary Science Institute); Processing: Gladys Kober (NASA/Catholic University of America) This new NASA Hubble Space Telescope image captures a jet of gas from a forming star shooting across the dark expanse. The bright pink and green patches running diagonally through the image are HH 80/81, a pair of Herbig-Haro (HH) objects previously observed by Hubble in 1995. The patch to the upper left is part of HH 81, and the bottom streak is part of HH 80. Herbig-Haro objects are bright, glowing regions that occur when jets of ionized gas ejected by a newly forming star collide with slower, previously ejected outflows of gas from that star. HH 80/81’s outflow stretches over 32 light-years, making it the largest protostellar outflow known. Protostars are fed by infalling gas from the surrounding environment, some of which can be seen in residual “accretion disks” orbiting the forming star. Ionized material within these disks can interact with the protostars’ strong magnetic fields, which channel some of the particles toward the pole and outward in the form of jets. As the jets eject material at high speeds, they can produce strong shock waves when the particles collide with previously ejected gas. These shocks heat the clouds of gas and excite the atoms, causing them to glow in what we see as HH objects. HH 80/81 are the brightest HH objects known to exist. The source powering these luminous objects is the protostar IRAS 18162-2048. It’s roughly 20 times the mass of the Sun, and it’s the most massive protostar in the entire L291 molecular cloud. From Hubble data, astronomers measured the speed of parts of HH 80/81 to be over 1,000 km/s, the fastest recorded outflow in both radio and visual wavelengths from a young stellar object. Unusually, this is the only HH jet found that is driven by a young, very massive star, rather than a type of young, low-mass star. The sensitivity and resolution of Hubble’s Wide Field Camera 3 was critical to astronomers, allowing them to study fine details, movements, and structural changes of these objects. The HH 80/81 pair lies 5,500 light-years away within the Sagittarius constellation. View the full article
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Explore Hubble Hubble Home Overview About Hubble The History of Hubble Hubble Timeline Why Have a Telescope in Space? Hubble by the Numbers At the Museum FAQs Impact & Benefits Hubble’s Impact & Benefits Science Impacts Cultural Impact Technology Benefits Impact on Human Spaceflight Astro Community Impacts Science Hubble Science Science Themes Science Highlights Science Behind Discoveries Universe Uncovered Hubble’s Partners in Science Hubble & Citizen Science AI & Hubble Science Explore the Night Sky Observatory Hubble Observatory Hubble Design Mission Operations Science Operations Astronaut Missions to Hubble Hubble vs Webb Team Hubble Team Career Aspirations Hubble Astronauts Multimedia Images Videos Sonifications Podcasts e-Books Online Activities 3D Hubble Models Lithographs Fact Sheets Posters Hubble on the NASA App Glossary News Hubble News Social Media Media Resources More 35th Anniversary Online Activities 3 min read Hubble’s Album of Planet-Forming Disks Hubble images of protoplanetary disks in visible and infrared light show dusty regions around newly developing stars where planets may form. Left: NASA, ESA, and K. Stapelfeldt (Jet Propulsion Laboratory); Processing: Gladys Kober (NASA/Catholic University of America) Right: NASA, ESA, and T. Megeath (University of Toledo); Processing: Gladys Kober (NASA/Catholic University of America) This collection of new images taken by NASA’s Hubble Space Telescope showcases protoplanetary disks, the swirling masses of gas and dust that surround forming stars, in both visible and infrared wavelengths. Through observations of young stellar objects like these, Hubble helps scientists better understand how stars form. Jets of gas blast from protostars in these visible-light images. HH 390’s outflow is accompanied by a one-sided nebula, evidence that the protoplanetary disk is not viewed edge-on from our perspective. Tau 042021 is a large, symmetrical disk seen edge-on, and is in a late stage of dust evolution, since the dust particles have clumped together into larger grains. HH 48 is a binary protostar system in which gravitational tidal forces from the larger star appear to be influencing the disk of the secondary object. ESO Hα574 is a very compact disk with a “collimated” ― or beam-like and linear ― outflow, and one of the faintest edge-on disks yet recognized. NASA, ESA, and K. Stapelfeldt (Jet Propulsion Laboratory); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (34.6 MB) These visible-light images depict dark, planet-forming dust disks around a hidden, newly developing star, called a protostar. Bipolar jets of fast-moving gases, traveling at about 93 miles (150 km) per second, shoot from both ends of the protostar. The top two images are of protostars found about 450 light-years away in the Taurus Molecular Cloud, while the bottom two are almost 500 light-years away in the Chameleon I star-forming region. Stars form out of collapsing clouds of gas and dust. As surrounding gas and dust falls toward the protostar, some of it forms a rotating disk around the star that continues to feed the growing object. Planets form from the remaining gas and dust orbiting the star. The bright yellow regions above and below the spinning disks are reflection nebulae, gas and dust lit up by the light of the star. The jets that are released from the magnetic poles of the stars are an important part of their formation process. The jets, channeled by the protostar’s powerful magnetic fields, disperse angular momentum, which is due to rotational movement of the object. This allows the protostar to spin slowly enough for material to collect. In the images, some of the jets appear to broaden. This occurs when the fast jet collides with the surrounding gas and causes it to glow, an effect called a shock emission. Bright central protostars and the shadows of their dusty disks appear in these infrared images. NASA, ESA, and T. Megeath (University of Toledo); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (36.6 MB) These edge-on views of protostars in infrared light also reveal thick, dusty protoplanetary disks. The dark areas may look like very large disks, but they are actually much wider shadows cast in the surrounding envelope by the central disks. The bright haze throughout the image comes from light scattering off of the surrounding cloud’s dust grains. The top right and bottom left stars reside in the Orion Molecular Cloud complex about 1,300 light-years away, and the top left and bottom right stars lie in the Perseus Molecular Cloud roughly 1,500 light-years away. In its early stages, these disks draw from the dust that remains around the forming stars. Unlike visible light, infrared light can travel through this “protostellar envelope.” The protostars in the visible images above are further along in their evolution, so much of the dusty envelope has dissipated. Otherwise, they could not be seen in visible wavelengths. Viewed in infrared light, the central star is visible through the thick dust of the protoplanetary disks. Bipolar jets are also present but not visible because the hot gas emission isn’t strong enough for Hubble to detect. HOPS 150 in the top right is actually in a binary system, in orbit with another young protostar. HOPS 150’s companion, HOPS 153, is not pictured in this image. From a wider Hubble survey of Orion protostars, including HOPS 150 and HOPS 367, astronomers found that regions with a higher density of stars tend to have more companion stars. They also found a similar number of companions between main-sequence (active, hydrogen-fusing stars) and their younger counterparts. New images added every day between January 12-17, 2026! Follow @NASAHubble on social media for the latest Hubble images and news and see Hubble’s Stellar Construction Zones for more images of young stellar objects. Facebook logo @NASAHubble @NASAHubble Instagram logo @NASAHubble Explore More Finding Plantary Construction Zones Hubble’s Exoplanets Recognizing Worlds Beyond Our Sun Media Contact: Claire Andreoli NASA’s Goddard Space Flight Center, Greenbelt, MD *****@*****.tld Share Details Last Updated Jan 15, 2026 Location NASA Goddard Space Flight Center Related Terms Hubble Space Telescope Astrophysics Astrophysics Division Goddard Space Flight Center Protostars Stars The Universe Keep Exploring Discover More Topics From Hubble Hubble Space Telescope Since its 1990 launch, the Hubble Space Telescope has changed our fundamental understanding of the universe. Hubble’s Stellar Construction Zones Explore the Night Sky Hubble News View the full article
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Roscosmos cosmonaut Oleg Platonov, left, NASA astronauts Mike Fincke, Zena Cardman, and JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui are seen inside the SpaceX Dragon Endeavour spacecraft onboard the SpaceX recovery ship SHANNON shortly after having landed in the Pacific Ocean off the coast of Long Beach, Calif., Thursday, Jan. 15, 2026. Cardman, Fincke, Yui, Platonov are returning after 167 days in space as part of Expedition 74 aboard the International Space Station.NASA/Bill Ingalls NASA’s SpaceX Crew-11 mission safely splashed down early Thursday morning in the Pacific Ocean off the coast of San Diego, concluding a more than five-month mission aboard the International Space Station. NASA astronauts Zena Cardman and Mike Fincke, JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui, and Roscosmos cosmonaut Oleg Platonov returned to Earth at 12:41 a.m. PST. Teams aboard SpaceX recovery vessels retrieved the spacecraft and its crew shortly after landing. “I couldn’t be prouder of our astronauts and the teams on the ground at NASA, SpaceX, and across our international partnerships,” said NASA Administrator Jared Isaacman. “Their professionalism and focus kept the mission on track, even with an adjusted timeline. Crew-11 completed more than 140 science experiments that advance human exploration. Missions like Crew-11 demonstrate the capability inherent in America’s space program—our ability to bring astronauts home as needed, launch new crews quickly, and continue pushing forward on human spaceflight as we prepare for our historic Artemis II mission, from low Earth orbit to the Moon and ultimately Mars.” Crew-11 returned home about a month earlier than planned because of a medical concern teams are monitoring with one of the crew members, who remains stable. Due to medical privacy, it is not appropriate for NASA to share more details about the crew member. Prior to return, NASA previously coordinated for all four crew members to be transported to a local hospital for additional evaluation, taking advantage of medical resources on Earth to provide the best care possible. Following the planned overnight hospital stay, the crew members will return to NASA’s Johnson Space Center in Houston and undergo standard postflight reconditioning and evaluations. The Crew-11 mission lifted off at 11:43 a.m. EDT on Aug.1, 2025, from Launch Complex 39A at NASA’s Kennedy Space Center in Florida. About 15 hours later, the crew’s SpaceX Dragon spacecraft docked to the orbital outpost at 1:27 a.m. CDT on Aug. 2. During their 167-day mission, the four crew members traveled nearly 71 million miles and completed more than 2,670 orbits around Earth. The Crew-11 mission was Fincke’s fourth spaceflight, Yui’s second, and the first for Cardman and Platonov. Fincke has logged 549 days in space, ranking him fourth among all NASA astronauts for cumulative days in space. Along the way, Crew-11 logged hundreds of hours of research, maintenance, and technology demonstrations. The crew members also celebrated the 25th anniversary of continuous human presence aboard the orbiting laboratory on Nov. 2, 2025. Research conducted aboard the space station advances scientific knowledge and demonstrates new technologies that enable us to prepare for human exploration of the Moon and Mars. NASA’s Commercial Crew Program provides reliable access to space, maximizing the use of the International Space Station for research and development by partnering with private U.S. companies, including SpaceX, to transport astronauts to and from the space station. Learn more about NASA’s Commercial Crew Program at: [Hidden Content] -end- Joshua Finch / Jimi Russell Headquarters, Washington 202-358-1100 *****@*****.tld / *****@*****.tld Sandra Jones / Joseph Zakrzewski Johnson Space Center, Houston 281-483-5111 sandra.p*****@*****.tld / *****@*****.tld Steven Siceloff Kennedy Space Center, Florida 321-867-2468 steven.p*****@*****.tld Share Details Last Updated Jan 15, 2026 LocationNASA Headquarters Related TermsHumans in SpaceCommercial CrewInternational Space Station (ISS)NASA Headquarters View the full article
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Earth Observatory Science Earth Observatory Clouds Swimming over Lago… Earth Earth Observatory Image of the Day EO Explorer Topics All Topics Atmosphere Land Heat & Radiation Life on Earth Human Dimensions Natural Events Oceans Remote Sensing Technology Snow & Ice Water More Content Collections Global Maps World of Change Articles Notes from the Field Blog Earth Matters Blog Blue Marble: Next Generation EO Kids Mission: Biomes About About Us Subscribe 🛜 RSS Contact Us Search December 27, 2025 When an astronaut aboard the International Space Station snapped this photograph of Lago Argentino in Patagonia on December 27, 2025, a school of fish-shaped clouds lingered over the glacial lake’s teal waters. Determining the clouds’ type and origin from the photograph alone is challenging, but several NASA scientists and university researchers offered a theory after reviewing the image. “The lens shape reminds me of lenticular clouds, which usually form near or over mountains,” said Maria Hakuba, a research scientist in the aerosols and clouds group at NASA’s Jet Propulsion Laboratory. “The edges of the cloud also look quite smooth rather than ‘fuzzy,’ which suggests they’re ice clouds that are relatively high up.” Lenticular clouds form as a result of lee waves, which develop when prevailing winds are forced up and over a topographic barrier, often a mountain range, and when the overlying air is stable. Air expands and cools at the crest of the waves, causing vapor to condense and form cloud droplets. Conversely, air on the other side of the waves descends, warming the air and causing the cloud to evaporate. The result is a set of seemingly stationary clouds that hover in place downwind of mountains. Lenticular clouds are often eye-catching, sometimes described as having shapes like almonds, upside-down dinner plates, lentils, flying saucers, or stacks of pancakes. Hazem Mahmoud, an atmospheric science lead at NASA’s Langley Research Center, agreed that the clouds were likely lenticular and offered additional insight. MODIS (Moderate Resolution Spectroradiometer) data suggest cloud-top altitudes near 9,200 meters (30,000 feet) and cloud-top temperatures around 220 Kelvin, along with relatively large particle sizes consistent with the presence of ice crystals, he said. “The high altitude and microphysical properties suggest Cirrocumulus lenticularis,” he said. Strong surface-level winds common in Patagonia likely swept across the glacial lakes of Los Glaciares National Park, forcing unusually moist air over the Andes, producing the lens-shaped clouds. Sublimation—the conversion of ice directly into water vapor—of glacial ice likely contributed to their formation by adding extra moisture into the air, he added. Wind shear and turbulence may have caused the elongated, trailing appearance that made the clouds resemble a school of fish, Mahmoud explained. These forces stretched and organized the clouds horizontally above the lake, while shadows cast onto the landscape accentuated their forms. “Together these clouds tell a remarkable story of interaction between the lake’s moisture source, the Andes’ dynamic topography, and atmospheric circulation,” he said. Santiago Gassó, an atmospheric scientist at NASA’s Goddard Space Flight Center, agreed they were likely lenticular clouds, citing the environmental context and Patagonia’s reputation as a hotspot for lenticular cloud formation. “Very often the clouds here are stationary and trapped by lee waves on the downwind side of the mountains,” Gassó said. “They often don’t precipitate because most of the moisture gets left on the west side of the mountain.” The stereotypical image of lenticular clouds is that they sit stationary at the top of mountains, but in reality, they tend to drift away “depending on the turbulence and flow,” he added. All three scientists agreed that without analyzing more data, it’s hard to say definitively whether the cloud is lenticular or a type of cumulus. The challenge with a single astronaut photograph or satellite image is that we largely see the cloud-top properties, Mahmoud said. “If we also had lidar or cloud radar data, we could measure the vertical structure and thickness and more confidently differentiate a thin lenticular layer from a deep cumulonimbus column,” he said. Whether cumulus or lenticular, it’s a coincidence that “fish” is the name atmospheric scientists sometimes use to describe formations of a type of shallow convective cloud found over the ocean. It was one of the patterns, along with “sugar,” “gravel,” and “flowers,” identified by a team of researchers who analyzed decades of MODIS cloud observations. Readers with a penchant for cloud classification can participate in GLOBE Clouds, a GLOBE citizen science project that makes it possible for students and members of the public to contribute to NASA research projects. As part of the project, participants have the opportunity to use Clouds Wizard, a feature that guides users through cloud identification with a series of interactive questions, animations, and photos. Astronaut photograph ISS074-E-8940 was acquired on December 27, 2025, with a Nikon Z9 digital camera using a focal length of 116 millimeters. It is provided by the ISS Crew Earth Observations Facility and the Earth Science and Remote Sensing Unit at NASA Johnson Space Center. The image was taken by a member of the Expedition 74 crew. The image has been cropped and enhanced to improve contrast, and lens artifacts have been removed. The International Space Station Program supports the laboratory as part of the ISS National Lab to help astronauts take pictures of Earth that will be of the greatest value to scientists and the public, and to make those images freely available on the Internet. Additional images taken by astronauts and cosmonauts can be viewed at the NASA/JSC Gateway to Astronaut Photography of Earth. Story by Adam Voiland. References & Resources Alexander, J.M. & Teitelbaum, H. (2011) Three-dimensional properties of Andes mountain waves observed by satellite: A case study. Journal of Geophysical Research Atmospheres, 116(D23). American Meteorological Society Lenticularis. Accessed January 14, 2026. American Meteorological Society Cumulus. Accessed January 14, 2026. Bony, S., et al. (2020) Sugar, Gravel, Fish, and Flowers: Dependence of Mesoscale Patterns of Trade-Wind Clouds on Environmental Conditions. Geophysical Research Letters, 47(7), e2019GL085988. DLR Institute of Atmospheric Physics (2020, September 7) Discovery of record-breaking mountain waves above the South American Andes. Accessed January 14, 2026. The GLOBE Observer What is GLOBE Clouds? Accessed January 14, 2026. Mount Washington Observatory A Closer Look at Lenticular Clouds. Accessed January 14, 2026. NASA Earth Observatory (2024, September 12) Marvelous Lenticularis. Accessed January 14, 2026. Pautet, P.D., et al. (2021) Mesospheric Mountain Wave Activity in the Lee of the Southern Andes. Journal of Geophysical Research: Atmospheres 126(7). Smith, R. (2005) Orographic Atmospheric Phenomena in Patagonia: A preliminary survey. Croatian Meteorological Journal, 40(40), 325-328. World Meteorological Organization Lenticularis. Accessed January 14, 2026. Downloads December 27, 2025 JPEG (10.18 MB) You may also be interested in: Stay up-to-date with the latest content from NASA as we explore the universe and discover more about our home planet. The Galaxy Next Door 3 min read The Large Magellanic Cloud—one of our closest neighboring galaxies—is a hotbed of star formation that is visible to both astronauts… Article Kamchatka Peaks Pierce the Clouds 3 min read The peninsula in eastern Siberia features rugged terrain with towering, snow-covered peaks and cloud-filled valleys stretching between the Pacific Ocean… Article Nighttime Over the Eastern Pacific 2 min read A long-exposure photo taken from low Earth orbit captured the brilliant illumination coming from airglow, lightning, and stars. Article 1 2 3 4 Next Keep Exploring Discover More from NASA Earth Science Subscribe to Earth Observatory Newsletters Subscribe to the Earth Observatory and get the Earth in your inbox. Earth Observatory Image of the Day NASA’s Earth Observatory brings you the Earth, every day, with in-depth stories and stunning imagery. Explore Earth Science Earth Science Data View the full article
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NASA’s SLS (Space Launch System) rocket is seen inside High Bay 3 of the Vehicle Assembly Building as teams await the arrival of Artemis II crewmembers to board their Orion spacecraft on top of the rocket as part of the Artemis II countdown demonstration test, Saturday, Dec. 20, 2025, at NASA’s Kennedy Space Center in Florida.Credit: NASA/Joel Kowsky NASA’s integrated SLS (Space Launch System) rocket and Orion spacecraft for the Artemis II mission is inching closer to launch – literally. The agency is targeting no earlier than 7 a.m. EST, Saturday, Jan. 17, to begin the multi-hour trek from the Vehicle Assembly Building to Launch Pad 39B at NASA’s Kennedy Space Center in Florida. A pre rollout mission news conference, live feed of rollout, and a media gaggle will stream on NASA’s YouTube channel. Individual streams for each of these events will be available from that page. Learn how to stream NASA content through a variety of online platforms, including social media. The time of rollout is subject to change if additional time is needed for technical preparations or weather. All times are Eastern. Events are as follows: Friday, Jan. 16: 12 p.m.: Artemis II Rollout, Mission Overview News Conference John Honeycutt, Artemis II mission management team chair Charlie Blackwell-Thompson, Artemis launch director, Exploration Ground Systems Jeff Radigan, Artemis II lead flight director, Flight Operations Directorate Lili Villarreal, landing and recovery director, Exploration Ground Systems Jacob Bleacher, chief exploration scientist, Exploration Systems Development Mission Directorate Saturday, Jan. 17: 7 a.m.: Rollout, Artemis II Live Views from Kennedy Space Center feed begins 9 a.m.: Artemis II Crew Rollout Media Event NASA Administrator Jared Isaacman and the Artemis II crew, including NASA astronauts Reid Wiseman, Victor Glover, and Christina Koch, and CSA (********* Space Agency) astronaut Jeremy Hansen, will answer questions about their preparations and the mission for media in-person at the countdown clock. NASA’s crawler-transporter 2 will carry the 11-million-pound stack at about one mile per hour along the four-mile route from the Vehicle Assembly Building to Launch Pad 39B, on a journey that will take up to 12 hours. To participate in the news conference by telephone, media must RSVP no later than two hours before the start to: ksc*****@*****.tld. These events will be open in-person only to media previously credentialed for launch. The deadline has passed for in-person accreditation for Artemis II events at Kennedy. Rollout to the pad marks another milestone leading up to the Artemis II mission. In the coming weeks, NASA will complete final preparations of the rocket and, if needed, rollback SLS and Orion to the Vehicle Assembly Building for additional work. While the Artemis II launch window opens as early as Friday, Feb. 6, the mission management team will assess flight readiness after the wet dress rehearsal across the spacecraft, launch infrastructure, and the crew and operations teams before selecting a launch date. Follow NASA’s Artemis blog for mission updates. Through Artemis, 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. Learn more about Artemis at: [Hidden Content] -end- Rachel Kraft / Lauren Low Headquarters, Washington 202-358-1600 rachel.h*****@*****.tld / lauren.e*****@*****.tld Tiffany Fairley Kennedy Space Center, Fla. 321-867-2468 *****@*****.tld Share Details Last Updated Jan 14, 2026 EditorJennifer M. DoorenLocationNASA Headquarters Related TermsMissionsArtemisArtemis 2Exploration Systems Development Mission Directorate View the full article
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NASA The New York–Newark–Jersey City Metropolitan Statistical Area, which spans 23 counties across New York, New Jersey, and Connecticut and has a population of about 19.9 million, is pictured at approximately 3:29 a.m. local time Dec. 20, 2025, from the International Space Station as it orbited 262 miles above the Atlantic coast. Crew members aboard the orbital lab have produced hundreds of thousands of images of the land, oceans, and atmosphere of Earth, and even of the Moon through Crew Earth Observations. Their photographs of Earth record how the planet changes over time due to human activity and natural events. This allows scientists to monitor disasters and direct response on the ground and study a number of phenomena, from the movement of glaciers to urban wildlife. Image credit: NASA View the full article
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Credit: NASA Read this press release in English here. La temperatura global de la superficie terrestre en 2025 fue un poco más cálida que en 2023 pero, dentro de los márgenes de error, ambos años está prácticamente empatados, según un análisis realizado por científicos de la NASA. Desde que comenzaron los registros en 1880, 2024 sigue siendo el año más caluroso. Las temperaturas globales en 2025 fueron más frías que en 2024, **** temperaturas promedio de 1,19° Celsius (2,14° Fahrenheit) por encima del promedio para el período de 1951 a 1980. El análisis del Instituto Goddard de Estudios Espaciales de la NASA incluye datos de la temperatura del aire obtenidos por más de 25.000 estaciones meteorológicas en todo el mundo, así como por instrumentos a bordo de barcos y boyas que miden la temperatura de la superficie del mar, y estaciones de investigación en la Antártida. Los datos son analizados utilizando métodos que toman en cuenta la distribución cambiante de las estaciones de medición de temperatura y los efectos del calentamiento urbano que podrían sesgar los cálculos. Además, análisis independientes realizados por la Administración Nacional Oceánica y Atmosférica (NOAA, por sus siglas en inglés), la plataforma Berkeley Earth, el Centro Hadley (que forma parte del servicio meteorológico nacional del Reino Unido) y los Servicios Climáticos Copernicus de Europa han concluido que la temperatura global de la superficie para 2025 ha sido la tercera más calurosa que se haya registrado. Estos científicos utilizan gran parte de los mismos datos de temperatura en sus análisis, pero emplean diferentes metodologías y modelos; todos ellos muestran la misma tendencia al calentamiento continuo. El conjunto completo de datos de la NASA sobre las temperaturas de la superficie global, así como los detalles de cómo los científicos de la NASA llevaron a ***** el análisis, están disponibles públicamente en línea (en inglés). Para obtener más información sobre los programas de ciencias de la Tierra de la NASA, visita el sitio web: [Hidden Content] -fin- Liz Vlock / María José Viñas Sede central, Washington 202-358-1600 *****@*****.tld / *****@*****.tld Peter Jacobs Centro de Vuelo Espacial Goddard, Greenbelt, MD 301-286-0535 *****@*****.tld Share Details Last Updated Jan 14, 2026 EditorJessica TaveauLocationNASA Headquarters Related TermsNASA en españolEarth Science DivisionGoddard Institute for Space StudiesScience Mission Directorate View the full article
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Credit: NASA Earth’s global surface temperature in 2025 was slightly warmer than 2023 – but within the margin of error the two years are effectively tied according to an analysis by NASA scientists. Since record-keeping began in 1880, the hottest year on record remains 2024. Global temperatures in 2025 were cooler than 2024, with average temperatures of 2.14 degrees Fahrenheit (1.19 degrees Celsius) above the 1951 to 1980 average. The analysis from NASA’s Goddard Institute for Space Studies includes air temperature data acquired by more than 25,000 meteorological stations around the world, from ship- and buoy-based instruments measuring sea surface temperature, and Antarctic research stations. The data are analyzed using methods that account for the changing distribution of temperature stations and for urban heating effects that could skew the calculations. Additionally, independent analyses by the National Oceanic and Atmospheric Administration, Berkeley Earth, the Hadley Centre (part of the United Kingdom’s weather forecasting Met Office), and Copernicus Climate Services in Europe have concluded the global surface temperature for 2025 was the third warmest on record. These scientists use much of the same temperature data in their analyses but employ different methodologies and models, which exhibit the same ongoing warming trend. NASA’s full dataset of global surface temperatures, as well as details of how agency scientists conducted the analysis are available online. For more information about NASA’s Earth science programs, visit: [Hidden Content] -end- Liz Vlock Headquarters, Washington 202-358-1600 *****@*****.tld Peter Jacobs Goddard Space Flight Center, Greenbelt, Md. 301-286-3308 *****@*****.tld Share Details Last Updated Jan 14, 2026 EditorJessica TaveauLocationNASA Headquarters Related TermsEarth Science DivisionGoddard Institute for Space StudiesScience Mission Directorate View the full article
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Explore Hubble Hubble Home Overview About Hubble The History of Hubble Hubble Timeline Why Have a Telescope in Space? Hubble by the Numbers At the Museum FAQs Impact & Benefits Hubble’s Impact & Benefits Science Impacts Cultural Impact Technology Benefits Impact on Human Spaceflight Astro Community Impacts Science Hubble Science Science Themes Science Highlights Science Behind Discoveries Universe Uncovered Hubble’s Partners in Science Hubble & Citizen Science AI & Hubble Science Explore the Night Sky Observatory Hubble Observatory Hubble Design Mission Operations Science Operations Astronaut Missions to Hubble Hubble vs Webb Team Hubble Team Career Aspirations Hubble Astronauts Multimedia Images Videos Sonifications Podcasts e-Books Online Activities 3D Hubble Models Lithographs Fact Sheets Posters Hubble on the NASA App Glossary News Hubble News Social Media Media Resources More 35th Anniversary Online Activities 3 min read Hubble Observes Stars Flaring to Life in Orion Protostar HOPS 181 is buried in layers of dusty gas clouds, but its energy shapes the material that surrounds it. NASA, ESA, and T. Megeath (University of Toledo); Processing: Gladys Kober (NASA/Catholic University of America) A protostar wrapped in obscuring dust creates a cavity with glowing walls while its jet streams into space. NASA, ESA, and T. Megeath (University of Toledo); Processing: Gladys Kober (NASA/Catholic University of America) A curving cavity in a cloud of gas has been hollowed out by a protostar in this Hubble image. NASA, ESA, and T. Megeath (University of Toledo); Processing: Gladys Kober (NASA/Catholic University of America) Just-forming stars, called protostars, dazzle a cloudy landscape in the Orion Molecular Cloud complex (OMC). These three new images from NASA’s Hubble Space Telescope were taken as part of an effort to learn more about the envelopes of gas and dust surrounding the protostars, as well as the outflow cavities where stellar winds and jets from the developing stars have carved away at the surrounding gas and dust. Scientists used these Hubble observations as part of a broader survey to study protostellar envelopes, or the gas and dust around the developing star. Researchers found no evidence that the outflow cavities were growing as the protostar moved through the later stages of star formation. They also found that the decreasing accretion of mass onto the protostars over time and the low rate of star formation in the cool, molecular clouds cannot be explained by the progressive clearing out of the envelopes. The OMC lies within the “sword” of the constellation Orion, roughly 1,300 light-years away. Protostar HOPS 181 is buried in layers of dusty gas clouds, but its energy shapes the material that surrounds it. NASA, ESA, and T. Megeath (University of Toledo); Processing: Gladys Kober (NASA/Catholic University of America) This Hubble image shows a small group of young stars amidst molecular clouds of gas and dust. Near the center of the image, concealed behind the dusty clouds, lies the protostar HOPS 181. The long, curved arc in the top left of the image is shaped by the outflow of material coming from the protostar, likely from the jets of particles shot out at high speeds from the protostar’s magnetic poles. The light of nearby stars reflects off and is scattered by dust grains that fill the image, giving the region its soft glow. Download this image (5.7 MB) A protostar wrapped in obscuring dust creates a cavity with glowing walls while its jet streams into space. NASA, ESA, and T. Megeath (University of Toledo); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (6 MB) The bright star in the lower right quadrant called CVSO 188 might seem like the diva in this image, but HOPS 310, located just to the left of center behind the dust, is the true hidden star. This protostar is responsible for the large cavity with bright walls that has been carved into the surrounding cloud of gas and dust by its jets and stellar winds. Running diagonally to the top right is one of the bipolar jets of the protostar. These jets consist of particles launched at high speeds from the protostar’s magnetic poles. Some background galaxies are visible in the upper right of the image. A curving cavity in a cloud of gas has been hollowed out by a protostar in this Hubble image. NASA, ESA, and T. Megeath (University of Toledo); Processing: Gladys Kober (NASA/Catholic University of America) Download this image (5.7 MB) The bright protostar to the left in this Hubble image is located within the Orion Molecular Clouds. Its stellar winds — ejected, fast-flowing particles that are spurred by the star’s magnetic field — have carved a large cavity in the surrounding cloud. In the top right, background stars speckle the image. New images added every day between January 12-17, 2026! Follow @NASAHubble on social media for the latest Hubble images and news and see Hubble’s Stellar Construction Zones for more images of young stellar objects. Facebook logo @NASAHubble @NASAHubble Instagram logo @NASAHubble Explore More Exploring the Birth of Stars Hubble’s Nebulae Media Contact: Claire Andreoli NASA’s Goddard Space Flight Center, Greenbelt, MD *****@*****.tld Share Details Last Updated Jan 14, 2026 Location NASA Goddard Space Flight Center Related Terms Hubble Space Telescope Astrophysics Astrophysics Division Goddard Space Flight Center Protostars Stars The Universe Keep Exploring Discover More Topics From Hubble Hubble Space Telescope Since its 1990 launch, the Hubble Space Telescope has changed our fundamental understanding of the universe. Hubble’s Stellar Construction Zones Explore the Night Sky Hubble News View the full article
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Earth Observatory Earth Earth Observatory Image of the Day EO Explorer Topics All Topics Atmosphere Land Heat & Radiation Life on Earth Human Dimensions Natural Events Oceans Remote Sensing Technology Snow & Ice Water More Content Collections Global Maps World of Change Articles Notes from the Field Blog Earth Matters Blog Blue Marble: Next Generation EO Kids Mission: Biomes About About Us Subscribe 🛜 RSS Contact Us Search The Operational Land Imager (OLI) on Landsat 8 captured this image of a fire burning in the Magadan Oblast district of Siberia on April 8, 2019. NASA Earth Observatory image by Joshua Stevens, using Landsat data from the U.S. Geological Survey. The number of wildland fires burning in the Arctic is on the rise, according to NASA researchers. Moreover, these blazes are burning larger, hotter, and longer than they did in previous decades. These trends are closely tied to the region’s rapidly changing climate. The Arctic is warming nearly four times faster than the global average, a shift that directly impacts rain and snow in the region and decreases soil moisture, both of which make the landscape more flammable. Lightning, the primary ignition source of Arctic fires, is also occurring farther north. These findings are detailed in a report published in 2025 by the Arctic Monitoring and Assessment Programme (AMAP), a working group of the Arctic Council. “Fire has always been a part of boreal and Arctic landscapes, but now it’s starting to act in more extreme ways that mimic what we’ve seen in the temperate and the tropical areas,” said Jessica McCarty, Deputy Earth Science Division Chief at NASA’s Ames Research Center and an Arctic fire specialist. McCarty, the report’s lead author, worked as part of an international team for AMAP. But it’s not just the number of fires that concerns scientists; it’s how hot they burn. “It’s the intensity that worries us the most because it has the most profound impact on how ecosystems are changing,” said Tatiana Loboda, chair of the Department of Geographical Sciences at the University of Maryland. 2002-2012 2012-2024 NASA Earth Observatory NASA Earth Observatory 2002-20122012-2024 NASA Earth Observatory NASA Earth Observatory 2002-2012 2012-2024 CurtainToggle2-Up Image Details These maps show the number of fires detected by NASA’s MODIS instrument on the Terra and Aqua satellites from 2002 to 2012 (yellow) and 2012 to 2025 (orange), highlighting an increase in fire activity and a poleward shift over time. NASA Earth Observatory maps by Michala Garrison using data from NASA’s Fire Information for Resource Management System (FIRMS). Arctic ecosystems: How are there fires in the Arctic? The word ‘Arctic’ often conjures images of glaciers, snow, and a frozen ocean. So how can such a place catch fire? Officially, the Arctic refers to the region north of 66.5 degrees north, though many Arctic researchers study 60 degrees north and above. While much of the area is covered in snow and ice, the Arctic also boasts a diverse range of ecosystems that change as they extend toward the pole. It begins with boreal forests, which are primarily made up of coniferous trees like spruce, fir, and pine. As these forests thin to the north, they give way to shrublands, then to grassland tundra, and eventually to rock, ice, and polar bears. Illustration by Esther Suh, NASA’s Ames Research Center. Much of the vegetation is covered in snow during the winter, which thaws in the spring. Exposed, the vegetation dries out in the sunlight. When given an ignition source like a lightning strike, it can quickly become fuel for a fire. What is changing? According to the 2025 AMAP report, an increasingly flammable landscape combined with more lightning strikes is leading to larger, more frequent, and more intense fires than the landscape is adapted for. “There is variability year to year, but across the decades we are averaging about double the burned area in the North American Arctic compared to the mid-20th century,” said Brendan Rogers, senior scientist at the Woodwell Climate Research Center. Low-intensity fires, which the Arctic is accustomed to, leave most of the forest standing, which allows the understory and upper soil layers to recover quickly. In contrast, intense fires kill off trees and can trigger a process known as secondary succession, in which new species replace those that died. These fires also burn deep into the carbon-rich soil, change the area’s hydrology, and accelerate snowmelt. In addition, the smoke and habitat damage from massive, hot fires pose significant health risks to human communities and local wildlife. The Operational Land Imager (OLI) on Landsat 8 captured this image of a large wildfire in western Greenland on August 3, 2017. Satellites first detected evidence of the fire on July 31, 2017. NASA Earth Observatory image by Jesse Allen using Landsat data from the U.S. Geological Survey. The mid-2010s ushered in a novel fire regime. For instance, Greenland saw significant wildfires in 2015, 2017, and in 2019. Researchers also began observing fires consistently springing up in the Arctic as early as late March, much earlier in the year than historical records show, and burning well after the first snow. “It’s concerning how frequently these fires burn the same place,” Loboda said. “A lot of areas now burn two, three, or even five times during a very short *******. It’s an immense impact: It’s happening across the tundra and the boreal regions, and these areas can’t recover.” In summer 2016, Tatiana Loboda (right) rafted through the North American Arctic to collect samples across tundra sites. The work, part of NASA’s Arctic-Boreal Vulnerability Experiment (ABoVE), investigates how repeat fires impact the ecosystem over short and long timescales. Photo by ***** Chen (left), University of Maryland. Peat, permafrost, and zombie fires What makes Arctic ecosystems, and by extension Arctic fire, unique compared to much of the world is what is happening below ground: specifically in the peat and permafrost. Peat is old—thousands and thousands of years old. When glaciers retreated at the end of the last ice age, they left behind deposits of old trees, grasses, and other organic matter that have partially decomposed to form carbon-rich soil. Over time, layers of deposits built up into peat, which is now a primary ingredient in soil across the Arctic. When intense fires burn into deep peat deposits, they can create a phenomenon called a holdover fire, more commonly known as a zombie fire, in which remnants of fire stay alive throughout the winter. These fires appear extinguished on the surface but continue to smolder underground through the winter, bursting back to life when spring brings drier conditions. Thawing permafrost reshapes the surface across ecosystems. Top: Thawing permafrost in a boreal forest causes the surface to cave in, tilting and toppling trees into a “drunken forest.” Bottom: Thawing permafrost in the tundra creates scalloped pond edges, as pockets of ice melt and water moves through the soil to pool on the surface. Photos by Clayton Elder, NASA’s Ames Research Center. Permafrost—ground that remains frozen year-round—can be even older. Some permafrost predates the human species, ***** sapiens, remaining continuously frozen for more than 400,000 years. This age is what makes these frozen layers so significant: They’ve been storing ancient organic matter, and the carbon within it, for millennia. When organisms die and decompose, that process naturally releases carbon dioxide and methane. In the Arctic, permafrost keeps these organisms literally frozen, which effectively freezes them in time. NASA scientist and permafrost expert Clayton Elder describes seeing this effect in the Permafrost Tunnel in Fairbanks, Alaska. “You can walk into the tunnel and see grass embedded in the wall,” Elder said. “It’s still green, but when you carbon date it, it’s 40,000 years old.” But as the Arctic warms, thaws, and burns, the carbon stored in peat and permafrost releases into the atmosphere. That matters, because what’s locked below the surface is enormous. Together, Arctic peat and permafrost store twice as much carbon as the entirety of Earth’s atmosphere. According to McCarty, this thawing will lead to global change. “This is old ice— ice that is part of our hydrologic system and formed a homeostasis of climate that we as a species grew up in,” McCarty said. “There will be changes that we can’t predict: humanity has not experienced the climate the planet is heading towards. It will be interesting to model; there are so many different ways it could go.” What’s next? To address the challenges of the Arctic, scientists are finding new applications of existing data and developing new technologies. “NASA satellites form the real backbone of what we understand,” said Rogers. “These satellites have given us a 25-year record of wildfire data, which is invaluable. They are critical for our understanding of how these fire regimes are changing and for thinking through anything in the solution space.” New satellites and artificial intelligence developments are advancing understanding of ignition sources, fuel availability and flammability, and fire behavior. All of these data are important for monitoring fires and modeling future fire behavior, as well as evaluating the vulnerability of boreal and Arctic ecosystems to increasing levels of fire. “One of our conclusions is that the observations need to be more targeted,” McCarty said. “We know some of what is happening, but we need to better understand why, and how to monitor these isolated areas. This means we’ll need satellites and field campaigns that are thinking about this more complex fire landscape. What happens in the Arctic will impact the rest of the planet.” Story by Milan Loiacono, NASA’s Ames Research Center. References & Resources Arctic Monitoring and Assessment Programme (2025, June) AMAP Arctic Climate Change Update 2024: Key Trends and Impacts. Accessed January 14, 2026. NASA (2026) Fire Information for Resource Management System. Accessed January 14, 2026. NASA Earth Observatory (2026, January) Fires on the Rise in the Far North. Accessed January 14, 2026. Downloads View All 2002-2012 JPEG (1.25 MB) 2012-2024 JPEG (1.41 MB) 2026 JPEG (196.35 KB) August 3, 2017 JPEG (7.76 MB) 2016 JPEG (279.53 KB) April 8, 2019 JPEG (8.85 MB) Share Details Last Updated Jan 13, 2026 Related Terms Earth Observatory Ice & Glaciers Wildfires You might also be interested in Fires on the Rise in the Far North 3 min read Satellite-based maps show northern wildland fires becoming more frequent and widespread as temperatures rise and lightning reaches higher latitudes. Article Fire on Ice: The Arctic’s Changing Fire Regime 7 min read An increasingly flammable landscape combined with more lightning strikes is leading to larger, more frequent, and more intense fires than… Article A Plume of Bright Blue in Melissa’s Wake 5 min read The category 5 hurricane stirred up carbonate sediment near Jamaica in what scientists believe is the largest such event in… Article 1 2 3 … 5405 Next Keep Exploring Discover More From NASA Earth Science Subscribe to Earth Observatory Newsletters Subscribe to the Earth Observatory and get the Earth in your inbox. Earth Observatory Image of the Day NASA’s Earth Observatory brings you the Earth, every day, with in-depth stories and stunning imagery. Explore Earth Science Earth Science at Work NASA Earth Science helps Americans respond to challenges and societal needs — such as wildland fires, hurricanes, and water supplies… View the full article
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Earth Observatory Science Earth Observatory Fires on the Rise in the Far… Earth Earth Observatory Image of the Day EO Explorer Topics All Topics Atmosphere Land Heat & Radiation Life on Earth Human Dimensions Natural Events Oceans Remote Sensing Technology Snow & Ice Water More Content Collections Global Maps World of Change Articles Notes from the Field Blog Earth Matters Blog Blue Marble: Next Generation EO Kids Mission: Biomes About About Us Subscribe 🛜 RSS Contact Us Search 2002-2012 2012-2024 NASA Earth Observatory NASA Earth Observatory 2002-20122012-2024 NASA Earth Observatory NASA Earth Observatory 2002-2012 2012-2024 2002-2012 and 2012-2024 CurtainToggle2-Up Image Details Downloads 2002-2012 JPEG (1 MB) 2012-2024 JPEG (1 MB) In the far north, wildfires are breaking old patterns. Satellite data show that wildland fires once scattered across the Arctic are now surging in numbers—particularly in northern Eurasia—and many are burning more intensely than before. These maps show the number of fires detected by the MODIS (Moderate Resolution Imaging Spectroradiometer) sensors on NASA’s Aqua and Terra satellites. The map on the left shows fire detections from 2002 to 2012 (yellow), while the map on the right shows detections from 2012 to 2024 (orange). The largest circles indicate areas with 15,000 or more detected fires, while the smallest circles represent areas with 1,000 or fewer. Fire detection data are from NASA’s Fire Information for Resource Management System (FIRMS). Although the geographical distribution of high-latitude wildfires varies from year to year, the maps reveal some clear long-term patterns. In the 2000s, fires north of 60 degrees latitude appeared across both North America and Eurasia, but starting in the early 2010s, their numbers skyrocketed, most dramatically in Eurasia. Even the icy island of Greenland entered a new fire regime during this *******, experiencing more large fires, though still too few to be visible on these maps. Researchers attribute these trends to rising temperatures, which have made northern landscapes more flammable, along with a poleward expansion of lightning—the primary ignition source for these fires. The findings are detailed in a report published in 2025 by the Arctic Monitoring and Assessment Programme (AMAP), a working group of the Arctic Council. The number of fire detections and their distribution, however, is just one metric of the Arctic’s changing fire regime. According to NASA researchers, fires in this region are also burning larger, hotter, and longer than they did in previous decades. “Fire has always been a part of the boreal and the Arctic landscape,” said Jessica McCarty, Deputy Earth Science Division Chief at NASA’s Ames Research Center and lead author of the report. “But now it’s starting to act in more extreme ways that mimic what we’ve seen in the temperate and the tropical areas.” NASA Earth Observatory maps by Michala Garrison, using the MODIS Collection 6.1 Active Fire Product from NASA’s Fire Information for Resource Management System (FIRMS). Story by Milan Loiacono. References & Resources Arctic Monitoring and Assessment Programme (2025, June) AMAP Arctic Climate Change Update 2024: Key Trends and Impacts. Accessed January 14, 2026. NASA (2026) Fire Information for Resource Management System. Accessed January 14, 2026. NASA Earth Observatory (2026, January) Fire on Ice: The Arctic’s Changing Fire Regime. Accessed January 14, 2026. Downloads 2002-2012 JPEG (1.25 MB) 2012-2024 JPEG (1.41 MB) You may also be interested in: Stay up-to-date with the latest content from NASA as we explore the universe and discover more about our home planet. Sprawling Gifford Fire Scorches California 3 min read The fast-growing blaze charred more than 100,000 acres in the span of a week. Article Seeing the Monroe Canyon Fire in a New Light 5 min read As wildland fires raged in the American West, NASA airborne technology was there to image it in incredible detail. Article Monroe Canyon Fire Intensifies 3 min read The blaze in central Utah experienced rapid growth during dry, windy days in late July 2025, creating hazy skies throughout… Article 1 2 3 4 Next Keep Exploring Discover More from NASA Earth Science Subscribe to Earth Observatory Newsletters Subscribe to the Earth Observatory and get the Earth in your inbox. Earth Observatory Image of the Day NASA’s Earth Observatory brings you the Earth, every day, with in-depth stories and stunning imagery. Explore Earth Science Earth Science Data View the full article
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Los cuatro miembros de la tripulación SpaceX Crew-11 se juntaron para una foto de grupo **** sus trajes presurizados Dragon durante una comprobación de dichos trajes en el módulo laboratorio Kibo de la Estación Espacial Internacional. En el sentido de las agujas del reloj, desde la parte inferior izquierda, aparecen el astronauta de la NASA Mike Fincke, el cosmonauta de Roscosmos Oleg Platonov, la astronauta de la NASA Zena Cardman y el astronauta de la JAXA (Agencia Japonesa de Exploración Aeroespacial) Kimiya Yui. Credit: NASA Read this press release in English here. La NASA y SpaceX prevén que, si las condiciones meteorológicas lo permiten, el desacoplamiento de la misión SpaceX Crew 11 de la agencia espacial estadounidense de la Estación Espacial Internacional se produzca no antes de las 5:05 p.m. EST (hora del este) del miércoles 14 de enero. El 8 de enero, la NASA anunció su decisión de traer de vuelta a la Tierra antes de lo previsto a los integrantes de la misión SpaceX Crew 11 de la agencia desde la estación espacial, mientras los equipos técnicos siguen de cerca un problema médico que afecta a un miembro de la tripulación que actualmente vive y trabaja a bordo del laboratorio orbital. Debido a la confidencialidad médica, no es apropiado que la NASA comparta más detalles sobre el miembro de la tripulación, quien se encuentra estable. Está planeado que los astronautas de la NASA Zena Cardman y Mike Fincke, el astronauta de JAXA (Agencia Japonesa de Exploración Aeroespacial) Kimiya Yui y el cosmonauta de Roscosmos Oleg Platonov americen frente a la costa de California a las 3:41 a.m. del jueves 15 de enero. Los responsables de la misión continúan supervisando las condiciones en la zona de recuperación, ya que el desacoplamiento de la nave Dragon de SpaceX depende de las condiciones operativas de la nave espacial, la preparación del equipo de recuperación, las condiciones meteorológicas, el estado del mar y otros factores. La NASA y SpaceX seleccionarán una hora y un lugar concretos para el amerizaje cuando se acerque la fecha del desacoplamiento de la nave espacial de Crew 11. La cobertura en directo (en inglés) de la NASA del regreso y las actividades relacionadas se retransmitirá en NASA+, Amazon Prime, y el canal de YouTube de la agencia. Aprenda cómo transmitir contenido de la NASA a través de diversas plataformas en línea, incluidas las redes sociales. La cobertura de la NASA es la siguiente (todas las horas son del este y están sujetas a cambios en función de las operaciones en tiempo real): Miércoles, 14 de enero 3 p.m. – Comienza la cobertura del cierre de escotilla en NASA+, Amazon Prime, y YouTube. 3:30 p.m. – Cierre de escotilla 4:45 p.m. – Comienza la cobertura del desacoplamiento en NASA+, Amazon Prime, y YouTube. 5:05 p.m. – Desacoplamiento Tras la finalización de la cobertura del desacoplamiento, la NASA distribuirá las conversaciones (solo en formato audio) entre la tripulación Crew 11, la estación espacial y los controladores de vuelo durante el tránsito de la nave Dragon alejándose del complejo orbital. Jueves, 15 de enero 2:15 a.m. – Comienza la cobertura del regreso en NASA+, Amazon Prime, y YouTube. 2:51 a.m. – Encendido de desorbitado 3:41 a.m. – Amerizaje 5:45 a.m. – El administrador de la NASA, Jared Isaacman, liderará una rueda de prensa sobre el regreso a la Tierra que se transmitirá en directo a través de NASA+, Amazon Prime, y el canal de YouTube de la agencia. Para participar virtualmente en la conferencia de prensa, los medios de comunicación deben ponerse en contacto **** la sala de prensa del Centro Espacial Johnson de la NASA para obtener los detalles de la llamada antes de las 5 p.m. CST (hora del centro) del 14 de enero, enviando un correo electrónico a *****@*****.tld o llamando al +1 281-483-5111. Para hacer preguntas, los medios de comunicación deben llamar al menos 10 minutos antes del inicio de la conferencia. La política de acreditación de medios de comunicación de la agencia está disponible en línea (en inglés). Encuentre la cobertura completa de la misión, el blog de tripulaciones comerciales de la NASA y más información sobre la misión Crew 11 (todo en inglés) en: [Hidden Content] -fin- Joshua Finch / Jimi Russell / María José Viñas Sede central, Washington +1 202-358-1100 *****@*****.tld / *****@*****.tld / *****@*****.tld Sandra Jones / Joseph Zakrzewski Centro Espacial Johnson, Houston +1 281-483-5111 sandra.p*****@*****.tld / *****@*****.tld Steve Siceloff Centro Espacial Kennedy, Fla. +1 321-867-2468 steven.p*****@*****.tld Share Details Last Updated Jan 13, 2026 EditorJennifer M. DoorenLocationNASA Headquarters Related TermsCommercial CrewInternational Space Station (ISS)ISS ResearchNASA en español View the full article
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Four SpaceX Crew-11 members gather together for a crew portrait wearing their Dragon pressure suits during a suit verification check inside the International Space Station’s Kibo laboratory module. Clockwise from bottom left are, NASA astronaut Mike Fincke, Roscosmos cosmonaut Oleg Platonov, NASA astronaut Zena Cardman, and JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui.Credit: NASA NASA and SpaceX are targeting no earlier than 5:05 p.m. EST, Wednesday, Jan. 14, for the undocking of the agency’s SpaceX Crew-11 mission from the International Space Station, pending weather conditions. On Jan. 8, NASA announced its decision to return the agency’s SpaceX Crew-11 mission to Earth from the space station earlier than originally planned as teams monitor a medical concern with a crew member currently living and working aboard the orbital laboratory, who is stable. Due to medical privacy, it is not appropriate for NASA to share more details about the crew member. NASA astronauts Zena Cardman and Mike Fincke, JAXA (Japan Aerospace Exploration Agency) astronaut Kimiya Yui, and Roscosmos cosmonaut Oleg Platonov are targeted to splash down off the coast of California at 3:41 a.m. on Thursday, Jan. 15. Mission managers continue monitoring conditions in the recovery area, as undocking of the SpaceX Dragon depends on spacecraft readiness, recovery team readiness, weather, sea states, and other factors. NASA and SpaceX will select a specific splashdown time and location closer to the Crew-11 spacecraft undocking. NASA’s live coverage of return and related activities will stream on NASA+, Amazon Prime, and the agency’s YouTube channel. Learn how to stream NASA content through a variety of online platforms, including social media. NASA’s coverage is as follows (all times Eastern and subject to changed based on real-time operations): Wednesday, Jan. 14 3 p.m. – Hatch closure coverage begins on NASA+, Amazon Prime, and YouTube. 3:30 p.m. – Hatch closing 4:45 p.m. – Undocking coverage begins on NASA+, Amazon Prime, and YouTube. 5:05 p.m. – Undocking Following the conclusion of undocking coverage, NASA will distribute audio-only communications between Crew-11, the space station, and flight controllers during Dragon’s transit away from the orbital complex. Thursday, Jan. 15 2:15 a.m. – Return coverage begins on NASA+, Amazon Prime, and YouTube. 2:51 a.m. – Deorbit burn 3:41 a.m. – Splashdown 5:45 a.m. – NASA Administrator Jared Isaacman will lead a Return to Earth news conference streaming live on NASA+, Amazon Prime, and the agency’s YouTube channel. To participate virtually in the news conference, media must contact the NASA Johnson newsroom for call details by 5 p.m. CST, Jan. 14, at: *****@*****.tld or 281-483-5111. To ask questions, media must dial in no later than 10 minutes before the start of the call. The agency’s media credentialing policy is available online. Find full mission coverage, NASA’s commercial crew blog, and more information about the Crew-11 mission at: [Hidden Content] -end- Joshua Finch / Jimi Russell Headquarters, Washington 202-358-1100 *****@*****.tld / *****@*****.tld Sandra Jones / Joseph Zakrzewski Johnson Space Center, Houston 281-483-5111 sandra.p*****@*****.tld / *****@*****.tld Steve Siceloff Kennedy Space Center, Fla. 321-867-2468 steven.p*****@*****.tld Share Details Last Updated Jan 13, 2026 EditorJennifer M. DoorenLocationNASA Headquarters Related TermsInternational Space Station (ISS)Commercial CrewISS Research View the full article