Geminid Meteors: View from Wyoming
Image Date: Dec. 13, 2025
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Geminid Meteors: View from Wyoming
NOIRLab 2025 Holiday Video Card & Free 2026 Astronomy Calendar
The National Science Foundation's NOIRLab (formally named the National Optical-Infrared Astronomy Research Laboratory) is the United States national center for ground-based, nighttime optical astronomy.
Through its five Programs — NSF Cerro Tololo Inter-American Observatory (CTIO), the Community Science and Data Center (CSDC), the International Gemini Observatory, NSF Kitt Peak National Observatory (KPNO) and NSF–DOE Vera C. Rubin Observatory — NOIRLab serves as a focal point for community development of scientific programs, the exchange of ideas, and creative development. The lab’s infrastructure enables the astronomy community to advance humanity’s understanding of the Universe by exploring significant areas of astrophysics, including dark energy and dark matter, galaxies and quasars, the Milky Way, exoplanets, and small bodies in our own Solar System.
NOIRLab makes continual updates to each facility and provides new opportunities for staff while expanding scientific capabilities and improving the experience for users. By providing the latest facilities for its staff and the scientific community, the lab positively impacts ground-based nighttime astronomical science. In addition, the lab focuses on developing international collaborations and partnerships to advance ground-based optical and infrared facilities and capabilities.
In cooperation with the astronomical community, partner organizations, other US optical and infrared system operators, and NSF, NOIRLab develops and advances plans for NSF-funded optical and infrared facilities.
The astronomical community is honored to have the opportunity to conduct astronomical research on I’oligam Du’ag (Kitt Peak) in Arizona, on Maunakea in Hawai‘i, and on Cerro Tololo and Cerro Pachón in Chile. We recognize and acknowledge the very significant cultural role and reverence that these sites have to the Tohono O'odham Nation, to the Native Hawaiian community, and to the local communities in Chile, respectively.
The Association of Universities for Research in Astronomy, Inc. (AURA) operates these facilities and NSF NOIRLab under a cooperative agreement with the U.S. National Science Foundation (NSF).
Seasons Greetings 2025 from The European Southern Observatory
The third photograph captures the mesmerising colors of an evening sky. The sky's gradient fades from blue at the top to white, then orange and pink at the bottom. A mountain range is visible at the bottom of the image with all but one of the mountains already in darkness. The last illuminated one is on the right, with a metallic structure on top. In the middle of the mountain range, a triangular shadow can be seen. A silver full moon high in the sky on the left underlines the timelessness of the image.
This a view of the seemingly endless expanses of the Chilean Atacama Desert. The silver full Moon shines bright in the beautiful gradient evening sky. Below it, to the right, the giant dome of ESO’s Extremely Large Telescope (ELT) glows with the golden sunset light.
The ELT is perched atop Cerro Armazones at an altitude of 3046 meters (nearly 10,000 feet). The dome might look small in the image, but the full 30-minute walk via the set of stairs from the entrance of the dome to its top, indicates its gigantic size: 80 meters high and 93 meters wide. Weighing about 6,100 tonnes, the dome is designed to protect the telescope and its mirrors, including the 39-m wide primary mirror—the biggest eye on the sky.
To the left of Cerro Armazones the last sunbeams of the evening cast a dark triangular shadow: Cerro Paranal, home to ESO’s Very Large Telescope (VLT), from where this picture was taken by Luca Sbordone, ESO staff astronomer. It is no wonder that this site hosts so many professional telescopes, as it boasts the darkest skies on Earth. Chile is home to all of ESO’s observatories, thanks to a long-lasting partnership that goes back more than 60 years—may it be as timeless and inspiring as this view.
Further information on the ELT: https://elt.eso.org
#NASA #ESO #Astronomy #Space #Science #SeasonsGreetings2025 #AstronomicalObservatories #ExtremelyLargeTelescope #ELT #Construction #Nebulae #Stars #Exoplanets #Galaxies #Universe #BiggestEyeOnTheSky #Technology #Engineering #CerroArmazones #VLT #CerroParanal #AtacamaDesert #Chile #MPIA #Germany #Deutschland #Europe #STEM #Education
Sprites: View from Texas | Earth Science
Photographer Paul Smith: "Some of the closest and brightest red sprites I have ever captured. All the colors from the green ghosts in the upper portions to pinks and purples in the lower tendrils. The details are incredible to me, especially considering the massive size yet short duration."
Although sprites have been seen, off and on, for at least a century, most scientists did not believe they existed until after 1989 when sprites were photographed by cameras onboard NASA's space shuttle. Now "sprite chasers" routinely photograph sprites from their own backyards. Give it a try, but stay safe.
Red Sprites: These mysterious bursts of light in the upper atmosphere momentarily resemble gigantic jellyfish. One unusual feature of sprites is that they are relatively cold. They operate more like long fluorescent light tubes than hot compact light bulbs. In general, red sprites take only a fraction of a second to occur and are best seen when powerful thunderstorms are visible from the side.
Learn more here: https://uhu.epss.hu/en/tle-phenomena/
Texas is the most populous state in the South Central region of the United States. It borders Louisiana to the east, Arkansas to the northeast, Oklahoma to the north, New Mexico to the west, and an international border with the Mexican states of Chihuahua, Coahuila, Nuevo León, and Tamaulipas to the south and southwest.
#NASA #Science #Planets #Earth #Atmosphere #Thunderstorms #Lightning #Sprites #TLE #Photography #PaulSmith #Photographer #CitizenScience #WestTexas #Texas #UnitedStates #STEM #Education
Bright Aurora Borealis: View from Missouri
Astrophotographer Tyler Schlitt: " . . . This one single pillar took almost 30 mins to clear my frame. Then about two hours later the sky exploded with naked eye aurora. I was truly stunned on the show we had in the backyard as I was not expecting something of that magnitude to unfold."
On Earth, auroras are mainly created by particles originally emitted by the Sun in the form of solar wind. When this stream of electrically charged particles gets close to our planet, it interacts with the magnetic field that acts as a gigantic shield. While it protects Earth’s environment from solar wind particles, it can also trap a small fraction of them. Particles trapped within the magnetosphere—the region of space surrounding Earth in which charged particles are affected by its magnetic field—can be energized and then follow the magnetic field lines down to the magnetic poles. There, they interact with oxygen and nitrogen atoms in the upper layers of the atmosphere, creating the flickering, colorful lights visible in the polar regions here on Earth.
Views of The Himalayas and Mount Everest | International Space Station
#NASA #Space #ISS #Science #Planets #Earth #SouthAsia #Nepal #TheHimalayas #MountEverest #AstronautVideography #Astronauts #KimiyaYui #Japan #日本 #JAXA #宇宙航空研究開発機構 #UnitedStates #Cosmonauts #Russia #Россия #Roscosmos #Роскосмос #HumanSpaceflight #SpaceLaboratory #InternationalCooperation #Expedition74 #UnitedStates #STEM #Education #HD #Video
Meteor by Moonlight: View from Colorado
Astrophotographer Mike Lewinski: "Meteorific! I caught a meteor in my timelapse from Crestone, Colorado, USA, on December 8, 2025 at 1:14am MST. The waning gibbous moon nicely illuminates the foreground here."
The waning gibbous moon is the phase that occurs after a full moon, where the illuminated portion of the moon decreases from 100% to about 50%.
Colorado is a state in the Western United States. It is one of the Mountain states, and Southwestern region of the United States, sharing the Four Corners region with Arizona, New Mexico, and Utah. It is also bordered by Wyoming to the north, Nebraska to the northeast, Kansas to the east, and Oklahoma to the Southeast.
Painting Galaxy Clusters by Numbers & Physics: X-ray Arithmetic | NASA Chandra
A new technique gives astronomers—and the public—an alternative look at examples of the largest objects in the universe. Developed using NASA’s Chandra X-ray Observatory data, “X-arithmetic” classifies galaxy clusters and groups by their nature rather than appearance. The technique sorts features in galaxy clusters and groups into three types and then applies a color to each. This new collection shows the central regions of five galaxy clusters in the sample: MS 0735+7421, the Perseus Cluster, M87, Abell 2052, and Cygnus A.
Galaxy clusters are the most massive objects in the universe held together by gravity, containing up to several thousand individual galaxies and huge reservoirs of superheated, X-ray-emitting gas. The mass of this hot gas is typically about five times higher than the total mass of all the galaxies in galaxy clusters. In addition to these visible components, 80% of the mass of galaxy clusters is supplied by dark matter. These cosmic giants are bellwethers not only for the galaxies, stars and black holes within them, but also for the evolution and growth of the universe itself.
It is no surprise then that NASA’s Chandra X-ray Observatory has observed many galaxy clusters over the lifetime of the mission. Chandra’s X-ray vision allows it to see the enormous stockpiles of hot cluster gas, with temperatures as high as 100 million degrees in exquisite clarity. This blazing gas tells stories about past and present activity within galaxy clusters.
Many of these galaxy clusters host supermassive black holes at their centers that periodically erupt in powerful outbursts. These explosions generate jets that are visible in radio wavelengths, inflating into bubbles full of energetic particles. These bubbles carry energy out into the surrounding gas.
Chandra’s images have revealed a variety of other structures formed during these black hole outbursts, including hooks, rings, arcs, and wings. However, appearances alone do not tell us what these structures are or how they formed.
To tackle this problem, a team of astronomers developed a novel image-processing technique to analyze X-ray data, allowing them to identify features in the gas of galaxy clusters, classifying them by their nature rather than just their appearance. Prior to this technique, called “X-arithmetic,” scientists could only identify the nature of a portion of the features and in a much less efficient way, via studies of the amounts of X-ray energy dispersed at distinct wavelengths. The authors applied X-arithmetic to 15 galaxy clusters and galaxy groups (these are similar to galaxy clusters but with fewer member galaxies). By comparing the outcome from the X-arithmetic technique to computer simulations, researchers now have a new tool that will help in understanding the physical processes inside these important titans of the universe.
A new paper looks at how these structures appear in parts of the X-ray spectrum. By splitting Chandra data into lower-energy and higher-energy X-rays and comparing the strengths of each structure in both, researchers can classify them into three distinct types that they have colored differently. A pink color is given to sound waves and weak shock fronts that arise from pressure disturbances traveling at close to the speed of sound, compressing the hot gas into thin layers. The bubbles inflated by jets are colored yellow, and cooling or slower-moving gas is blue. The resulting images, “painted” to reflect the nature of each structure, offer a new way to interpret the complex aftermath of black hole activity using only X-ray imaging data. This method works on Chandra (and other X-ray) observations, and on simulations of galaxy clusters, providing a tool to combine data and theory.
The galaxy clusters in the study often have large regions of cooling or slow-moving gas near their centers, and only show evidence for shock fronts. The galaxy groups, on the other hand, are not like this. They show multiple shock fronts in their central regions and smaller amounts of cooling and slow-moving gas compared to the sample of galaxy clusters.
This contrast between galaxy clusters and galaxy groups suggests that black hole feedback—that is, the interdependent relationship between outbursts from a black hole and its environment—appears stronger in galaxy groups. This may be because feedback is more violent in the groups than in the clusters, or because a galaxy group has weaker gravity holding the structure together than a galaxy cluster. The same outburst from a black hole, with the same power level, can therefore more easily affect a galaxy group than a galaxy cluster.
There are still many open questions about these black hole outbursts. For example, scientists would like to know how much energy they put into the gas around them and how often they occur. These violent events play a key role in regulating the cooling of the hot gas and controlling the formation of stars in clusters. By revealing the physics underlying the structures they leave behind, the X-arithmetic technique brings us closer to understanding the influence of black holes on the largest scales.
A paper describing this new technique and its results has been published in The Astrophysical Journal and is led by Hannah McCall from the University of Chicago. The other authors are Irina Zhuravleva (University of Chicago), Eugene Churazov (Max Planck Institute for Astrophysics, Germany), Congyao Zhang (University of Chicago), Bill Forman and Christine Jones (Center for Astrophysics | Harvard & Smithsonian), and Yuan Li (University of Massachusetts at Amherst).
NASA's Marshall Space Flight Center in Huntsville, Alabama, manages the Chandra program. The Smithsonian Astrophysical Observatory's Chandra X-ray Center controls science operations from Cambridge, Massachusetts, and flight operations from Burlington, Massachusetts.
Painting Galaxy Clusters by Numbers & Physics | NASA Chandra X-ray Observatory
Galaxy clusters are the most massive objects in the universe held together by gravity, containing up to several thousand individual galaxies and huge reservoirs of superheated, X-ray-emitting gas. The mass of this hot gas is typically about five times higher than the total mass of all the galaxies in galaxy clusters. In addition to these visible components, 80% of the mass of galaxy clusters is supplied by dark matter. These cosmic giants are bellwethers not only for the galaxies, stars, and black holes within them, but also for the evolution and growth of the universe itself.
NASA’s Chandra X-ray Observatory has observed many galaxy clusters over the lifetime of the mission. Chandra’s X-ray vision allows it to see the enormous stockpiles of hot cluster gas with temperatures as high as 100 million degrees in exquisite clarity. This blazing gas tells stories about past and present activity within galaxy clusters.
NASA's Chandra X-ray Observatory is being canceled in NASA's Fiscal Year 2026 Budget Request, along with 18 other active science missions. NASA's science budget is being reduced by nearly 50%. NASA's total budget will become the lowest since 1961, after accounting for inflation.
Many of these galaxy clusters host supermassive black holes at their centers. These periodically erupt in powerful outbursts. The explosions generate jets that are visible in radio wavelengths, inflating into bubbles full of energetic particles. These bubbles carry energy out into the surrounding gas. Chandra’s images have revealed a wealth of other structures formed during these black hole outbursts, including hooks, rings, arcs, and wings. However, appearances alone do not tell us what these structures are or how they formed.
To tackle this problem, a team of astronomers developed a novel image-processing technique to analyze X-ray data, allowing them to identify features in the gas of galaxy clusters like never before, classifying them by their nature rather than just their appearance. Prior to this technique, called “X-arithmetic,” scientists could only identify the nature of a portion of the features and in a much less efficient way, via studies of the amounts of X-ray energy dispersed at distinct wavelengths. The authors applied X-arithmetic to 15 galaxy clusters and galaxy groups. Galaxy groups are similar to galaxy clusters but with fewer member galaxies.
By comparing the outcome from the X-arithmetic technique to computer simulations, researchers now have a new tool that will help in understanding the physical processes inside these important titans of the universe. The researchers were able to classify features in the galaxy clusters and groups into three distinct types that they have colored by splitting Chandra data into lower-energy and higher-energy X-rays and comparing the strengths of each structure. The physical features included bubbles, sound waves, and cooler or slower-moving gas.
There are still many open questions about these black hole outbursts. For example, scientists would like to know how much energy they put into the gas around them and how often they occur. These violent events play a key role in regulating the cooling of the hot gas and controlling the formation of stars in clusters. By revealing the physics underlying the structures they leave behind, the X-arithmetic technique brings us closer to understanding the influence of black holes on the largest scales.
Aurora: View from Wisconsin
Photographer Michele Sadauskas: "For some time, a green arc hung in the northern sky. Data seemed good for a decent show, but that green arc just wouldn't materialize into something more. I had just hopped into the truck to thaw out when pillars began to form. I hopped back out and in no time, a wall of intense reds climbed over my head, coloring the snow blood red. Magnificent! I also really enjoyed capturing the orange pillar in amongst the red. The October 2024 storm had awesome orange aurora, but up till tonight I haven't captured an orange pillar. Happy I did, it is my favorite color!"
On Earth, auroras are mainly created by particles originally emitted by the Sun in the form of solar wind. When this stream of electrically charged particles gets close to our planet, it interacts with the magnetic field that acts as a gigantic shield. While it protects Earth’s environment from solar wind particles, it can also trap a small fraction of them. Particles trapped within the magnetosphere—the region of space surrounding Earth where charged particles are affected by its magnetic field—can be energized and then follow the magnetic field lines down to the magnetic poles. There, they interact with oxygen and nitrogen atoms in the upper layers of the atmosphere, creating the flickering, colorful lights visible in the polar regions here on Earth.
Meet NASA's X-59 Test Pilot Nils Larson | Armstrong Flight Research Center
For more information about the X-59 and NASA's Quesst mission, visit www.nasa.gov/quesst
Video Credit: NASA's Armstrong Flight Research Center (AFRC)
Duration: 2 minutes
Release Date: Dec. 12, 2025
#NASA #Aerospace #SupersonicFlight #SupersonicAircraft #X59 #X59Pilot #NilsLarson #Sonicboom #QuietAviation #Aviation #QuesstMission #CommercialAviation #Science #Physics #Engineering #AerospaceResearch #AeronauticalResearch #FlightTests #LockheedMartin #NASAArmstrong #AFRC #Edwards #California #UnitedStates #STEM #Education #HD #Video
2026 Moon Phases - Southern Hemisphere | NASA Goddard
The phase and libration of the Moon for 2026, at hourly intervals as viewed from the Southern Hemisphere. Includes supplemental graphics that display the Moon's orbit, subsolar and sub-Earth points, and the Moon's distance from Earth at true scale. Craters near the terminator are labeled, as are Apollo landing sites, maria, and other albedo features in sunlight.
Greenish Glow of Interstellar Comet 3I/ATLAS | Gemini North Telescope
After emerging from behind the Sun, 3I/ATLAS reappeared in the sky close to Zaniah, a triple-star system located in the constellation Virgo. This image is composed of exposures taken through four filters—blue, green, orange, and red. As exposures are taken, the comet remains fixed in the center of the telescope’s field of view. However, the positions of the background stars change relative to the comet, causing them to appear as colorful streaks in the final image.
What remains unknown is how the comet will behave as it leaves the Sun's vicinity and cools down. Many comets have a delayed reaction in experiencing the Sun's heat due to the lag in time that it takes for heat to make its way through the interior of the comet. A delay can activate the evaporation of new chemicals or trigger a comet outburst. Gemini will continue to monitor the comet as it leaves the Solar System and detect changes in its gas composition and outburst behavior.
Learn more about the Gemini North Telescope:
https://noirlab.edu/public/programs/gemini-observatory/gemini-north/
Cooling the "largest astronomical instruments ever" | European Southern Observatory
The light gathered by European Southern Observatory's Extremely Large Telescope (ELT) will be captured by house-sized instruments that need to be cooled down to detect faint signals from the cosmos. How do we cool these huge systems to as low as -270 ºC? Our engineers are hard at work at it.
Learn more more about the European Southern Observatory’s ELT at: https://elt.eso.org/
2026 Moon Phases - Northern Hemisphere | NASA Goddard
The phase and libration of the Moon for 2026, at hourly intervals as viewed from the Northern Hemisphere. Includes supplemental graphics that display the Moon's orbit, subsolar and sub-Earth points, and the Moon's distance from Earth at true scale. Craters near the terminator are labeled, as are Apollo landing sites, maria, and other albedo features in sunlight.
Northern "Fox Fires" of Finnish Lapland
In a Finnish myth, when an arctic fox runs so fast that its bushy tail brushes the mountains, flaming sparks are cast into the heavens creating the northern lights. In fact the Finnish word "revontulet", a name for the aurora borealis or northern lights, can be translated as fire fox. So that evocative myth took on a special significance for the photographer of this northern night skyscape from Finnish Lapland near Kilpisjarvi Lake. The snowy scene is illuminated by moonlight. Saana, an iconic fell or mountain of Lapland, rises at the right in the background. However, as the beautiful northern lights danced overhead, the wild fire fox in the foreground enthusiastically ran around the photographer and his equipment, making it difficult to capture in this lucky single shot.
Lapland is the largest and northernmost region of Finland. Lapland borders the Finnish region of North Ostrobothnia in the south. It also borders the Gulf of Bothnia, Norrbotten County in Sweden, Finnmark County and Troms County in Norway, and Murmansk Oblast and the Republic of Karelia in Russia. The topography of Lapland varies from vast mires and forests in the south to fells in the north. The Arctic Circle crosses Lapland, so polar phenomena such as the midnight sun and polar night can be viewed in this region.
Finland, officially the Republic of Finland, is a Nordic country in Northern Europe. It borders Sweden to the northwest, Norway to the north, and Russia to the east, with the Gulf of Bothnia to the west and the Gulf of Finland to the south, opposite Estonia.