Russian MS-33 Cargo Spacecraft: Soyuz Rocket Launch | International Space Station

Russian MS-33 Cargo Spacecraft: Soyuz Rocket Launch | International Space Station

The unpiloted Roscosmos Progress 94 cargo spacecraft is safely in orbit and headed to the International Space Station following its launch at 7:59 a.m. EDT (4:59 p.m. Baikonur time), March 22, 2026, on a Soyuz rocket from the Baikonur Cosmodrome in Kazakhstan. Aboard Progress 94 is about three tons of cargo—including food, fuel, 52kg of scientific equipment, and 12kg of medical supplies for the orbiting laboratory.  

Following launch, one of the Progress spacecraft’s two KURS automated rendezvous antennas did not deploy as planned. All other systems are operating as designed, and Progress will continue toward its planned docking at 9:34 a.m. Tuesday, March 24, to the space-facing port of the station’s Poisk module. Roscosmos will continue troubleshooting the antenna issue. If the antenna cannot be deployed, Roscosmos cosmonaut and station commander, Sergey Kud-Sverchkov, will manually pilot the spacecraft for rendezvous and docking using the Telerobotically Operated Rendezvous System (TORU). It is a control panel located in the Zvezda Service Module that can be used as a backup to the KURS automated system. 

The State Corporation for Space Activities "Roscosmos", commonly known as Roscosmos, is a state corporation of the Russian Federation responsible for space flights, cosmonautics programs, and aerospace research.

Follow Expedition 74:

https://blogs.nasa.gov/spacestation/

Expedition 74 Crew
Station Commander: Sergey-Kud Sverchkov (Russia)
Roscosmos (Russia) Flight Engineers: Andrey Fedyaev, Sergei Mikaev

European Space Agency Flight Engineer: Sophie Adenot

NASA Flight Engineers: Jessica Meir, Jack Hathaway, Chris Williams

An international partnership of space agencies provides and operates the elements of the International Space Station (ISS). The principals are the space agencies of the United States, Russia, Europe, Japan, and Canada.

Video Credit: Roscosmos

Duration: 9 minute, 24 seconds
Date: March 22, 2026

#NASA #Space #Science #Planets #Earth #ISS #Progress94 #ProgressCargoSpacecraft #SoyuzRocketLaunch #Kazakhstan #Қазақстан #Astronauts #UnitedStates #ESA #France #Europe #Cosmonauts #Russia #Roscosmos #HumanSpaceflight #SpaceLaboratory #InternationalCooperation #Expedition74 #STEM #Education #HD #Video

NASA Artemis II Moon Rocket Rollout to Launch Pad 39B | Kennedy Space Center

NASA Artemis II Moon Rocket Rollout to Launch Pad 39B | Kennedy Space Center

NASA’s Artemis II Space Launch System (SLS) rocket and Orion spacecraft, secured to the mobile launcher, are seen as they journey to and after arrival at Launch Pad 39B on Friday, March 20, 2026, at NASA’s Kennedy Space Center in Florida. 

NASA’s Artemis II flight test will take Commander Reid Wiseman, Pilot Victor Glover, and Mission Specialist Christina Koch from NASA, and Mission Specialist Jeremy Hansen from the Canadian Space Agency (CSA), around the Moon and back to Earth with launch opportunities beginning in April 2026. 

Check the NASA Artemis II Mission page for updates:

https://www.nasa.gov/mission/artemis-ii/

Artemis blog:

https://blogs.nasa.gov/artemis/

This was a multi-hour trek from the Vehicle Assembly Building (VAB) to Launch Pad 39B. The four-mile journey on the crawler-transporter-2, at a careful speed of roughly 1 mile per hour, can take up to 12 hours. The massive crawler keeps the mobile launcher and rocket perfectly level throughout the trip, even on the gentle slopes of the crawlerway. At the pad, the stack will be secured and ground support systems will be connected in preparation for flight.

The crawler-transporters, formally known as the Missile Crawler Transporter Facilities, are a pair of tracked vehicles used to transport launch vehicles from NASA's Vehicle Assembly Building (VAB) along the Crawlerway to Launch Complex 39. They were originally used to transport the Saturn IB and Saturn V rockets during the Apollo, Skylab and Apollo–Soyuz programs. They were then used to transport Space Shuttles from 1981 to 2011. The crawler-transporters carry vehicles on the mobile launcher platforms (MLPs) used by NASA, and after each launch return to the pad to take the platform back to the VAB.

The two crawler-transporters were designed and built by Marion Power Shovel Company using some components designed and built by Rockwell International at a cost of US$14 million (US$128.5 million in 2022) each. Upon its construction, the crawler-transporter became the largest self-powered land vehicle in the world. 

Image Credits: United Launch Alliance (ULA), NASA/Brandon Hancock
Date: March 20, 2026

#NASA #Space #Science #Earth #Moon #ArtemisProgram #ArtemisII #OrionSpacecraft #SLS #SLSRocket #CrawlerTransporter2 #CrewedMissions #Astronauts #DeepSpace #MoonToMars #Engineering #SpaceTechnology #HumanSpaceflight #SolarSystem #SpaceExploration #NASAKennedy #KSC #VAB #MerrittIsland #Florida #ULA #UnitedStates #STEM #Education

Galaxy UGC 12591 in Pegasus: A Remarkable Galactic Hybrid | Hubble

Galaxy UGC 12591 in Pegasus: A Remarkable Galactic Hybrid | Hubble

This NASA/European Space Agency Hubble Space Telescope image showcases the remarkable galaxy UGC 12591. Classified as an S0/Sa galaxy, UGC 12591 sits somewhere between a lenticular and a spiral. It lies just under 400 million light-years away from us in the westernmost region of the Pisces–Perseus Supercluster, a long chain of galaxy clusters that stretches out for hundreds of light-years—one of the largest known structures in the cosmos.

The galaxy itself is also extraordinary: it is incredibly massive. The galaxy and its halo together contain several hundred billion times the mass of the Sun; four times the mass of the Milky Way. It also whirls round extremely quickly, rotating at speeds of up to 1.8 million kilometers per hour!

Observations with Hubble are helping astronomers to understand the mass of UGC 1259, and to determine whether the galaxy simply formed and grew slowly over time, or whether it might have grown unusually massive by colliding and merging with another large galaxy in its past.

Image Credit: ESA/Hubble & NASA
Release Date: Feb. 27, 2017

#NASA #ESA #Astronomy #Space #Science #Galaxies #HybridGalaxies #S0SaGalaxies #LenticularGalaxies #SpiralGalaxies #InteractingGalaxies #UGC12591 #PegasusConstellation #Cosmos #Universe #HubbleSpaceTelescope #HST #Europe #GSFC #STScI #UnitedStates #STEM #Education

Planet Mars Images: March 19-21, 2026 | NASA's Curiosity & Perseverance Rovers

Planet Mars Images: March 19-21, 2026 | NASA's Curiosity & Perseverance Rovers

Mars 2020 - sol 1806

MSL - sol 4841

MSL - sol 4840

MSL - sol 4841

MSL - sol 4840

MSL - sol 4842

MSL - sol 4842

MSL - sol 4841

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Friends of NASA (FoN) is an independent non-governmental organization (NGO) dedicated to building international support for peaceful space exploration, commerce, scientific discovery, and STEM education. 

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Celebrating 13+ Years on Mars (2012-2025)

Mission Name: Mars Science Laboratory (MSL)

Rover Name: Curiosity

Main Job: To determine if Mars was ever habitable to microbial life. 

Launch: Nov. 6, 2011

Landing Date: Aug. 5, 2012, Gale Crater, Mars

Celebrating 5+ Years on Mars

Mission Name: Mars 2020

Rover Name: Perseverance

Main Job: Seek signs of ancient life and collect samples of rock and regolith (broken rock and soil) for return to Earth.

Launch: July 30, 2020    

Landing: Feb. 18, 2021, Jezero Crater, Mars

For more information on NASA's Mars missions, visit: mars.nasa.gov

Image Credits: NASA/JPL-Caltech/ASU/MSSS

Processing: Kevin M. Gill

Image Release Dates: March 19-21, 2026

#NASA #Space #Astronomy #Science #Planets #Mars #Astrobiology #Geology #CuriosityRover #MSL #MountSharp #GaleCrater #PerseveranceRover #Mars2020 #JezeroCrater #Robotics #SpaceTechnology #SpaceEngineering #MSSS #JPL #Caltech #UnitedStates #CitizenScience #KevinGill #STEM #Education

NASA Artemis II Moon Rocket: Launchpad Bound | Kennedy Space Center

NASA Artemis II Moon Rocket: Launchpad Bound | Kennedy Space Center

NASA’s Artemis II Space Launch System (SLS) rocket and Orion spacecraft, secured to the mobile launcher, are seen as they leave the Vehicle Assembly Building (VAB) on Friday, March 20, 2026, at NASA’s Kennedy Space Center in Florida. 

NASA’s Artemis II flight test will take Commander Reid Wiseman, Pilot Victor Glover, and Mission Specialist Christina Koch from NASA, and Mission Specialist Jeremy Hansen from the Canadian Space Agency (CSA), around the Moon and back to Earth with launch opportunities beginning in April 2026. 

Check the NASA Artemis II Mission page for updates:

https://www.nasa.gov/mission/artemis-ii/

Artemis blog:

https://blogs.nasa.gov/artemis/

This was a multi-hour trek from the Vehicle Assembly Building (VAB) to Launch Pad 39B. The four-mile journey on the crawler-transporter-2, at a careful speed of roughly 1 mile per hour, can take up to 12 hours. The massive crawler keeps the mobile launcher and rocket perfectly level throughout the trip, even on the gentle slopes of the crawlerway. At the pad, the stack will be secured and ground support systems will be connected in preparation for flight.

The crawler-transporters, formally known as the Missile Crawler Transporter Facilities, are a pair of tracked vehicles used to transport launch vehicles from NASA's Vehicle Assembly Building (VAB) along the Crawlerway to Launch Complex 39. They were originally used to transport the Saturn IB and Saturn V rockets during the Apollo, Skylab and Apollo–Soyuz programs. They were then used to transport Space Shuttles from 1981 to 2011. The crawler-transporters carry vehicles on the mobile launcher platforms (MLPs) used by NASA, and after each launch return to the pad to take the platform back to the VAB.

The two crawler-transporters were designed and built by Marion Power Shovel Company using some components designed and built by Rockwell International at a cost of US$14 million (US$128.5 million in 2022) each. Upon its construction, the crawler-transporter became the largest self-powered land vehicle in the world. 

Image Credit: United Launch Alliance (ULA)
Dates: March 20, 2026

#NASA #Space #Science #Earth #Moon #ArtemisProgram #ArtemisII #OrionSpacecraft #SLS #SLSRocket #CrawlerTransporter2 #CrewedMissions #Astronauts #DeepSpace #MoonToMars #Engineering #SpaceTechnology #HumanSpaceflight #SolarSystem #SpaceExploration #NASAKennedy #KSC #VAB #MerrittIsland #Florida #ULA #UnitedStates #STEM #Education

NASA Artemis II Moon Rocket: VAB Departure | Kennedy Space Center

NASA Artemis II Moon Rocket: VAB Departure | Kennedy Space Center

NASA’s Artemis II Space Launch System (SLS) rocket and Orion spacecraft, secured to the mobile launcher, are seen as they leave the Vehicle Assembly Building (VAB) between Thursday and Friday, March 19-20, 2026, at NASA’s Kennedy Space Center in Florida. 

NASA’s Artemis II flight test will take Commander Reid Wiseman, Pilot Victor Glover, and Mission Specialist Christina Koch from NASA, and Mission Specialist Jeremy Hansen from the Canadian Space Agency (CSA), around the Moon and back to Earth with launch opportunities beginning in April 2026. 

Check the NASA Artemis II Mission page for updates:

https://www.nasa.gov/mission/artemis-ii/

Artemis blog:

https://blogs.nasa.gov/artemis/

This was a multi-hour trek from the Vehicle Assembly Building (VAB) to Launch Pad 39B. The four-mile journey on the crawler-transporter-2, at a careful speed of roughly 1 mile per hour, can take up to 12 hours. The massive crawler keeps the mobile launcher and rocket perfectly level throughout the trip, even on the gentle slopes of the crawlerway. At the pad, the stack will be secured and ground support systems will be connected in preparation for flight.

The crawler-transporters, formally known as the Missile Crawler Transporter Facilities, are a pair of tracked vehicles used to transport launch vehicles from NASA's Vehicle Assembly Building (VAB) along the Crawlerway to Launch Complex 39. They were originally used to transport the Saturn IB and Saturn V rockets during the Apollo, Skylab and Apollo–Soyuz programs. They were then used to transport Space Shuttles from 1981 to 2011. The crawler-transporters carry vehicles on the mobile launcher platforms (MLPs) used by NASA, and after each launch return to the pad to take the platform back to the VAB.

The two crawler-transporters were designed and built by Marion Power Shovel Company using some components designed and built by Rockwell International at a cost of US$14 million (US$128.5 million in 2022) each. Upon its construction, the crawler-transporter became the largest self-powered land vehicle in the world. 

Image Credit: United Launch Alliance (ULA)
Dates: March 19-20, 2026

#NASA #Space #Science #Earth #Moon #ArtemisProgram #ArtemisII #OrionSpacecraft #SLS #SLSRocket #CrawlerTransporter2 #CrewedMissions #Astronauts #DeepSpace #MoonToMars #Engineering #SpaceTechnology #HumanSpaceflight #SolarSystem #SpaceExploration #NASAKennedy #KSC #VAB #MerrittIsland #Florida #ULA #UnitedStates #STEM #Education

The Valentine Rose Nebula—Sh2-174 in Cepheus: Wide-field view

The Valentine Rose Nebula—Sh2-174 in Cepheus: Wide-field view

Sh2-174 is an unusual ancient planetary nebula. A planetary nebula is created when a low-mass star blows off its outer layers at the end of its life. The core of the star remains and is called a white dwarf. Usually the white dwarf can be found very near the center of the planetary nebula. However, in the case of Sh2-174 it is off to the right. This asymmetry is due to the planetary nebula's interaction with the interstellar medium that surrounds it. 

Distance from Earth:  ~1,000 light-years

Credit: Alessandro Cipolat Bares

Image Details: Askar500 and ZWO ASI2600MC, ANTLIA ALP-T 3nm, 48x600"

Capture Location: Aosta Valley, Western Alps, Italy
Image Date: Feb. 27, 2026
Release Date: March 9, 2026

#NASA #Astronomy #Space #Science #Stars #WhiteDwarfStars #Nebulae #PlanetaryNebulae #Sh2174 #ValentineRoseNebula #CepheusConstellation #Cosmos #Universe #Astrophotography #AlessandroCipolatBares #Astrophotographer #Europe #STEM #Education

Close-up: The Valentine Rose Nebula—Sh2-174 in Cepheus | Mayall Telescope

Close-up: The Valentine Rose Nebula—Sh2-174 in Cepheus | Mayall Telescope

This image was obtained with the wide-field view of the Mosaic camera on the Mayall 4-meter telescope at Kitt Peak National Observatory in Arizona. Sh2-174 is an unusual ancient planetary nebula. A planetary nebula is created when a low-mass star blows off its outer layers at the end of its life. The core of the star remains and is called a white dwarf. Usually the white dwarf can be found very near the center of the planetary nebula. However, in the case of Sh2-174 it is off to the right. (It is the very blue star near the center of the blue gas). This asymmetry is due to the planetary nebula's interaction with the interstellar medium that surrounds it. 

The image was generated with observations in the B (blue), I (orange), Hydrogen-alpha (red) and Oxygen [OIII] (blue) filters. In this image, North is up, East is to the left.

Learn more about the Mayall Telescope: 
https://noirlab.edu/science/programs/kpno/telescopes/nicholas-mayall-4m-telescope

Credit: T.A. Rector (University of Alaska Anchorage) and H. Schweiker (WIYN and NOIRLab/NSF/AURA)
Release Date: Feb. 12, 2013

#NASA #Astronomy #Space #Science #Stars #WhiteDwarfStars #Nebulae #PlanetaryNebulae #Sh2174 #ValentineRoseNebula #CepheusConstellation #Cosmos #Universe #MayallTelescope #KPNO #Arizona #NSF #AURA #UnitedStates #STEM #Education

Simulation: NASA Artemis Space Launch System Moon Rocket Exhaust Plumes

Simulation: NASA Artemis Space Launch System Moon Rocket Exhaust Plumes

🚀NASA is using advanced simulations to provide the best possible launch conditions for the Artemis II test flight around the Moon. Learn how this NASA-developed tool is helping us better understand the Space Launch System's flight environment . . .

This simulation of the Artemis I launch shows how the Space Launch System rocket's exhaust plumes interact with air, water, and the launchpad. Colors on surfaces indicate pressure levels—red for high pressure and blue for low pressure. The teal contours illustrate where water is present.

Airflow around rockets as they travel from Earth into space can have a dramatic impact on a mission. This is why NASA used advanced simulations to provide the best possible launch conditions for the Artemis II test flight around the Moon. 

To better understand the Artemis Space Launch System (SLS) rocket’s flight environment, engineers turned to a NASA-developed tool called the Launch, Ascent, and Vehicle Aerodynamics (LAVA) framework. The software addresses computational fluid dynamics, the flow behavior of gases and liquids. 

Using data from the 2022 Artemis I launch, researchers at NASA’s Ames Research Center in California’s Silicon Valley used LAVA to simulate complex interactions between the rocket plume and a system that pumps water to suppress sound during launch. The system protects the rocket and other equipment from potentially damaging sound waves. 

Comparing simulations with and without the sound suppression system activated revealed that the water effectively reduces pressure waves from sound, but exhaust gases from the rocket could also redirect water, causing significant pressure increases in certain areas of the launchpad. 

The LAVA simulations improved NASA’s understanding of the plume interaction with the Artemis mobile launcher platform. Using this knowledge, aerospace engineers at NASA’s Kennedy Space Center in Florida refined the design plume pressures and adapted the launch platform to endure those pressures for Artemis II, NASA’s first mission with crew aboard the SLS and Orion spacecraft. 

NASA will release LAVA in the coming weeks to the aerospace community and accelerate innovation by enabling U.S. companies and researchers to run complex simulations and optimize designs for aircraft and rockets. NASA has hosted a seminar on using LAVA with more about the tool’s capabilities. 

The work on LAVA is supported through NASA’s Transformational Tools and Technologies project. It develops new computational capabilities to help predict aerospace vehicle performance. The project is part of NASA’s Transformative Aeronautics Concepts Program under the Aeronautics Research Mission Directorate (ARMD).  

NASA’s decades of aeronautics research expertise strengthens its space missions, using tools like wind tunnel testing, advanced software development, and other innovations to enhance safety and reliability.

Video Credit: NASA/Chris DeGrendele, Timothy Sandstrom
Text Credit: Diana Fitzgerald
Duration: 15 seconds
Release Date: March 20, 2026

#NASA #Space #Science #Moon #ArtemisProgram #ArtemisII #SLS #SLSRocket #RocketEnginePlumes #PressureWaveSimulations #RocketLaunchConditions #LAVAFramework #Astronauts #HumanSpaceflight #Engineering #SpaceTechnology #SolarSystem #SpaceExploration #NASAMarshall #MSFC #NASAAmes #NASAKennedy #ARMD #UnitedStates #STEM #Education #HD #Video

Water Rockets & Beyond for Young Students: A Chinese Teacher in Jiangxi Province

Water Rockets & Beyond for Young Students: A Chinese Teacher in Jiangxi Province

"A Chinese teacher spent five years developing nine-types of water rockets to let his students' dreams fly high. Who knows? A future rocket designer might be right among them!"

A water rocket is a type of model rocket using water as its reaction mass. The water is forced out by a pressurized gas, typically compressed air. Like all rocket engines, it operates on the principle of Newton's third law of motion. Water rocket hobbyists typically use one or more plastic soft drink bottles as the rocket's pressure vessel. A variety of designs are possible including multi-stage rockets. Water rockets are also custom-built from composite materials to achieve world record altitudes.

Jiangxi is an inland province in east China. Spanning from the banks of the Yangtze river in the north into hillier areas in the south and east, it borders Anhui to the north, Zhejiang to the northeast, Fujian to the east, Guangdong to the south, Hunan to the west, and Hubei to the northwest.

Video Credit: Xinhua Sci-Tech
Duration: 35 seconds
Release Date: March 21, 2026

#NASA #Space #Science #Astronomy #Technology #Engineering #Rocketry #WaterRockets #Projectiles #Physics #Mechanics #Students #Teachers #Jian #Jiangxi #江西 #China #中国 #STEM #Education #HD #Video

The Cat's Eye Galaxy: Messier 94 with Starburst Ring in Canes Venatici

The Cat's Eye Galaxy: Messier 94 with Starburst Ring in Canes Venatici

This image shows the galaxy Messier 94. It lies in the small northern constellation of the Hunting Dogs (Canes Venatici), about 16 million light-years away.

Within the bright ring around Messier 94 new stars are forming at a high rate and many young, bright stars are present within it—thanks to this feature called a starburst ring.

The cause of this peculiarly shaped star-forming region is likely a pressure wave going outwards from the galactic center, compressing the gas and dust in the outer region. The compression of material means the gas starts to collapse into denser clouds. Inside these dense clouds, gravity pulls the gas and dust together until temperature and pressure are high enough for stars to be born.

Messier 94 (also known as the Crocodile Eye Galaxy, or Croc's Eye Galaxy) was discovered by Pierre Méchain in 1781, and cataloged by Charles Messier.

Image Credit: Alessandro Cipolat Bares
Image Details: ARTEC 200E and ZWO AI2600MC, 80x300"
Capture Location: Aosta Valley, Western Alps, Italy
Image Date: March 13, 2026
Release Date: March 14, 2026

#NASA #Astronomy #Space #Science #Galaxies #Messier94 #M94 #SpiralGalaxies #StarburstGalaxies #StarburstRings #DoubleRingGalaxies #CanesVenaticiConstellation #Cosmos #Universe #Hubble #HST #SpaceTelescopes #ESA #Europe #STScI #GSFC #UnitedStates #STEM #Education

The Black Eye Galaxy: Messier 64 in Coma Berenices | Webb & Hubble

The Black Eye Galaxy: Messier 64 in Coma Berenices | Webb & Hubble

Easily identified by the spectacular band of dark dust that partially obscures its bright core, Messier 64, or the Black Eye Galaxy, is characterized by its bizarre internal motion. The gas in the outer regions of this spiral galaxy is rotating in the opposite direction from the gas and stars in its inner regions. This strange behavior may be the result of a merger between M64 and a satellite galaxy over a billion years ago.

Distance from Earth: 17 million light-years

New stars are forming in the region where the oppositely rotating gases collide, are compressed, and then contract. Particularly noticeable in this stunning Hubble image of the galaxy’s core are recently formed hot, blue stars and pink clouds of glowing hydrogen gas that fluoresce when exposed to ultraviolet light from the newly-formed stars.

English astronomer Edward Pigott first spotted M64 in March 1719, just 12 days before German astronomer Johann Elert Bode, and roughly a year before Charles Messier independently rediscovered it in March of 1780. The galaxy is located 17 million light-years from Earth in the constellation Coma Berenices. The best time of year to look for the Black Eye Galaxy is May. Its apparent magnitude of 9.8 requires a moderately sized telescope and dark sky site.

This image is a composite view from NASA’s Hubble Space Telescope and James Webb Space Telescope. It shows Messier 64 captured at near- and mid-infrared wavelengths by Webb, while Hubble’s image shows the galaxy in ultraviolet, visible, and near-infrared light. These observations were taken to learn more about star formation in nearby galaxies. 

Image Description: A massive spiral galaxy glows with a yellow core, surrounded by arms full of orange-brown dust and pink and blue patches of star formation. Framed by a haze of dark dust, the galaxy shines against black space dotted with a few stars.

Image Credit: NASA, CSA, ESA, F. Belfiore (European Southern Observatory – Germany), J. Lee (Space Telescope Science Institute), A. Leroy (The Ohio State University), and D. Thilker (The Johns Hopkins University)

Processing: Gladys Kober (NASA/Catholic University of America)
Release Date: March 20, 2026

#NASA #ESA #Astronomy #Space #Science #Galaxies #Messier64 #M64 #SpiralGalaxies  #InteractingGalaxies #ComaBerenicesConstellation #Cosmos #Universe #JWST #InfraredAstronomy #HubbleSpaceTelescope #HST #UltravioletAstronomy #SpaceTelescopes #CSA #Canada #Europe #GSFC #STScI #UnitedStates #STEM #Education

The Cat's Paw Nebula: NGC 6334 | Webb & Chandra Space Telescopes

The Cat's Paw Nebula: NGC 6334 | Webb & Chandra Space Telescopes

Part of a collection of images from NASA's Chandra X-ray Observatory and other telescopes features regions where stars are forming, areas often nicknamed “stellar nurseries.” X-rays are energetic enough that they can penetrate the gas and dust of these regions, giving insight to the young stars and other high-energy phenomena that are happening within, including the effects of X-rays on any planets or planet-forming disks orbiting the stars.

This image reveals a chaotic scene still in development—massive young stars are carving away at nearby gas and dust, while their bright starlight is producing a bright nebulous glow represented in blue. The disruptive young stars, with their relatively short lifespans and luminosity, will eventually quench the local star formation process.

The Cat’s Paw Nebula is located approximately 4,000 light-years away in the constellation Scorpius.

Image Description: The Cat’s Paw Nebula including X-rays from Chandra (pink) and infrared data from James Webb. A mottled patch of purple at the center reveals young, million-year-old stars tucked behind thick, overlapping rings of dark orange cosmic dust. The pockets of blue sky appearing through the clouds highlight the complex structure of this stellar nursery.

Credits: X-ray: NASA/SAO/CXC; Infrared: NASA/ESA/CSA/STScI

Image Processing: NASA/CXC/SAO/J. Major
Release Date: March 19, 2026

#NASA #Astronomy #Space #Science #NASAWebb #Nebulae #CatsPawNebula #NGC6334 #ScorpiusConstellation #Universe #NASAChandra #XrayAstronomy #JWST #InfraredAstronomy #NIRCam #UnfoldTheUniverse #ESA #Europe #CSA #Canada #GSFC #STScI #CXC #UnitedStates #STEM #Education

NASA Artemis II Moon Rocket Launchpad Arrival: Part II | Kennedy Space Center

NASA Artemis II Moon Rocket Launchpad Arrival: Part II | Kennedy Space Center

NASA’s Artemis II Space Launch System (SLS) rocket and Orion spacecraft, secured to the mobile launcher, are seen as they arrive at Launch Pad 39B, Friday, March 20, 2026, at NASA’s Kennedy Space Center in Florida. NASA’s Artemis II flight test will take Commander Reid Wiseman, Pilot Victor Glover, and Mission Specialist Christina Koch from NASA, and Mission Specialist Jeremy Hansen from the Canadian Space Agency (CSA), around the Moon and back to Earth with launch opportunities beginning in April 2026. 

Check the NASA Artemis II Mission page for updates:

https://www.nasa.gov/mission/artemis-ii/

Artemis blog:

https://blogs.nasa.gov/artemis/

This was a multi-hour trek from the Vehicle Assembly Building (VAB) to Launch Pad 39B. The four-mile journey on the crawler-transporter-2, at a careful speed of roughly 1 mile per hour, can take up to 12 hours. The massive crawler keeps the mobile launcher and rocket perfectly level throughout the trip, even on the gentle slopes of the crawlerway. At the pad, the stack will be secured and ground support systems will be connected in preparation for flight.

The crawler-transporters, formally known as the Missile Crawler Transporter Facilities, are a pair of tracked vehicles used to transport launch vehicles from NASA's Vehicle Assembly Building (VAB) along the Crawlerway to Launch Complex 39. They were originally used to transport the Saturn IB and Saturn V rockets during the Apollo, Skylab and Apollo–Soyuz programs. They were then used to transport Space Shuttles from 1981 to 2011. The crawler-transporters carry vehicles on the mobile launcher platforms (MLPs) used by NASA, and after each launch return to the pad to take the platform back to the VAB.

The two crawler-transporters were designed and built by Marion Power Shovel Company using some components designed and built by Rockwell International at a cost of US$14 million (US$128.5 million in 2022) each. Upon its construction, the crawler-transporter became the largest self-powered land vehicle in the world. 

Image Credit: NASA/Joel Kowsky
Date: March 20, 2026

#NASA #Space #Science #Earth #Moon #ArtemisProgram #ArtemisII #OrionSpacecraft #SLS #SLSRocket #CrawlerTransporter2 #CrewedMissions #Astronauts #DeepSpace #MoonToMars #Engineering #SpaceTechnology #HumanSpaceflight #SolarSystem #SpaceExploration #NASAKennedy #KSC #VAB #MerrittIsland #Florida #UnitedStates #STEM #Education

NASA Artemis II Moon Rocket Launchpad Journey: Part II | Kennedy Space Center

NASA Artemis II Moon Rocket Launchpad Journey: Part II | Kennedy Space Center

NASA’s Artemis II Space Launch System (SLS) rocket and Orion spacecraft, secured to the mobile launcher, are seen as they make the 4.2 mile journey toward Launch Pad 39B, Friday, March 20, 2026, at NASA’s Kennedy Space Center in Florida. NASA’s Artemis II flight test will take Commander Reid Wiseman, Pilot Victor Glover, and Mission Specialist Christina Koch from NASA, and Mission Specialist Jeremy Hansen from the Canadian Space Agency (CSA), around the Moon and back to Earth with launch opportunities beginning in April 2026. 

Check the NASA Artemis II Mission page for updates:

https://www.nasa.gov/mission/artemis-ii/

Artemis blog:

https://blogs.nasa.gov/artemis/

This is a multi-hour trek from the Vehicle Assembly Building (VAB) to Launch Pad 39B. The four-mile journey on the crawler-transporter-2, at a careful speed of roughly 1 mile per hour, will take up to 12 hours. The massive crawler keeps the mobile launcher and rocket perfectly level throughout the trip, even on the gentle slopes of the crawlerway. Once at the pad, the stack will be secured, ground support systems will be connected in preparation for flight.

The crawler-transporters, formally known as the Missile Crawler Transporter Facilities, are a pair of tracked vehicles used to transport launch vehicles from NASA's Vehicle Assembly Building (VAB) along the Crawlerway to Launch Complex 39. They were originally used to transport the Saturn IB and Saturn V rockets during the Apollo, Skylab and Apollo–Soyuz programs. They were then used to transport Space Shuttles from 1981 to 2011. The crawler-transporters carry vehicles on the mobile launcher platforms (MLPs) used by NASA, and after each launch return to the pad to take the platform back to the VAB.

The two crawler-transporters were designed and built by Marion Power Shovel Company using some components designed and built by Rockwell International at a cost of US$14 million (US$128.5 million in 2022) each. Upon its construction, the crawler-transporter became the largest self-powered land vehicle in the world. 

Image Credit: NASA/Joel Kowsky/Aubrey Gemignani
Image Date: March 20, 2026

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