Planet Mars Images: Sept. 23-26, 2025 | NASA's Curiosity & Perseverance Rovers

Planet Mars Images: Sept. 23-26, 2025 | NASA's Curiosity & Perseverance Rovers

Mars 2020 - sol 1635

MSL - sol 4667

MSL - sol 4671

MSL - sol 4671

Mars 2020 - sol 1634

MSL - sol 4668

MSL - sol 4671

Mars 2020 - sol 1635

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Celebrating 13+ Years on Mars (2012-2024)

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 4+ 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: Sept. 23-26, 2025

#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

Shenzhou-20 Astronauts Complete Fourth Spacewalk | China Space Station

Shenzhou-20 Astronauts Complete Fourth Spacewalk | China Space Station

The Shenzhou-20 crew aboard China's orbiting space station completed their mission's fourth spacewalk early on September 26, 2025, according to the China Manned Space Agency (CMSA).

The astronaut trio—Chen Dong, Chen Zhongrui and Wang Jie—worked outside the space station for approximately six hours and accomplished all assigned tasks at 01:35 Beijing Time, assisted by the Tiangong space station's robotic arm and a ground control team.

Chen Zhongrui and Wang Jie, tasked with conducting the spacewalk operations, finished the installation of debris protection devices and the inspection and maintenance of external equipment, according to the CMSA.

This is the first time a spacewalk has been performed by two astronauts from China's third group of astronaut recruits.

Up to now, the Shenzhou-20 astronauts have completed four extravehicular activities, making it one of the Chinese crews that have carried out the most spacewalks aboard the orbiting space station.

The crew has stayed in orbit for more than 150 days, carrying out a large number of scientific experiments and technological tests.

The Shenzhou-20 astronauts entered the space station on April 25 for a mission expected to last around 6 months.

Shenzhou-20 Crew

Chen Dong (陈冬) - Commander - Third spaceflight

Chen Zhong Rui (陈中瑞) - Operator - First spaceflight

Wang Jie (王杰) - Flight Engineer - First spaceflight

Video Credit: CCTV
Duration: 1 minute, 21 seconds
Release Date: Sept. 26, 2025

#NASA #Space #Science #China #中国 #Shenzhou20Mission #神舟二十号 #Shenzhou20Crew #Taikonauts #ChenDong #ChenZhongrui #WangJie #Astronauts #ChinaSpaceStation #中国空间站 #TiangongSpaceStation #SpaceLaboratory #EVA #Spacewalk #CMSA #中国载人航天工程办公室 #LongDurationMissions #HumanSpaceflight #STEM #Education #Video

Equinox Auroras over Tromsø, Norway

Equinox Auroras over Tromsø, Norway

Photographer Markus Varik: " . . . nothing comes close to, what we witnessed yesterday. It was unfortunately super cloudy around Tromsø, but the weather forecast said, there should be openings here and there later on in the evening. In reality, there was more rain and clouds and there were periods, where we were just sitting under cold freezing rain for elongated periods of time. But when it mattered, the sky cleared up. The variety of different colors was just insane . . ."

The equinox marks the exact moment when the center of the Sun crosses the plane of a planet’s equator. 

The aurora borealis, also known as the northern lights, occurs in an upper layer of Earth’s atmosphere called the ionosphere, but they typically originate with activity on the Sun. Occasionally, during explosions called coronal mass ejections, the Sun releases charged particles that speed across the solar system.

Auroras are produced when the Earth's magnetosphere is sufficiently disturbed by the solar wind that the trajectories of charged particles in solar wind and magnetospheric plasma, mainly in the form of electrons and protons, precipitate them into the upper atmosphere (thermosphere/exosphere) due to Earth's magnetic field, where their energy is lost. The resulting ionization and excitation of atmospheric constituents emits light of varying color and complexity. [Wikipedia]

Solid Colored Aurora

Green is common at the upper latitudes, while red is rare. On the other hand, aurora viewed from lower latitudes tend to be red.

Element Emission Colors

Oxygen: The big player in the aurora is oxygen. Oxygen is responsible for the vivid green (wavelength of 557.7 nm) and also for a deep brownish-red (wavelength of 630.0 nm). Pure green and greenish-yellow aurorae result from the excitation of oxygen.

Nitrogen: Nitrogen emits blue (multiple wavelengths) and red light.

Other Gases: Other gases in the atmosphere become excited and emit light, although the wavelengths may be outside of the range of human vision or else too faint to see. Hydrogen and helium, for example, emit blue and purple. Although our eyes cannot see all of these colors, photographic film and digital cameras often record a broader range of hues.

Aurora Colors According to Altitude

Above 150 miles: red, oxygen

Up to 150 miles: green, oxygen

Above 60 miles: purple or violet, nitrogen

Up to 60 miles: blue, nitrogen

The Colors of the Aurora (National Park Service)

https://www.nps.gov/articles/-articles-aps-v8-i1-c9.htm

Image Credit: Markus Varik
Markus' website: 
https://www.facebook.com/greenlandertromso
Image Date: Sept. 22, 2025

#NASA #Space #Astronomy #Science #Planets #Earth #Aurora #AuroraBorealis #NorthernLights #SolarSystem #Sun #Photography #Photographer #MarkusVarik #Tromsø #Norway #Norge #GSFC #UnitedStates #STEM #Education

NASA's Orion Spacecraft: How the Launch Abort System for Crew Safety Works

NASA's Orion Spacecraft: How the Launch Abort System for Crew Safety Works

"On launch day, every element of Orion is poised for purpose. Among the most important is the Launch Abort System (LAS)—a slender tower mounted above the crew module, ready to provide astronauts with a swift and controlled escape, if the mission requires it. The LAS is always on watch, standing guard from the moment the crew boards Orion and the hatch is closed. Should it be called into action, it can respond in milliseconds—whether on the launch pad or during ascent—separating the spacecraft from its rocket, guiding it to a safe trajectory and clearing the way for a return to Earth."

Learn more about Orion's LAS: 
https://lockheedmartin.com/en-us/news/features/2025/how-orion-s-launch-abort-system-protects-astronauts.html

The upcoming Artemis II test flight will send NASA astronauts Reid Wiseman, Victor Glover, and Christina Koch, and Canadian Space Agency (CSA) astronaut Jeremy Hansen around the Moon and return them safely back home.

The Artemis II crew will be sent on a ten-day Moon journey no earlier than April 2026.

NASA's Artemis II Mission:

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

Video Credit: Lockheed Martin
Duration: 2 minutes, 26 seconds
Release Date: Sept. 25, 2025

#NASA #ESA #CSA #Space #Mars #Moon #ArtemisProgram #ArtemisIIMission #ArtemisII #OrionSpacecraft #DeepSpace #Astronauts #MoonToMars #Science #SpaceTechnology #SpaceExploration #SolarSystem #HumanSpaceflight #CommercialSpace #LockheedMartin #SafetySystems #CrewSafety #AstronautSafety #LaunchAbortSystem #LAS #UnitedStates #Canada #Europe #STEM #Education #HD #Video

Liftoff: Amazon Project Kuiper Satellites on Atlas V Rocket | United Launch Alliance

Liftoff: Amazon Project Kuiper Satellites on Atlas V Rocket | United Launch Alliance

A United Launch Alliance (ULA) Atlas V rocket lifts off from Space Launch Complex-41 at Cape Canaveral on Sept. 25, 2025 at 8:09 a.m. EDT carrying the Kuiper 3 mission for Amazon's Project Kuiper broadband satellite constellation. The ULA Atlas V 551 mission launched 27 operational broadband satellites, bringing the total number of Project Kuiper satellites launched by ULA to 81.

Project Kuiper is Amazon's low Earth orbit (LEO) satellite broadband network. Its mission is to provide fast, reliable Internet access to customers around the world, including those in unserved and underserved communities, using a constellation of more than 3,200 LEO satellites.

United Launch Alliance (ULA) update:
https://newsroom.ulalaunch.com/releases/united-launch-alliance-propels-amazons-project-kuiper-to-enhance-broadband-access-to-connect-the-world

Amazon's Project Kuiper:
https://www.aboutamazon.com/what-we-do/devices-services/project-kuiper

Credit: United Launch Alliance (ULA)

Duration: 19 seconds
Release Date: Sept. 25, 2025

#NASA #Space #Earth #Satellites #LEO #Amazon #ProjectKuiper #Kuiper3Mission #SatelliteConstellations #CommunicationsSatellites #BroadbandInternetServices #AtlasVRockets #ULA #CapeCanaveral #Florida #UnitedStates #CommercialSpace #STEM #Education #HD #Video

Atlas V Rocket Liftoff: Amazon Project Kuiper Satellites | United Launch Alliance

Atlas V Rocket Liftoff: Amazon Project Kuiper Satellites | United Launch Alliance

A United Launch Alliance (ULA) Atlas V rocket lifts off from Space Launch Complex-41 at Cape Canaveral on Sept. 25, 2025 at 8:09 a.m. EDT carrying the Kuiper 3 mission for Amazon's Project Kuiper broadband satellite constellation. The ULA Atlas V 551 mission launched 27 operational broadband satellites, bringing the total number of Project Kuiper satellites launched by ULA to 81.

Project Kuiper is Amazon's low Earth orbit (LEO) satellite broadband network. Its mission is to provide fast, reliable Internet access to customers around the world, including those in unserved and underserved communities, using a constellation of more than 3,200 LEO satellites.

United Launch Alliance (ULA) update:
https://newsroom.ulalaunch.com/releases/united-launch-alliance-propels-amazons-project-kuiper-to-enhance-broadband-access-to-connect-the-world

Amazon's Project Kuiper:
https://www.aboutamazon.com/what-we-do/devices-services/project-kuiper

Credit: United Launch Alliance (ULA)
Release Date: Sept. 25, 2025

#NASA #Space #Earth #Satellites #LEO #Amazon #ProjectKuiper #Kuiper3Mission #SatelliteConstellations #CommunicationsSatellites #BroadbandInternetServices #AtlasVRockets #ULA #CapeCanaveral #Florida #UnitedStates #CommercialSpace #STEM #Education

Behind The Scenes: IMAP, SWFO-L1 & Carruthers Missions Pre-launch | NASA

Behind The Scenes: IMAP, SWFO-L1 & Carruthers Missions Pre-launch | NASA

A SpaceX Falcon 9 rocket with the National Oceanic and Atmospheric Administration's SWFO-L1 spacecraft and NASA’s IMAP and Carruthers Geocorona Observatory stands vertical at Launch Complex 39A during early morning on Monday, Sept. 22, 2025, at the agency’s Kennedy Space Center in Florida.

A SpaceX Falcon 9 rocket, with NASA’s IMAP and Carruthers Geocorona Observatory, as well as the National Oceanic and Atmospheric Administration's SWFO-L1 spacecraft attached, rolls to Launch Pad 39A on September 21, 2025, at NASA’s Kennedy Space Center in Florida.

A SpaceX Falcon 9 rocket, with NASA’s IMAP and Carruthers Geocorona Observatory, as well as the National Oceanic and Atmospheric Administration's SWFO-L1 spacecraft attached, rolls to Launch Pad 39A on Sunday, Sept. 21, 2025, at NASA’s Kennedy Space Center in Florida. 

The National Oceanic and Atmospheric Administration's SWFO-L1, along with NASA's Interstellar Mapping and Acceleration Probe (IMAP) and Carruthers Geocorona Observatory fully integrated for launch.

Technicians integrate NASA’s Carruthers Geocorona Observatory and the National Oceanic and Atmospheric Administration’s (NOAA) Space Weather Follow On Lagrange - 1 (SWFO-L1) satellite to the Evolved Expendable Launch Vehicle Secondary Payload Adapter Array Ring (ESPA) inside the Astrotech Space Operations Facility near NASA’s Kennedy Space Center in Florida on Friday, Sept. 5, 2025.

Technicians integrate NASA’s Carruthers Geocorona Observatory and the National Oceanic and Atmospheric Administration’s (NOAA) Space Weather Follow On Lagrange - 1 (SWFO-L1) satellite to the Evolved Expendable Launch Vehicle Secondary Payload Adapter Array Ring (ESPA) inside the Astrotech Space Operations Facility near NASA’s Kennedy Space Center in Florida on Friday, Sept. 5, 2025.

The integration of the rideshares prepares for the next milestone of attaching NASA’s IMAP (Interstellar Mapping and Acceleration Probe) Sun mapping observatory to a payload adapter and stacking all three observatories together to prepare them for encapsulation in the payload fairing.

The National Oceanic and Atmospheric Administration's SWFO-L1 Observatory successfully positioned above a work stand during pre-launch processing at the Astrotech Space Operations Facility near NASA’s Kennedy Space Center in Florida.

Technicians use a crane to lift the National Oceanic and Atmospheric Administration’s (NOAA) Space Weather Follow On–Lagrange 1 (SWFO-L1) Observatory above a work stand for integrations on Friday, July 25, 2025, during prelaunch processing at the Astrotech Space Operations Facility near NASA’s Kennedy Space Center in Florida.

A SpaceX Falcon 9 rocket successfully launched and deployed NASA’s Interstellar Mapping and Acceleration Probe (IMAP), the agency’s Carruthers Geocorona Observatory, and the National Oceanic and Atmospheric Administration’s (NOAA) Space Weather Follow On–Lagrange 1 (SWFO-L1) spacecraft. Launch took place on schedule at 7:30 a.m. EDT, Wednesday, Sept. 24, 2025, from Launch Complex 39A at NASA's Kennedy Space Center in Florida. 

The missions will each focus on different effects of the solar wind—the continuous stream of particles emitted by the Sun—and space weather—the changing conditions in space driven by the Sun—from their origins at the Sun to their farthest reaches billions of miles away at the edge of our solar system. 

The Interstellar Mapping and Acceleration Probe (IMAP) will explore and map the heliosphere—the invisible cosmic shield surrounding our solar system—to answer great unknowns about how particles accelerate in the solar wind.

Learn more about IMAP: 
https://science.nasa.gov/mission/imap/ 
https://imap.princeton.edu/

NASA’s Carruthers Geocorona Observatory is a small satellite that will observe Earth’s outermost atmospheric layer, the exosphere. It will image the faint glow of ultraviolet light from this region, called the geocorona, to better understand how space weather impacts our planet. The Carruthers mission continues the legacy of the Apollo era, expanding on measurements first taken during Apollo 16.

The SWFO-L1 spacecraft will monitor space weather and detect solar storms in advance, serving as an early warning beacon for potentially disruptive space weather, helping safeguard Earth’s critical infrastructure and technological-dependent industries. The SWFO-L1 spacecraft is the first NOAA observatory designed specifically for and fully dedicated to continuous, operational space weather observations.

Credit: SpaceX/NOAA/BAE Space & Mission Systems

Dates: Sept. 21-24, 2025

#NASA #NOAA #Space #Astronomy #Science #IMAPMission #IMAP #Stars #InterstellarMedium #ISM #Sun #Heliophysics #Heliosphere #Planets #Earth #SolarSystem #SolarPlasma #SolarWind #SpaceWeather #PrincetonU #SWFOL1 #CarruthersGeocoronaObservatory #GSFC #SpaceX #Falcon9Rocket #KSC #Florida #UnitedStates #STEM #Education

Planet Earth Aerosols: Inside the Visualization | NASA Goddard

Planet Earth Aerosols: Inside the Visualization | NASA Goddard

NASA uses satellites, ground measurements, and powerful computer models to track tiny particles floating in our air called aerosols. These small particles can travel thousands of miles, affecting the air we breathe and how far we can see, even far from where they originated. This visualization shows how these particles moved through Earth's atmosphere between August 1 and September 14, 2024.

Each color represents a type of aerosol: sea salt (blue), dust (pink/magenta), smoke from fires (orange/red), and sulfates from pollution and volcanoes (green). This visualization is based on NASA's Goddard Earth Observing System (GEOS) model. It provides realistic, high-resolution weather and aerosol data that enables customized environmental prediction and advances in artifical intelligence (AI) research.

Credit: NASA's Goddard Space Flight Center
Emme Watkins (eMITS): Lead Producer
Kathleen Greer (GSFC AMA): Lead Producer
Lesley Ott (HQ): Lead Scientist
Joseph V. Ardizzone (NASA/GSFC): Visualizer
Helen-Nicole Kostis (USRA): Visualizer
Duration: 3 minutes
Release Date: Sept. 25, 2025

#NASA #Space #Satellites #Science #Planets #Earth #Atmosphere #AirQuality #Aerosols #WildfireSmoke #Dust #Volcanoes #AirPollution #ClimateModels #ClimateChange #GlobalHeating #Climate #Environment #EarthObservation #RemoteSensing #GEOS #ArtificialIntelligence #AI #GSFC #UnitedStates #STEM #Education #Visualization #HD #Video

China Smart Dragon-3 Commercial Satellite Rocket Launch (Ship-based)

China Smart Dragon-3 Commercial Satellite Rocket Launch (Ship-based)

Lifting off at 07:56 UTC September 24, 2025, a Smart Dragon 3 (Jielong-3) rocket launched 11 GeeSat Geely-06 constellation satellites, plus another cubesat from the sea near Rizhao in east China's Shandong province. This was the eighth successful flight, further proving the Smart Dragon's capability to deliver 1,560 kg to a 500 km Sun-synchronous orbit. Smart Dragon-3 has a length of approximately 31 meters with a weight of 140 tons at liftoff.

The Jielong-3 rocket was developed by the China Academy of Launch Vehicle Technology (CALT), a subsidiary of the China Aerospace Science and Technology Corporation (CASC), the country’s state-owned main space contractor. The four-stage rocket is operated by China Rocket Co. Ltd., a commercial spinoff from CASC. 

The Geely-06 constellation, operated by Geely Holding Group, is a significant advancement in China's commercial satellite network. The constellation's first phase deployment includes 64 satellites, providing real-time global surface communications and supporting an extensive user base. The constellation is designed to serve 20 million users worldwide, handling up to 340 million messages per day. It supports high-frequency users and medium- to low-frequency users, transmitting 1,900-byte packets for text, voice, and images. The first phase is set to expand to 72 satellites, boosting capacity and service reliability. 

Geely is also piloting satellite-Internet of Things (IoT) technologies for smart vehicles, marine fisheries, heavy machinery, and logistics. The constellation's service frequency features strong diffraction characteristics to better ensure communication availability and reliability "above international standards".

Image Credit: CGTN

Date: Sept. 24, 2025

#NASA #Space #Satellites #Earth #China #中国 #SmartDragon3Rocket #Jielong3Rocket #捷龙三号运载火箭 #SolidFueledRocket #SeaLaunch #RocketLaunch #CALT #CASC #GeeSats #Geely06Constellation #Spaceflight #SpaceTechnology #CommercialSpace #TSLC #Rizhao #Shandong #STEM #Education

SpaceX Falcon 9 Launch: IMAP, SWFO-L1, & Carruthers Missions | NASA Kennedy

SpaceX Falcon 9 Launch: IMAP, SWFO-L1, & Carruthers Missions | NASA Kennedy

A SpaceX Falcon 9 rocket successfully launched and deployed NASA’s Interstellar Mapping and Acceleration Probe (IMAP), the agency’s Carruthers Geocorona Observatory, and the National Oceanic and Atmospheric Administration’s (NOAA) Space Weather Follow On–Lagrange 1 (SWFO-L1) spacecraft. Launch took place on schedule at 7:30 a.m. EDT, Wednesday, Sept. 24, 2025, from Launch Complex 39A at NASA's Kennedy Space Center in Florida. 

The missions will each focus on different effects of the solar wind—the continuous stream of particles emitted by the Sun—and space weather—the changing conditions in space driven by the Sun—from their origins at the Sun to their farthest reaches billions of miles away at the edge of our solar system. 

The Interstellar Mapping and Acceleration Probe (IMAP) will explore and map the heliosphere—the invisible cosmic shield surrounding our solar system—to answer great unknowns about how particles accelerate in the solar wind.

Learn more about IMAP: 
https://science.nasa.gov/mission/imap/ 
https://imap.princeton.edu/

NASA’s Carruthers Geocorona Observatory is a small satellite that will observe Earth’s outermost atmospheric layer, the exosphere. It will image the faint glow of ultraviolet light from this region, called the geocorona, to better understand how space weather impacts our planet. The Carruthers mission continues the legacy of the Apollo era, expanding on measurements first taken during Apollo 16.

The SWFO-L1 spacecraft will monitor space weather and detect solar storms in advance, serving as an early warning beacon for potentially disruptive space weather, helping safeguard Earth’s critical infrastructure and technological-dependent industries. The SWFO-L1 spacecraft is the first NOAA observatory designed specifically for and fully dedicated to continuous, operational space weather observations.

Video Credit: SpaceX

Duration: 28 seconds
Date: Sept. 24, 2025

#NASA #NOAA #Space #Astronomy #Science #IMAPMission #IMAP #Stars #InterstellarMedium #ISM #Sun #Heliophysics #Heliosphere #Planets #Earth #SolarSystem #SolarPlasma #SolarWind #SpaceWeather #PrincetonU #SWFOL1 #CarruthersGeocoronaObservatory #GSFC #SpaceX #Falcon9Rocket #KSC #Florida #UnitedStates #STEM #Education #HD #Video

Stellar Nursery Sagittarius B2: MIRI versus NIRCam Views | Webb Telescope

Stellar Nursery Sagittarius B2: MIRI versus NIRCam Views | Webb Telescope

This video shows two views of a colorful array of massive stars and glowing cosmic dust in the Sagittarius B2 (Sgr B2) molecular cloud, the most massive and active star-forming region in our Milky Way galaxy.

The first image shown is Webb’s mid-infrared instrument (MIRI) view of the Sgr B2 region in mid-infrared light with warm dust glowing brightly. To the right is one clump of clouds that captured astronomers’ attention. It is redder than the rest of the clouds in the image and corresponds to an area that other telescopes have shown to be one of the most molecularly rich regions known. 

The second image shown is the molecular cloud glow in near-infrared light, captured by Webb’s near-infrared camera (NIRCam). In this light, astronomers see more of the region’s diverse, colorful stars, but less of its gas and dust structure.

Only the brightest stars in this region emit mid-infrared light that can be picked up by Webb’s MIRI instrument. This is why the first image has so many fewer stars than that captured by Webb’s NIRCam in the second image.

Credit: NASA, ESA, CSA, STScI, A. Ginsburg (University of Florida), N. Budaiev (University of Florida), T. Yoo (University of Florida), A. Pagan (STScI), N. Bartmann (ESA/Webb)

Duration: 30 seconds
Release Date: Sept. 24, 2025

#NASA #Astronomy #Space #Science #Stars #Nebulae #SagittariusB2 #SgrB2 #MolecularClouds #Sagittarius #Constellations #MilkyWayGalaxy #Universe #SpaceTelescopes #JWST #MIRI #NIRCam #InfraredAstronomy #GSFC #STScI #UnitedStates #ESA #Europe #CSA #Canada #STEM #Education #HD #Video

Close-up: Molecular Cloud Sagittarius B2 (MIRI image) | Webb Telescope

Close-up: Molecular Cloud Sagittarius B2 (MIRI image) | Webb Telescope

Webb’s mid-infrared instrument (MIRI) shows the Sagittarius B2 (Sgr B2) region in mid-infrared light, with warm dust glowing brightly. To the right is one clump of clouds that captured astronomers’ attention. It is redder than the rest of the clouds in the image and corresponds to an area that other telescopes have shown to be one of the most molecularly rich regions known. Additional analysis of this intriguing region could yield important insights into why Sgr B2 is so much more productive in making stars than the rest of the galactic center.

Only the brightest stars in this region emit mid-infrared light that can be picked up by Webb’s MIRI instrument. This is why this image has so many fewer stars than that captured by Webb’s near-infrared camera (NIRCam). The darkest areas of the image are not empty space but areas where cosmic dust and gas are so dense that light cannot penetrate them to reach the telescope.

Image Description: Cosmic clouds of pink and purple are surrounded by dark areas that appear like black space dotted with bright blue stars. A group of small clouds to the right is more red than any other area of the image.

Credit: NASA, ESA, CSA, STScI, A. Ginsburg (University of Florida), N. Budaiev (University of Florida), T. Yoo (University of Florida)

Image Processing: A. Pagan (STScI)

Duration: 30 seconds
Release Date: Sept. 24, 2025

#NASA #Astronomy #Space #Science #Stars #Nebulae #SagittariusB2 #SgrB2 #MolecularClouds #Sagittarius #Constellations #MilkyWayGalaxy #Universe #SpaceTelescopes #JWST #MIRI #InfraredAstronomy #GSFC #STScI #UnitedStates #ESA #Europe #CSA #Canada #STEM #Education #HD #Video

Molecular Cloud Sagittarius B2 (MIRI image) | James Webb Space Telescope

Molecular Cloud Sagittarius B2 (MIRI image) | James Webb Space Telescope

Webb’s mid-infrared instrument (MIRI) shows the Sagittarius B2 (Sgr B2) region in mid-infrared light, with warm dust glowing brightly. To the right is one clump of clouds that captured astronomers’ attention. It is redder than the rest of the clouds in the image and corresponds to an area that other telescopes have shown to be one of the most molecularly rich regions known. Additional analysis of this intriguing region could yield important insights into why Sgr B2 is so much more productive in making stars than the rest of the galactic center.

Only the brightest stars in this region emit mid-infrared light that can be picked up by Webb’s MIRI instrument. This is why this image has so many fewer stars than that captured by Webb’s near-infrared camera (NIRCam). The darkest areas of the image are not empty space but areas where cosmic dust and gas are so dense that light cannot penetrate them to reach the telescope.

Image Description: Cosmic clouds of pink and purple are surrounded by dark areas that appear like black space dotted with bright blue stars. A group of small clouds to the right is more red than any other area of the image.

Credit: NASA, ESA, CSA, STScI, A. Ginsburg (University of Florida), N. Budaiev (University of Florida), T. Yoo (University of Florida)

Image Processing: A. Pagan (STScI)
Release Date: Sept. 24, 2025

#NASA #Astronomy #Space #Science #Stars #Nebulae #SagittariusB2 #SgrB2 #MolecularClouds #Sagittarius #Constellations #MilkyWayGalaxy #Universe #SpaceTelescopes #JWST #MIRI #InfraredAstronomy #GSFC #STScI #UnitedStates #ESA #Europe #CSA #Canada #STEM #Education 

Close-up: Sagittarius B2 Molecular Cloud (NIRCam image) | Webb Telescope

Close-up: Sagittarius B2 Molecular Cloud (NIRCam image) | Webb Telescope

Stars, gas and cosmic dust in the Sagittarius B2 molecular cloud glow in near-infrared light, captured by Webb’s near-infrared camera (NIRCam). In this light, astronomers see more of the region’s diverse, colorful stars, but less of its gas and dust structure. Webb’s instruments each provide astronomers with important information that help build a more complete picture of what is happening in this intriguing portion of the center of our galaxy. 

Sagittarius B2 (Sgr B2) is located about 390 light years from the center of the Milky Way. This complex is the largest molecular cloud in the vicinity of the core and one of the largest in the galaxy, spanning a region about 150 light years across. The total mass of Sgr B2 is about 3 million times the mass of the Sun.

Sagittarius B2 is located only a few hundred light-years from the supermassive black hole at the heart of the galaxy called Sagittarius A*, a region densely packed with stars, star-forming clouds, and complex magnetic fields. The infrared light that Webb detects is able to pass through a portion of the area’s thick clouds to reveal young stars and the warm dust surrounding them. Astronomers think that analysis of Webb’s data will help unravel enduring mysteries of the star formation process, and why Sagittarius B2 is forming so many more stars than the rest of the galactic center.

However, one of the most notable aspects of Webb’s images of Sagittarius B2 are the portions that remain dark. These ironically empty-looking areas of space are actually so dense with gas and dust that even Webb cannot see through them. These thick clouds are the raw material of future stars and a cocoon for those still too young to shine.

Image Description: A wide view of a region of space filled with stars and clumps of orange clouds.

Credit: NASA, ESA, CSA, STScI, A. Ginsburg (University of Florida), N. Budaiev (University of Florida), T. Yoo (University of Florida). Image processing: A. Pagan (STScI)

Duration: 30 seconds
Release Date: Sept. 24, 2025

#NASA #Astronomy #Space #Science #Stars #Nebulae #SagittariusB2 #SgrB2 #MolecularClouds #Sagittarius #Constellations #MilkyWayGalaxy #Universe #SpaceTelescopes #JWST #NIRCam #InfraredAstronomy #GSFC #STScI #UnitedStates #ESA #Europe #CSA #Canada #STEM #Education #HD #Video

Sagittarius B2 Molecular Cloud (NIRCam image) | James Webb Space Telescope

Sagittarius B2 Molecular Cloud (NIRCam image) | James Webb Space Telescope

Stars, gas and cosmic dust in the Sagittarius B2 molecular cloud glow in near-infrared light, captured by Webb’s near-infrared camera (NIRCam). In this light, astronomers see more of the region’s diverse, colorful stars, but less of its gas and dust structure. Webb’s instruments each provide astronomers with important information that help build a more complete picture of what is happening in this intriguing portion of the center of our galaxy. 

Sagittarius B2 (Sgr B2) is located about 390 light years from the center of the Milky Way. This complex is the largest molecular cloud in the vicinity of the core and one of the largest in the galaxy, spanning a region about 150 light years across. The total mass of Sgr B2 is about 3 million times the mass of the Sun.

Sagittarius B2 is located only a few hundred light-years from the supermassive black hole at the heart of the galaxy called Sagittarius A*, a region densely packed with stars, star-forming clouds, and complex magnetic fields. The infrared light that Webb detects is able to pass through a portion of the area’s thick clouds to reveal young stars and the warm dust surrounding them. Astronomers think that analysis of Webb’s data will help unravel enduring mysteries of the star formation process, and why Sagittarius B2 is forming so many more stars than the rest of the galactic center.

However, one of the most notable aspects of Webb’s images of Sagittarius B2 are the portions that remain dark. These ironically empty-looking areas of space are actually so dense with gas and dust that even Webb cannot see through them. These thick clouds are the raw material of future stars and a cocoon for those still too young to shine.

Image Description: A wide view of a region of space filled with stars and clumps of orange clouds.

Credit: NASA, ESA, CSA, STScI, A. Ginsburg (University of Florida), N. Budaiev (University of Florida), T. Yoo (University of Florida). Image processing: A. Pagan (STScI)
Release Date: Sept. 24, 2025

#NASA #Astronomy #Space #Science #Stars #Nebulae #SagittariusB2 #SgrB2 #MolecularClouds #Sagittarius #Constellations #MilkyWayGalaxy #Universe #SpaceTelescopes #JWST #NIRCam #InfraredAstronomy #GSFC #STScI #UnitedStates #ESA #Europe #CSA #Canada #STEM #Education 

SpaceX Falcon 9 Liftoff: IMAP, SWFO-L1, & Carruthers Missions | NASA Kennedy

SpaceX Falcon 9 Liftoff: IMAP, SWFO-L1, & Carruthers Missions | NASA Kennedy

A SpaceX Falcon 9 rocket successfully launched and deployed NASA’s Interstellar Mapping and Acceleration Probe (IMAP), the agency’s Carruthers Geocorona Observatory, and the National Oceanic and Atmospheric Administration’s (NOAA) Space Weather Follow On–Lagrange 1 (SWFO-L1) spacecraft. Launch took place on schedule at 7:30 a.m. EDT, Wednesday, Sept. 24, 2025, from Launch Complex 39A at NASA's Kennedy Space Center in Florida. 

The missions will each focus on different effects of the solar wind—the continuous stream of particles emitted by the Sun—and space weather—the changing conditions in space driven by the Sun—from their origins at the Sun to their farthest reaches billions of miles away at the edge of our solar system. 

The Interstellar Mapping and Acceleration Probe (IMAP) will explore and map the heliosphere—the invisible cosmic shield surrounding our solar system—to answer great unknowns about how particles accelerate in the solar wind.

Learn more about IMAP: 
https://science.nasa.gov/mission/imap/ 
https://imap.princeton.edu/

NASA’s Carruthers Geocorona Observatory is a small satellite that will observe Earth’s outermost atmospheric layer, the exosphere. It will image the faint glow of ultraviolet light from this region, called the geocorona, to better understand how space weather impacts our planet. The Carruthers mission continues the legacy of the Apollo era, expanding on measurements first taken during Apollo 16.

The SWFO-L1 spacecraft will monitor space weather and detect solar storms in advance, serving as an early warning beacon for potentially disruptive space weather, helping safeguard Earth’s critical infrastructure and technological-dependent industries. The SWFO-L1 spacecraft is the first NOAA observatory designed specifically for and fully dedicated to continuous, operational space weather observations.

Video Credit: SpaceX

Duration: 26 seconds
Date: Sept. 24, 2025

#NASA #NOAA #Space #Astronomy #Science #IMAPMission #IMAP #Stars #InterstellarMedium #ISM #Sun #Heliophysics #Heliosphere #Planets #Earth #SolarSystem #SolarPlasma #SolarWind #SpaceWeather #PrincetonU #SWFOL1 #CarruthersGeocoronaObservatory #GSFC #SpaceX #Falcon9Rocket #KSC #Florida #UnitedStates #STEM #Education #HD #Video