Wednesday, November 08, 2023

NASA Artemis II Moon Crew Vehicle: European Service Module Integration

NASA Artemis II Moon Crew Vehicle: European Service Module Integration






The Artemis II mission will bring astronauts around the Moon and back for the first time in over 50 years. Engineers connected the Orion crew and European service modules for the Artemis II mission on Oct. 19, 2023, inside the Neil Armstrong Operations and Checkout Building at NASA’s Kennedy Space Center in Florida. With the crew and service modules integrated, the team will power up the combined crew and service module for the first time. After power on tests are complete, Orion will begin altitude chamber testing, which will put the spacecraft through conditions as close as possible to the environment it will experience in the vacuum of deep space. 

The crew and service modules are the two major components of Orion that will fly NASA astronauts Reid Wiseman, Victor Glover, and Christina Koch, along with Canadian Space Agency (CSA) astronaut Jeremy Hansen on a mission around the Moon and bring them home safely.


Credit: NASA/Frank Michaux/Amanda Stevenson

Image Date: Oct. 19, 2023


#NASA #Space #Astronomy #Earth #Moon #MoonToMars #Mars #ArtemisProgram #ArtemisII #OrionSpacecraft #EuropeanServiceModule #ESM #Astronauts #HumanSpaceflight #SolarSystem #Science #Exploration #KSC #Florida #UnitedStates #Europe #ESA #STEM #Education

Tuesday, November 07, 2023

Highlights of The Perseus Cluster of Galaxies | ESA Euclid Space Telescope

Highlights of The Perseus Cluster of Galaxies | ESA Euclid Space Telescope



These high resolution cutouts from Euclid's full view of the Perseus Cluster showcases the power of the European Space Agency's new Euclid space telescope in obtaining extremely sharp images over a large region of the sky in one single pointing. Although these images represent only a small part of the entire color view, the same quality shown here is available over the full field.

Many faint galaxies were previously unseen. Several of them are so distant that their light has taken 10 billion years to reach us. By mapping the distribution and shapes of these galaxies, cosmologists will be able to find out more about how dark matter shaped the Universe that we see today.

This is the first time that such a large image has allowed us to capture so many Perseus galaxies with a high level of detail. Perseus is one of the most massive structures known in the Universe, located ‘just’ 240 million light-years away from Earth, containing thousands of galaxies, immersed in a vast cloud of hot gas. Astronomers demonstrated that galaxy clusters like Perseus can only have formed if dark matter is present in the Universe.

Image Credit: ESA/Euclid/Euclid Consortium/NASA 

Image Processing: J.-C. Cuillandre (CEA Paris-Saclay), G. Anselmi, CC BY-SA 3.0 IGO

Release Date: Nov. 7, 2023


#NASA #ESA #ESAEuclid #Astronomy #Space #Science #Galaxies #GalaxyCluster #PerseusGalaxyCluster #Perseus #Constellation #Cosmos #Universe #ESAEuclid #EuclidSpaceTelescope #Europe #STEM #Education

Pan & Zoom: The Perseus Cluster of Galaxies | ESA Euclid Space Telescope

Pan & Zoom: The Perseus Cluster of Galaxies | ESA Euclid Space Telescope


The European Space Agency's new Euclid space telescope captured this incredible snapshot—a revolution for astronomy. This image shows ~1,000+ galaxies belonging to the Perseus Cluster, and more than 100,000 additional galaxies further away in the background, each containing up to hundreds of billions of stars. 

Many of these faint galaxies were previously unseen. Several of them are so distant that their light has taken 10 billion years to reach us. By mapping the distribution and shapes of these galaxies, cosmologists will be able to find out more about how dark matter shaped the Universe that we see today.

This is the first time that such a large image has allowed us to capture so many Perseus galaxies in such a high level of detail. Perseus is one of the most massive structures known in the Universe, located ‘just’ 240 million light-years away from Earth, containing thousands of galaxies, immersed in a vast cloud of hot gas. Astronomers demonstrated that galaxy clusters like Perseus can only have formed if dark matter is present in the Universe.

Video Credit: ESA/Euclid/Euclid Consortium/NASA 

Image Processing: J.-C. Cuillandre (CEA Paris-Saclay), G. Anselmi, CC BY-SA 3.0 IGO

Duration: 49 seconds

Release Date: Nov. 7, 2023


#NASA #ESA #ESAEuclid #Astronomy #Space #Science #Galaxies #GalaxyCluster #PerseusGalaxyCluster #Perseus #Constellation #Cosmos #Universe #ESAEuclid #EuclidSpaceTelescope #Europe #STEM #Education #HD #Video

Panning across The Horsehead Nebula | ESA Euclid Space Telescope

Panning across The Horsehead Nebula | ESA Euclid Space Telescope

Euclid shows us a spectacularly panoramic and detailed view of the Horsehead Nebula, also known as Barnard 33 and part of the constellation Orion.

At approximately 1375 light-years away, the Horsehead—visible as a dark cloud shaped like a horse’s head—is the closest giant star-forming region to Earth. It sits just to the south of star Alnitak, the easternmost of Orion’s famous three-star belt, and is part of the vast Orion molecular cloud.

Many other telescopes have taken images of the Horsehead Nebula, but none of them are able to create such a sharp and wide view as Euclid can with just one observation. Euclid captured this image of the Horsehead in about one hour, which showcases the mission's ability to very quickly image an unprecedented area of the sky in high detail.


Credits: ESA/Euclid/Euclid Consortium/NASA Image Processing: J.-C. Cuillandre (CEA Paris-Saclay), G. Anselmi, CC BY-SA 3.0 IGO

Duration: 37 seconds

Release Date: Nov. 6, 2023


#NASA #ESA #ESAEuclid #Astronomy #Space #Science #Nebulae #Nebula #HorseheadNebula #Barnard33 #Star #SigmaOrionis #Orion #Constellation #Cosmos #Universe #ESAEuclid #EuclidSpaceTelescope #Europe #STEM #Education #HD #Video

The Horsehead Nebula | Europe's Euclid Space Telescope

The Horsehead Nebula | Europe's Euclid Space Telescope


The European Space Agency's new Euclid space telescope shows us a spectacularly panoramic and detailed view of the Horsehead Nebula, also known as Barnard 33 and part of the constellation Orion. About 1,375 light-years away, it is the closest giant star-forming region to Earth.  It sits just to the south of star Alnitak, the easternmost of Orion’s famous three-star belt, and is part of the vast Orion molecular cloud. With Euclid, which captured this image, scientists hope to find many dim and previously unseen Jupiter-mass planets in their celestial infancy, as well as baby stars. 

Many other telescopes have taken images of the Horsehead Nebula, but none of them are able to create such a sharp and wide view as Euclid can with just one observation. Euclid captured this image of the Horsehead in about one hour, which showcases the mission's ability to very quickly image an unprecedented area of the sky in high detail.

In Euclid’s new observation of this stellar nursery, scientists hope to find many dim and previously unseen Jupiter-mass planets in their celestial infancy, as well as young brown dwarfs and baby stars.

“We are particularly interested in this region, because star formation is taking place in very special conditions,” explains Eduardo Martin Guerrero de Escalante of the Instituto de Astrofisica de Canarias in Tenerife and a legacy scientist for Euclid.

These special conditions are caused by radiation coming from the very bright star Sigma Orionis, which is located above the Horsehead, just outside Euclid’s field-of-view (the star is so bright that the telescope would see nothing else if it pointed directly towards it).

Ultraviolet radiation from Sigma Orionis causes the clouds behind the Horsehead to glow, while the thick clouds of the Horsehead itself block light from directly behind it; this makes the head look dark. The nebula itself is made up largely of cold molecular hydrogen, which gives off very little heat and no light. Astronomers study the differences in the conditions for star formation between the dark and bright clouds.

The star Sigma Orionis itself belongs to a group of more than a hundred stars, called an open cluster.


Credit: ESA/Euclid/Euclid Consortium/NASA, image processing by J.-C. Cuillandre (CEA Paris-Saclay), G. Anselmi; CC BY-SA 3.0 IGO

Release Date: Nov. 7, 2023


#NASA #ESA #ESAEuclid #Astronomy #Space #Science #Nebulae #Nebula #HorseheadNebula #Barnard33 #Star #SigmaOrionis #Orion #Constellation #Cosmos #Universe #ESAEuclid #EuclidSpaceTelescope #Europe #STEM #Education

Euclid Space Telescope: First Images | European Space Agency

Euclid Space Telescope: First Images | European Space Agency

On Nov. 7, 2023, the European Space Agency (ESA) released the first full-color images captured by the Euclid space telescope—the Perseus cluster of galaxies, the globular cluster NGC 6397, the irregular galaxy NGC 6822, the spiral galaxy IC 342 and the Horsehead Nebula.


Video Credit: ESA/Euclid/Euclid Consortium/NASA 

Image Processing: J.-C. Cuillandre (CEA Paris-Saclay), G. Anselmi

Acknowledgement: SciNews

Duration: 2 minutes, 49 seconds

Release Date: Nov. 7, 2023


#NASA #ESA #ESAEuclid #Astronomy #Space #Science #Nebulae #HorseheadNebula #Stars #GlobularCluster #NGC6397 #Galaxies #GalaxyCluster #PerseusGalaxyCluster #Galaxy #IrregularGalaxy #NGC6822 #IC342 #Cosmos #Universe #ESAEuclid #EuclidSpaceTelescope #Europe #STEM #Education #HD #Video

Monday, November 06, 2023

Planet Mars Images: November 2023 | NASA's Perseverance Rover | JPL

Planet Mars Images: November 2023 | NASA's Perseverance Rover | JPL

Mars 2020 - sol 963
Mars 2020 - sol 963
Mars 2020 - sol 959
Mars 2020 - sol 959
Mars 2020 - sol 963
Mars 2020 - sol 961


Celebrating 2+ 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.
Mars Helicopter (Ingenuity)
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: Nov. 3-6, 2023

#NASA #Space #Astronomy #Science #Mars #RedPlanet #Planet #Astrobiology #Geology #PerseveranceRover #Mars2020 #IngenuityHelicopter #JezeroCrater #Robotics #SpaceTechnology #SpaceEngineering #JPL #Caltech #UnitedStates #CitizenScience #KevinGill #STEM #Education

Twilight Magic: The Moon and Jupiter in Colorado Skies

Twilight Magic: The Moon and Jupiter in Colorado Skies

Astrophotographer Mike Lewinski: "Moon up top, Jupiter in the middle."


"Twilight drops her curtain down, and pins it with a star."

—Lucy Maud Montgomery, Canadian author (1874–1942)


Twilight is light produced by sunlight scattering in the upper atmosphere, when the Sun is below the horizon. It illuminates the lower atmosphere and the Earth's surface.


Image Credit: Mike Lewinski

Image Date: Nov. 6, 2023


#NASA #Space #Astronomy #Science #Stars #SolarSystem #Planets #Jupiter #Earth #Moon #Planet #Twilight #Atmosphere #Astrophotography #NightPhotography #MikeLewinski #Astrophotographer #CitizenScience #SolarSystem #Crestone #SanLuisValley #Colorado #UnitedStates #STEM #Education

NASA's Artemis II Moon Rocket: Watch Crews Add RS-25 Engines

NASA's Artemis II Moon Rocket: Watch Crews Add RS-25 Engines

NASA's Artemis II Moon rocket reached a significant milestone as teams fully installed all four RS-25 engines to the 212-foot-tall core stage for NASA’s Space Launch System (SLS) rocket at NASA’s Michoud Assembly Facility in New Orleans. During Artemis II, the four engines, arranged like legs on a chair at the bottom of the mega rocket, will fire for eight minutes at launch, producing more than 2 million pounds of thrust to send the Artemis II crew around the Moon. 

Boeing is the lead contractor for the SLS core stage. Aerojet Rocketdyne, an L3Harris Technologies company, is the lead contractor for the SLS engines. NASA’s Marshall Space Flight Center in Huntsville, Alabama, manages the SLS Program and Michoud.

Learn more about the Artemis II Mission: https://www.nasa.gov/artemis-ii 

For more information about NASA’s Space Launch System (SLS), visit https://www.nasa.gov/sls


Video Credit: NASA's Marshall Space Flight Center (MSFC)

Duration: 2 minutes

Release Date: Nov. 6, 2023

#NASA #Space #Moon #NASAArtemis #ArtemisProgram #ArtemisII #NASASLS #SpaceLaunchSystem #SLS #CoreStage #RS25Engines #AerojetRocketdyne #Boeing #DeepSpace #Astronauts #MoonToMars #Science #Engineering #SpaceTechnology #SpaceExploration #SolarSystem #MSFC #NASAMichoud #MAF #NewOrleans #Louisiana #UnitedStates #STEM #Education

Distant Galaxy UHZ1: NASA Space Telescopes Discover Record-Breaking Black Hole

Distant Galaxy UHZ1: NASA Space Telescopes Discover Record-Breaking Black Hole

This image contains the most distant black hole ever detected in X-rays, a result that may explain how some of the first supermassive black holes in the universe formed. This discovery was made using X-rays from NASA’s Chandra X-ray Observatory (purple) and infrared data from NASA’s James Webb Space Telescope (red, green, blue).

The extremely distant black hole is located in the galaxy UHZ1 in the direction of the galaxy cluster Abell 2744. The galaxy cluster is about 3.5 billion light-years from Earth. Webb data, however, reveal that UHZ1 is much farther away than Abell 2744. At some 13.2 billion light-years away, UHZ1 is seen when the universe was only 3% of its current age.

By using over two weeks of observations from Chandra, researchers were able to detect X-ray emission from UHZ1—a telltale signature of a growing supermassive black hole in the center of the galaxy. The X-ray signal is extremely faint and Chandra was only able to detect it—even with this long observation—because of the phenomenon known as gravitational lensing that enhanced the signal by a factor of four.

The purple parts of the image show X-rays from large amounts of hot gas in Abell 2744. The infrared image shows hundreds of galaxies in the cluster, along with a few foreground stars. The insets zoom into a small area centered on UHZ1. The small object in the Webb image is the distant galaxy UHZ1 and the center of the Chandra image shows X-rays from material close to the supermassive black hole in the middle of UHZ1. The large size of the X-ray source compared to the infrared view of the galaxy is because it represents the smallest size that Chandra can resolve. The X-rays actually come from a region that is much smaller than the galaxy.

Different smoothing was applied to the full-field Chandra image and to the Chandra image in the close-up. Smoothing across many pixels was performed for the large image, to highlight the faint cluster emission, at the expense of not showing faint X-ray point sources like UHZ1. Much less smoothing was applied to the close-up so faint X-ray sources are visible. The image is oriented so that north points 42.5 degrees to the right of vertical.

This discovery is important for understanding how supermassive black holes—those that contain up to billions of solar masses and reside in the centers of galaxies—can reach colossal masses soon after the big bang. Do they form directly from the collapse of massive clouds of gas, creating black holes weighing between about ten thousand and a hundred thousand suns? Or do they come from explosions of the first stars that create black holes weighing only between about ten and a hundred suns?

The team of astronomers found strong evidence that the newly discovered black hole in UHZ1 was born massive. They estimate its mass falls between 10 and 100 million suns, based on the brightness and energy of the X-rays. This mass range is similar to that of all the stars in the galaxy where it lives, which is in stark contrast to black holes in the centers of galaxies in the nearby universe that usually contain only about a tenth of a percent of the mass of their host galaxy’s stars.

The large mass of the black hole at a young age, plus the amount of X-rays it produces and the brightness of the galaxy detected by Webb, all agree with theoretical predictions in 2017 for an “Outsize Black Hole” that directly formed from the collapse of a huge cloud of gas.

The researchers plan to use this and other results pouring in from Webb and those combining data from other telescopes to fill out a larger picture of the early universe.

The paper describing the results appears in Nature Astronomy and a preprint is available online: 

https://arxiv.org/abs/2305.15458

Visual Description:

The main image of this release features a glimpse of a black hole in an early stage of its development, just 470 million years after the Big Bang.

The composite image shows data from NASA's Chandra X-ray Observatory and James Webb Space Telescope. It features scores of seemingly tiny celestial objects in a sea of black. This is the galaxy cluster Abell 2744. When magnified, the tiny white, orange, and purple celestial objects are revealed to be spiral and elliptical galaxies, and gleaming stars. Many of these colorful specks appear to float in a neon purple cloud of X-ray gas in the center of the image, some 3.5 billion light-years from Earth.

Just to the right of center, at the edge of the purple gas cloud, is a tiny orange speck. This speck is far in the distance, well beyond the Abell galaxy cluster. It represents a galaxy 13.2 billion light-years from Earth containing a supermassive black hole.

In this composite image packed with celestial objects, the tiny orange speck is easily overlooked. Therefore, the main image of the release is also presented fully labelled. In the labelled version of the image, a thin box outlines the distant galaxy, and two enlargements are inset at our upper left. In the enlargement showing Chandra data, a hazy, neon purple oval with a light pink core is shown. This purple oval represents intense X-rays from a growing supermassive black hole estimated to weigh between 10 and 100 million suns. The purple oval is not visible in the composite image because of the way the Chandra data was processed. This black hole is located in the distant galaxy in the center of the enlargement showing Webb data.

NASA's Marshall Space Flight Center 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.

The James Webb Space Telescope is the world’s premier space science observatory. Webb will solve mysteries in our solar system, look beyond to distant worlds around other stars, and probe the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, European Space Agency (ESA) and the Canadian Space Agency (CSA).


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

Image Processing: NASA/CXC/SAO/L. Frattare & K. Arcand

Release Date: Nov. 6, 2023


#NASA #Space #Astronomy #Science #GalaxyUHZ1 #Abell2744 #Constellation #Sculptor #Cosmos #Universe #NASAChandra #ChandraObservatory #Xray #MSFC #JWST #Infrared #SpaceTelescopes #ESA #GSFC #STScI #UnitedStates #ESA #CSA #Infographic #STEM #Education

NASA Webb & Chandra Space Telescopes Discover Record-Breaking Black Hole

NASA Webb & Chandra Space Telescopes Discover Record-Breaking Black Hole

Astronomers have discovered the most distant black hole yet seen in X-rays using two NASA telescopes, the Chandra X-ray Observatory and James Webb Space Telescope. The black hole is at an early stage of growth that had never been witnessed before, where its mass is similar to that of its host galaxy.

This result may explain how some of the first supermassive black holes in the universe formed.

By combining data from Chandra and Webb, a team of researchers was able to find the telltale signature of a growing black hole just 470 million years after the Big Bang. The extremely distant black hole is located in the galaxy UHZ1 in the direction of the galaxy cluster Abell 2744. The galaxy cluster is about 3.5 billion light-years from Earth. However, the Webb data reveal that UHZ1 is actually much farther away than Abell 2744. At some 13.2 billion light-years away, astronomers are seeing UHZ1 when the universe was only 3% of its current age.

By using over two weeks of observations from Chandra, the researchers were able to detect X-ray emission from UHZ1. This is a telltale signature of a growing supermassive black hole in the center of the galaxy. The X-ray signal is extremely faint and Chandra was only able to detect it—even with this long observation—because of the phenomenon known as gravitational lensing that enhanced the signal by some 400%.

This discovery is important for understanding how some supermassive black holes can reach colossal masses soon after the big bang. Do they form directly from the collapse of massive clouds of gas, creating black holes weighing between about ten thousand and a hundred thousand suns? Or do they come from explosions of the first stars that create black holes weighing only between about ten and a hundred suns?

The researchers suggest this is the best evidence yet obtained that some black holes form from massive clouds of gas. They plan to use this and other results pouring in from Webb and those combining data from other telescopes including Chandra to help fill out a larger picture of black holes in the early universe.


Video Credit: Chandra X-ray Observatory

Duration: 2 minutes, 52 seconds

Release Date: Nov. 6, 2023


#NASA #Space #Astronomy #Science #GalaxyUHZ1 #Abell2744 #Constellation #Sculptor #Cosmos #Universe #NASAChandra #ChandraObservatory #Xray #MSFC #JWST #Infrared #SpaceTelescopes #ESA #GSFC #STScI #UnitedStates #ESA #CSA #STEM #Education #HD #Video

Spiral Galaxy NGC 941 in Cetus | Hubble Space Telescope

Spiral Galaxy NGC 941 in Cetus | Hubble Space Telescope

This image features the spiral galaxy NGC 941. It lies about 55 million light-years from Earth. The data used for this image were collected by Hubble’s Advanced Camera for Surveys (ACS). The beautiful NGC 941 is undoubtedly the main attraction in this image; however, this hazy-looking galaxy was not the motivation for the data being collected. That distinction belongs to an astronomical event that took place in the galaxy years before: the supernova SN 2005ad. The location of this faded supernova was observed as part of a study of multiple hydrogen-rich supernovae, also known as type II supernovae, in order to better understand the environments in certain types of supernovae take place. Whilst the study was conducted by professional astronomers, SN 2005ad itself owes its discovery to a distinguished amateur astronomer named Kōichi Itagaki, who has discovered over 170 supernovae.

Image Description: A spiral galaxy, seen face-on from Earth. The spiral arms of the galaxy are bright but not well defined, merging into a swirling disc with a faint halo of dimmer gas around it. The core glows brightly in a lighter color and has a bit of faint dust crossing it. Two redder, visually smaller galaxies and a bright star are prominent around the galaxy, with more tiny objects in the background.

This might raise the question of how an amateur astronomer could spot something like a supernova event before professional astronomers—who have access to telescopes such as Hubble. The answer is in part that the detection of supernovae is a mixture of skill, facilities and luck. Most astronomical events happen over time spans that dwarf human lifetimes, but supernova explosions are extraordinarily fast, appearing very suddenly and then brightening and dimming over a period of days or weeks. 

Another aspect is that professional astronomers often do not spend that much time actually observing. There is a great deal of competition for time on telescopes such as Hubble, and then data from a few hours of observations might take weeks, months, or sometimes even years to process and analyze to their full potential. Amateur astronomers can spend much more time actually observing the skies, and sometimes have extremely impressive systems of telescopes, computers and software that they can put to use. 

So many supernovae are spotted by skillful amateurs, such as Itagaki, that there is actually an online system set up for reporting them (the Transient Name Server). This is a big help to professional astronomers, because with supernova events time is truly of the essence. After the discovery of SN 2005ab was reported, professional astronomers were able to follow up with spectroscopic studies and confirm it as a type II supernova, which eventually led to its location being included in this study with Hubble. Such a study would not be possible without a rich library of previous supernovae, built with the keen eyes of amateur astronomers.


Credit: ESA/Hubble & NASA, C. Kilpatrick

Release Date: Nov. 6, 2023


#NASA #ESA #Hubble #Astronomy #Space #Science #Galaxies #Galaxy #NGC941 #Galaxy #Supernovae #Supernova #SN2005ab #Cetus #Constellation #Cosmos #Universe #HST #HubbleSpaceTelescope #GSFC #STScI #UnitedStates #Europe #STEM #Education

Sunday, November 05, 2023

Zooming in on Galactic Duo NGC 3169 & NGC 3166 | ESO

Zooming in on Galactic Duo NGC 3169 & NGC 3166 | ESO

This sequence starts with a wide-field view of the prominent constellation of Leo (The Lion). As we zoom in many fainter stars become visible as well as a few of the many galaxies in this part of the sky. In the final sequence we close in on the pair of galaxies NGC 3169 and NGC 3166. This detailed view was captured by the Wide Field Imager on the MPG/ESO 2.2-meter telescope at the La Silla Observatory in Chile.


Credit: European Southern Observatory (ESO)/A. Fujii/Digitized Sky Survey 2/Igor Chekalin

Duration: 1 minute

Release Dare: Nov. 27, 2015


#NASA #Astronomy #Space #Science #GalaxyCluster #Galaxies #Galaxy #NGC3166 #NGC3169 #NGC3165 #Sextans #Constellation #MilkyWayGalaxy #Cosmos #Universe #OpticalTelescope #MPGESOTelescope #LaSillaObservatory #Chile #Europe #STEM #Education #HD #Video

Galaxies NGC 3166 & NGC 3169 in Sextans | European Southern Observatory

Galaxies NGC 3166 & NGC 3169 in Sextans | European Southern Observatory


This galactic grouping, found about 70 million light-years away in the constellation Sextans (The Sextant), was discovered by the English astronomer William Herschel in 1783. Modern astronomers have gauged the distance between NGC 3169 (left) and NGC 3166 (right) as a mere 50,000 light-years, a separation that is only about half the diameter of the Milky Way Galaxy. In such tight quarters, gravity can start to play havoc with galactic structure. At the bottom-right of the pair, a third galaxy is portrayed, NGC 3165. The image comes from the Wide Field Imager on the MPG/ESO 2.2-meter telescope at the La Silla Observatory in Chile.

Spiral galaxies like NGC 3169 and NGC 3166 tend to have orderly swirls of stars and dust pinwheeling about their glowing centers. Close encounters with other massive objects can jumble this classic configuration, often serving as a disfiguring prelude to the merging of galaxies into one larger galaxy. So far, the interactions of NGC 3169 and NGC 3166 have just lent a bit of character. NGC 3169’s arms, shining bright with big, young, blue stars, have been teased apart, and lots of luminous gas has been drawn out from its disc. In NGC 3166’s case, the dust lanes that also usually outline spiral arms are in disarray. Unlike its bluer counterpart, NGC 3166 is not forming many new stars.

NGC 3169 has another distinction: the faint yellow dot beaming through a veil of dark dust just to the left of and close to the galaxy’s center. This flash is the leftover of a supernova detected in 2003 and known accordingly as SN 2003cg. A supernova of this variety, classified as a Type Ia, is thought to occur when a dense, hot star called a white dwarf—a remnant of medium-sized stars like our Sun—gravitationally sucks gas away from a nearby companion star. This added fuel eventually causes the whole star to explode in a runaway fusion reaction.


Image Credit: European Southern Observatory (ESO)/Igor Chekalin

Image Date: April 20, 2011

#NASA #Astronomy #Space #Science #GalaxyCluster #Galaxies #Galaxy #NGC3166 #NGC3169 #NGC3165 #Sextans #Constellation #MilkyWayGalaxy #Cosmos #Universe #OpticalTelescope #MPGESOTelescope #LaSillaObservatory #Chile #Europe #STEM #Education

Galaxies NGC 3166 & NGC 3169 in Sextans | Schulman Telescope

Galaxies NGC 3166 & NGC 3169 in Sextans | Schulman Telescope


This galactic grouping, found about 70 million light-years away in the constellation Sextans (The Sextant), was discovered by the English astronomer William Herschel in 1783. Modern astronomers have gauged the distance between NGC 3169 (left) and NGC 3166 (right) as a mere 50,000 light-years, a separation that is only about half the diameter of the Milky Way Galaxy. In such tight quarters, gravity can start to play havoc with galactic structure.

Spiral galaxies like NGC 3169 and NGC 3166 tend to have orderly swirls of stars and dust pinwheeling about their glowing centers. Close encounters with other massive objects can jumble this classic configuration, often serving as a disfiguring prelude to the merging of galaxies into one larger galaxy. So far, the interactions of NGC 3169 and NGC 3166 have just lent a bit of character. NGC 3169’s arms, shining bright with big, young, blue stars, have been teased apart, and lots of luminous gas has been drawn out from its disc. In NGC 3166’s case, the dust lanes that also usually outline spiral arms are in disarray. Unlike its bluer counterpart, NGC 3166 is not forming many new stars.

NGC 3169 has another distinction: the faint yellow dot beaming through a veil of dark dust just to the left of and close to the galaxy’s center. This flash is the leftover of a supernova detected in 2003 and known accordingly as SN 2003cg. A supernova of this variety, classified as a Type Ia, is thought to occur when a dense, hot star called a white dwarf—a remnant of medium-sized stars like our Sun—gravitationally sucks gas away from a nearby companion star. This added fuel eventually causes the whole star to explode in a runaway fusion reaction.

Technical Details

Optics: Schulman 32-inch RCOS Telescope

Camera: SBIG STX16803

The 0.81 m (32 in) Schulman Telescope is a Ritchey-Chrétien reflector built by RC Optical Systems and installed in 2010. It is operated by the Mount Lemmon SkyCenter and is Arizona's largest dedicated public observatory. The Schulman Telescope was designed from inception for remote control over the Internet by amateur and professional astrophotographers worldwide. It is currently the world's largest telescope dedicated for this purpose.


Image Credit & Copyright: Adam Block/Mount Lemmon SkyCenter/University of Arizona
Caption Acknowledgements: Adam Block/European Southern Observatory (ESO)
Image Date: Jan. 1, 2013

#NASA #Astronomy #Space #Science #GalaxyCluster #Galaxies #Galaxy #NGC3166 #NGC3169 #Sextans #Constellation #MilkyWayGalaxy #Cosmos #Universe #UA #MountLemmonObservatory #SchulmanTelescope #Astrophotographer #AdamBlock #Arizona #UnitedStates #STEM #Education

Panning over Starstruck Image of Irregular Galaxy Arp 263 | Hubble

Panning over Starstruck Image of Irregular Galaxy Arp 263 | Hubble


The irregular galaxy Arp 263 lurks in the background of this image from the NASA/European Space Agency Hubble Space Telescope, but the view is dominated by a stellar photobomber; the bright star BD+17 2217. Arp 263—also known as NGC 3239—is a patchy, irregular galaxy studded with regions of recent star formation, and astronomers believe that its ragged appearance is due to its having formed from the merger of two galaxies. It lies around 25 million light-years away in the constellation Leo.


Image Description: An irregular galaxy that appears like a triangle-shaped patch of tiny stars. It is densest in the center and along one edge, growing faint out to the opposite corner. Several bright pink patches mark areas of star formation, and the galaxy’s brightest stars are around these. A large, bright star, with two sets of long spikes, stands between the viewer and the galaxy.

The interloping foreground star, BD+17 2217, is adorned with two sets of criss-crossing diffraction spikes. The interaction of light with Hubble’s internal structure means that concentrated bright objects such as stars are surrounded by four prominent spikes. Since this image of BD+17 2217 was created using two sets of Hubble data, the spikes from both images surround this stellar photobomber. The spikes are at different angles because Hubble was at different orientations when it collected the two datasets.

Two different Hubble investigations into Arp 263, using two of Hubble’s third-generation instruments, contributed data to this image. The first investigation was part of an effort to observe the sites of recent supernovae, such as the supernova SN 2012A that was detected just over a decade ago in Arp 263. Astronomers used Hubble’s powerful Wide Field Camera 3 to search for lingering remnants of the colossal stellar explosion. The second investigation is part of a campaign using Hubble’s Advanced Camera for Surveys to image all the previously unobserved peculiar galaxies in the Arp catalogue, including Arp 263, in order to find promising subjects for further study using the James Webb Space Telescope.


Credit: European Space Agency (ESA)/Hubble & NASA, J. Dalcanton, A. Filippenko, N. Bartmann

Duration: 30 seconds

Release Date: Oct. 30, 2023


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