Wednesday, July 05, 2023

Meet the Mars Perseverance Rover's Samples: Salette & Coulettes | NASA/JPL

Meet the Mars Perseverance Rover's Samples: Salette & Coulettes | NASA/JPL

Meet two of the Martian samples that have been collected and are awaiting return to Earth as part of the Mars Sample Return campaign. As of late June 2023, NASA’s Mars Perseverance rover has collected and sealed 20 scientifically selected samples inside pristine tubes. The next stage is to get them back for study.

Considered one of the highest priorities by the scientists in the Science and Astrobiology Decadal Survey 2023-2032, Mars Sample Return would be the first mission to return samples from another planet and provides the best opportunity to reveal the early evolution of Mars, including the potential for ancient life. NASA is teaming with the European Space Agency on this important endeavor. 

Learn more about Samples No. 4 and 5—“Salette” and “Coulettes”—a pair of igneous rock samples collected from the floor of Jezero Crater. These samples capture a diversity of minerals that scientists believe show evidence of habitability on Mars. 

Read about all the carefully selected samples: https://mars.nasa.gov/mars-rock-samples

Learn more about the Mars Sample Return campaign: https://mars.nasa.gov/msr 

A key objective for Perseverance's mission on Mars is astrobiology, including the search for signs of ancient microbial life. The rover will characterize the planet's geology and past climate, pave the way for human exploration of the Red Planet, as well as be the first mission to collect and cache Martian rock and regolith (broken rock and dust).


Credit: NASA/JPL-Caltech

Duration: 1 minute

Release Date: July 5, 2023


#NASA #ESA #Space #Astronomy #Science #Mars #RedPlanet #Planet #Astrobiology #Geology #PerseveranceRover #Mars2020 #MarsSampleReturn #MSR #SampleSalette #SampleCoulettes #JezeroCrater #Robotics #Technology #Engineering #JPL #UnitedStates #Europe #MoonToMars #STEM #Education #HD #Video

Expedition 69 Astronaut Woody Hoburg Talks with Robot Brains Podcast

Expedition 69 Astronaut Woody Hoburg Talks with Robot Brains Podcast

Aboard the International Space Station, Expedition 69 Flight Engineer Woody Hoburg of NASA discussed life and work aboard the orbital outpost during an in-flight interview July 5 with the Robot Brains Podcast. Hoburg is in the midst of a long-duration mission living and working aboard the microgravity laboratory to advance scientific knowledge and demonstrate new technologies for future human and robotic exploration missions. Such research benefits people on Earth and lays the groundwork for future human exploration through the agency’s Artemis missions, which will send astronauts to the Moon to prepare for future expeditions to Mars.

NASA Astronaut William Hoburg's Official Biography:

https://www.nasa.gov/astronauts/biographies/warren-hoburg

https://www.nasa.gov/content/warren-hoburg-phd-nasa-astronaut

Follow Expedition 69 updates here:

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

Expedition 69 Crew (July 2023)

Station Commander: Sergey Prokopyev of Roscosmos (Russia)

Roscosmos (Russia): Flight Engineers Dmitri Petelin & Andrey Fedyaev

Flight Engineer Sultan Alneyadi of the United Arab Emirates (UAE)

NASA: Flight Engineers Frank Rubio, Stephen Bowen, Warren Hoburg

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. The ISS has been the most politically complex space exploration program ever undertaken.


Credit: NASA's Johnson Space Center (JSC)

Duration: 20 minutes

Release Date: July 5, 2023


#NASA #Space #Earth #Science #ISS #Astronauts #WoodyHoburg #Cosmonauts #HumanSpaceflight #Robots #Robotics #Technology #UnitedStates #Russia #Роскосмос #UAE #MicrogravityResearch #SpaceResearch #SpaceLaboratory #UNOOSA #InternationalCooperation #Expedition69 #STEM #Education #HD #Video

A Star Fit for Life | High Above Down Under | NASA Goddard

A Star Fit for Life | High Above Down Under | NASA Goddard

Episode 1: Follow two NASA rocket teams as they launch from Australia to study our nearest stellar neighbors—Alpha Centauri A & B—on a quest to understand how stars make the planets around them suitable for life. 

This is the first in a six-part series released weekly starting June 27, 2023.

To learn more about NASA’s Sounding Rockets Program - https://www.nasa.gov/soundingrockets


Credit: NASA’s Goddard Space Flight Center 

Additional footage: Office of the Chief Minister of the Northern Territory government, Equatorial Launch Australia

Additional graphics: Vecteezy.com

Host: Miles Hatfield (NASA/GSFC) 

Writers/Videographers: 

Miles Hatfield (NASA/GSFC) 

Mara Johnson-Groh (NASA/GSFC) 

Producers: 

Beth Anthony (NASA/GSFC) 

Joy Ng (NASA/GSFC) 

Lacey Young (NASA/GSFC) 

Animators: 

Walt Feimer (NASA/GSFC) 

Jenny McElligott (NASA/GSFC) 

Scientific Advisor: 

Kevin France (CU Boulder/LASP/SISTINE)

Special thanks to:

Equatorial Launch Australia

Gumatj Corporation Ltd.

Office of the Chief Minister of the Northern Territory government

Duration: 5 minutes

Release Date: June 27, 2023


#NASA #Space #Astronomy #Science #Stars #Exoplanets #Planets #GoldilocksZone #Water #Astrobiology #SoundingRockets #TeamSistine #TeamDeuce #RocketLaunches #SouthernHemisphere #Australia #NorthernTerritory #YolnguPeople #AboriginalAustralians #Host #MilesHatfield #STEM #Education #Animation #HD #Video

Living with the Stars | High Above Down Under | NASA Goddard

Living with the Stars | High Above Down Under | NASA Goddard

Episode 2: Follow two NASA rocket teams as they launch from Australia to study our nearest stellar neighbors—Alpha Centauri A & B—on a quest to understand how stars make the planets around them suitable for life. 

In this episode, hear from a local Yolngu leader and learn what it takes to make a rocket range from scratch. (Spoiler: It is not an easy task.)

To learn more about NASA’s Sounding Rockets Program - https://www.nasa.gov/soundingrockets


Credit: NASA’s Goddard Space Flight Center (GSFC)

Additional footage: Office of the Chief Minister of the Northern Territory government, Equatorial Launch Australia

Additional graphics: motionarray.com

Host: Miles Hatfield (NASA/GSFC) 

Writers/Videographers: 

Miles Hatfield (NASA/GSFC) 

Mara Johnson-Groh (NASA/GSFC) 

Producers: 

Beth Anthony (NASA/GSFC) 

Joy Ng (NASA/GSFC) 

Lacey Young (NASA/GSFC) 

Animators: 

Walt Feimer (NASA/GSFC) 

Jenny McElligott (NASA/GSFC) 

Scientific Advisor: 

Kevin France (CU Boulder/LASP/SISTINE)

Special thanks to:

Equatorial Launch Australia

Gumatj Corporation Ltd.

Office of the Chief Minister of the Northern Territory Government

Dorothy Yunupingu

Duration: 4 minutes, 49 seconds

Release Date: July 5, 2023


#NASA #Space #Astronomy #Science #Stars #Exoplanets #Planets #Astrobiology #SoundingRockets #RocketLaunches #TeamSistine #TeamDeuce #SouthernHemisphere #Australia #NorthernTerritory #YolnguPeople #AboriginalAustralians #Host #MilesHatfield #STEM #Education #Animation #HD #Video

How Did Life Begin on Earth? We Asked a NASA Expert

How Did Life Begin on Earth? We Asked a NASA Expert

Here is a big question: How did life begin on Earth? We do not quite know, but this fundamental question is a driving force behind astrobiology research at NASA. Understanding how life originated on our planet could inform us about the potential for life to exist throughout the universe. 

Astrobiology expert Shawn Domagal-Goldman explains more about our search for answers. Explore more about astrobiology at NASA: https://astrobiology.nasa.gov

 

Credit: National Aeronautics and Space Administration (NASA)

Producers: Scott Bednar, Jessica Wilde

Editor: Daniel Salazar

Duration: 1 minute, 42 seconds

Release Date: July 5, 2023


#NASA #Space #Astronomy #Science #Exoplanets #Planets #Planet #Earth #Biology #Astrobiology #Life #ShawnDomagalGoldman #Astrobiologist #NASAGoddard #GSFC #UnitedStates #STEM #Education #HD #Video

Galaxy NGC 6946: Dust Reservoirs Found in Two Supernovae | Webb Space Telescope

Galaxy NGC 6946: Dust Reservoirs Found in Two Supernovae | Webb Space Telescope

A 4-part image is split down the middle with a vertical white line, at the top right of each half of the image is a white box extending out from lines connected to smaller white boxes in each image. On the left side, the large white box connected to the smaller white box is labeled SN 2004et. In this larger box is a zoomed-in image of a dot on the larger background image, and the zoomed-in image appears as a splotchy, red and white circle. On the right side, the large white box is labeled SN 2017eaw, and the zoomed-in image is a small light blue dot. The background images on each side are mostly black sections of a galaxy, with various smatterings of white dust clumps, small red dots, and light blue dots.

This image from the Kitt Peak National Observatory of NGC 6496 contextualizes the locations of Supernova 2004et and Supernova 2017eaw within the galaxy. Scientists using NASA’s James Webb Space Telescope’s MIRI (Mid-Infrared Instrument) found large amounts of dust within two Type II supernovae, Supernova 2004et (SN 2004et) and Supernova 2017eaw (SN 2017eaw), located 22 million light-years away from Earth in spiral galaxy NGC 6946. The large amounts of dust found in these supernovae using MIRI supports that supernovae played a key role in supplying dust to the early universe.

Researchers using NASA’s James Webb Space Telescope have made major strides in confirming the source of dust in early galaxies. Observations of two Type II supernovae, Supernova 2004et (SN 2004et) and Supernova 2017eaw (SN 2017eaw), have revealed large amounts of dust within the ejecta of each of these objects. The mass found by researchers supports the theory that supernovae played a key role in supplying dust to the early universe.

Dust is a building block for many things in our universe—planets in particular. As dust from dying stars spreads through space, it carries essential elements to help give birth to the next generation of stars and their planets. Where that dust comes from has puzzled astronomers for decades. One significant source of cosmic dust could be supernovae—after the dying star explodes, its leftover gas expands and cools to create dust.

“Direct evidence of this phenomenon has been slim up to this point, with our capabilities only allowing us to study the dust population in one relatively nearby supernova to date—Supernova 1987A, 170,000 light-years away from Earth,” said lead author Melissa Shahbandeh of Johns Hopkins University and the Space Telescope Science Institute in Baltimore, Maryland. “When the gas cools enough to form dust, that dust is only detectable at mid-infrared wavelengths provided you have enough sensitivity.”

For supernovae more distant than SN 1987A like SN 2004et and SN 2017eaw, both in NGC 6946 about 22 million light-years away, that combination of wavelength coverage and exquisite sensitivity can only be obtained with Webb’s MIRI (Mid-Infrared Instrument).

The Webb observations are the first breakthrough in the study of dust production from supernovae since the detection of newly formed dust in SN 1987A with the Atacama Large Millimeter/submillimeter Array (ALMA) telescope nearly a decade ago. 

Another particularly intriguing result of their study is not just the detection of dust, but the amount of dust detected at this early stage in the supernova’s life. In SN 2004et, the researchers found more than 5,000 Earth masses of dust.

“When you look at the calculation of how much dust we’re seeing in SN 2004et especially, it rivals the measurements in SN 1987A, and it’s only a fraction of the age,” added program lead Ori Fox of the Space Telescope Science Institute. “It’s the highest dust mass detected in supernovae since SN 1987A.” 

Observations have shown astronomers that young, distant galaxies are full of dust, but these galaxies are not old enough for intermediate-mass stars, like the Sun, to have supplied the dust as they age. More massive, short-lived stars could have died soon enough and in large enough numbers to create that much dust. 

While astronomers have confirmed that supernovae produce dust, the question has lingered about how much of that dust can survive the internal shocks reverberating in the aftermath of the explosion. Seeing this amount of dust at this stage in the lifetimes of SN 2004et and SN 2017eaw suggests that dust can survive the shockwave—evidence that supernovae really are important dust factories after all.

Researchers also note that the current estimations of the mass may be the tip of the iceberg. While Webb has allowed researchers to measure dust cooler than ever before, there may be undetected, colder dust radiating even farther into the electromagnetic spectrum that remains obscured by the outermost layers of dust.

The researchers emphasized that the new findings are also just a hint at newfound research capabilities into supernovae and their dust production using Webb, and what that can tell us about the stars from which they came. 

“There’s a growing excitement to understand what this dust also implies about the core of the star that exploded,” Fox said. “After looking at these particular findings, I think our fellow researchers are going to be thinking of innovative ways to work with these dusty supernovae in the future.”

SN 2004et and SN2017eaw are the first of five targets included in this program. The observations were completed as part of Webb General Observer program 2666. The paper was published in the Monthly Notices of the Royal Astronomical Society on July 5, 2023.

Webb is an international program led by NASA with its partners, European Space Agency (ESA), and Canadian Space Agency (CSA).


Credit: NASA, ESA, CSA, Ori Fox (STScI), Melissa Shahbandeh (STScI)

Image Processing: Alyssa Pagan (STScI)

Release Date: July 5, 2023


#NASA #Astronomy #Space #Science #Galaxies #Galaxy #NGC6496 #Supernovae #SN2004et #SN2017eaw #Dust #Cosmos #Universe #UnfoldTheUniverse #JamesWebb #SpaceTelescope #JWST #ESA #Europe #CSA #Canada #GSFC #STScI #KPNO #UnitedStates #Infographic #STEM #Education

Comet NEOWISE | International Space Station

Comet NEOWISE | International Space Station


In July 2020, comet NEOWISE (short for C/2020 F3 NEOWISE) thrilled skywatchers in North America, in Europe, and in space. It will be approximately 6,800 years before NEOWISE returns to the inner parts of the solar system.

This video shows NEOWISE as viewed from the International Space Station (ISS) on July 5, 2020. An astronaut shot more than 340 photos as the comet rose above the sunlit limb of Earth while the ISS passed over Uzbekistan and central Asia.

In 2020, Comet Neowise had a nucleus measuring roughly 5 kilometers (3 miles) in diameter, and its dust and ion tails stretch hundreds of thousands to millions of kilometers while pointing away from the Sun. The icy visitor was discovered on March 27, 2020, by NASA’s Near-Earth Object Wide-field Infrared Survey Explorer (NEOWISE) spacecraft as the comet was headed toward the Sun. The comet made its closest approach to the Sun on July 3, and then turned back toward the outer solar system.

Comets are made of frozen leftovers from the formation of the solar system roughly 4.6 billion years ago. The masses of dust, rock, and ice heat up when approaching the Sun; as they get closer, they spew gases and dust into a glowing head and tail. Satellite data indicate the NEOWISE has a dust tail and possibly two ionized gas tails. The comet is made visible by sunlight reflecting off of its gas emissions and dust tail.

“It’s quite rare for a comet to be bright enough that we can see it with the naked eye or even just with binoculars,” said Emily Kramer, a co-investigator of the NEOWISE satellite, in a NASA Science Live webcast. “The last time we had a comet this bright was Hale-Bopp back in 1995-1996.”

NEOWISE is expected to make its closest approach to Earth on July 22, passing at a harmless distance of 103 million kilometers (64 million miles). From mid-July onward, viewers can spot the comet after sunset, below the Big Dipper in the northwest sky. For best viewing, make sure to find a spot away from city lights and with a clear view of the sky. While you may be able to see it with your naked eye, you might want to bring binoculars or a small telescope.


Video Credit: ISS Crew Earth Observations Facility and Sara Schmidt of the Earth Science and Remote Sensing Unit, Johnson Space Center

Caption Credit: Kasha Patel

Duration: 22 seconds

Release Date: July 5, 2020


#NASA #Space #Astronomy #Science #ISS #Sun #Earth #Comets #CometNeowise #C2020F3Neowise #SolarSystem #Astronauts #HumanSpaceflight #Expedition63 #JSC #UnitedStates #International #STEM #Education #Timelapse #HD #Video

Comet NEOWISE | International Space Station

Comet NEOWISE | International Space Station

In July 2020, comet NEOWISE (short for C/2020 F3 NEOWISE) thrilled skywatchers in North America, in Europe, and in space. It will be approximately 6,800 years before NEOWISE returns to the inner parts of the solar system.

This photo shows NEOWISE as viewed from the International Space Station (ISS) on July 5, 2020. An astronaut shot more than 340 photos as the comet rose above the sunlit limb of Earth while the ISS passed over Uzbekistan and central Asia.

In 2020, Comet Neowise had a nucleus measuring roughly 5 kilometers (3 miles) in diameter, and its dust and ion tails stretch hundreds of thousands to millions of kilometers while pointing away from the Sun. The icy visitor was discovered on March 27, 2020, by NASA’s Near-Earth Object Wide-field Infrared Survey Explorer (NEOWISE) spacecraft as the comet was headed toward the Sun. The comet made its closest approach to the Sun on July 3, and then turned back toward the outer solar system.

Comets are made of frozen leftovers from the formation of the solar system roughly 4.6 billion years ago. The masses of dust, rock, and ice heat up when approaching the Sun; as they get closer, they spew gases and dust into a glowing head and tail. Satellite data indicate the NEOWISE has a dust tail and possibly two ionized gas tails. The comet is made visible by sunlight reflecting off of its gas emissions and dust tail.

“It’s quite rare for a comet to be bright enough that we can see it with the naked eye or even just with binoculars,” said Emily Kramer, a co-investigator of the NEOWISE satellite, in a NASA Science Live webcast. “The last time we had a comet this bright was Hale-Bopp back in 1995-1996.”

NEOWISE is expected to make its closest approach to Earth on July 22, passing at a harmless distance of 103 million kilometers (64 million miles). From mid-July onward, viewers can spot the comet after sunset, below the Big Dipper in the northwest sky. For best viewing, make sure to find a spot away from city lights and with a clear view of the sky. While you may be able to see it with your naked eye, you might want to bring binoculars or a small telescope.

Astronaut photograph ISS063-E-39888 was acquired on July 5, 2020, with a Nikon D5 digital camera using a focal length of 28 millimeters. The image was taken by members of the Expedition 63 crew. 


Image Credit: ISS Crew Earth Observations Facility and the Earth Science and Remote Sensing Unit, Johnson Space Center

Caption Credit: Kasha Patel

Release Date: July 5, 2020


#NASA #Space #Astronomy #Science #ISS #Sun #Earth #Comets #CometNeowise #C2020F3Neowise #SolarSystem #Astronauts #HumanSpaceflight #Expedition63 #JSC #UnitedStates #International #STEM #Education

A Map of the Observable Universe

A Map of the Observable Universe

What if you could see out to the edge of the observable universe? You would see galaxies, galaxies, galaxies, and then, well, quasars, which are the bright centers of distant galaxies. To expand understanding of the very largest scales that humanity can see, a map of the galaxies and quasars found by the Sloan Digital Sky Survey from 2000 to 2020—out to near the edge of the observable universe—has been composed. Featured here, one wedge from this survey encompasses about 200,000 galaxies and quasars out beyond a look-back time of 12 billion years and cosmological redshift 5. Almost every dot in the nearby lower part of the illustration represents a galaxy, with redness indicating increasing redshift and distance. Similarly, almost every dot on the upper part represents a distant quasar, with blue-shaded dots being closer than red. Clearly shown among many discoveries, gravity between galaxies has caused the nearby universe to condense and become increasingly more filamentary than the distant universe.


Image Credit & Copyright: B. Ménard & N. Shtarkman; Data: SDSS, Planck, JHU, Sloan, NASA, ESA

Sloan Digital Sky Survey Website: 

https://www.sdss.org

Release Date: July 5, 2023


#NASA #Space #Astronomy #Science #Cosmos #Universe #Map #Galaxies #Quasars #SloadDigitalSurvey #Illustration #Infographic #STEM #Education #APoD

Tuesday, July 04, 2023

Frosty Sand Dunes of Mars | NASA's Mars Reconnaissance Orbiter

Frosty Sand Dunes of Mars | NASA's Mars Reconnaissance Orbiter



A field of sand dunes occupies this frosty 5-kilometer diameter crater in the high-latitudes of the northern plains of Mars. Some dunes have separated from the main field and appear to be climbing up the crater slope along a gully-like form.

Black and white images are less than 5 km across; enhanced color images are less than 1 km.

Local Mars time

14:15

Latitude (centered)

76.150°

Longitude (East)

270.545°

Spacecraft altitude

315.8 km (196.3 miles)

The Mars Reconnaissance Orbiter (MRO) is a spacecraft designed to study the geology and climate of Mars, to provide reconnaissance of future landing sites, and to relay data from surface missions back to Earth. It was launched on Aug. 12, 2005, and reached Mars on March 10, 2006.

NASA’s Jet Propulsion Laboratory (JPL), a division of the California Institute of Technology in Pasadena, Calif., manages the Mars Reconnaissance Orbiter for NASA’s Science Mission Directorate, Washington. The HiRISE camera was built by Ball Aerospace and Technology Corporation and is operated by the University of Arizona.

Credit: NASA/JPL/University of Arizona

Image Date: Feb. 17, 2021

Release Date: March 15, 2021


#NASA #Astronomy #Space #Science #Mars #Planet #RedPlanet #Geology #NorthernPlains #SandDunes #Crater #Landscape #Terrain #MRO #HiRISE #Spacecraft #JPL #Caltech #UA #UniversityOfArizona #UnitedStates #SolarSystem #STEM #Education

Frosty Sand Dunes of Mars | NASA's Mars Reconnaissance Orbiter

Frosty Sand Dunes of Mars | NASA's Mars Reconnaissance Orbiter

A field of sand dunes occupies this frosty 5-kilometer diameter crater in the high-latitudes of the northern plains of Mars. Some dunes have separated from the main field and appear to be climbing up the crater slope along a gully-like form.

Black and white images are less than 5 km across; enhanced color images are less than 1 km.

Local Mars time

14:15

Latitude (centered)

76.150°

Longitude (East)

270.545°

Spacecraft altitude

315.8 km (196.3 miles)

The Mars Reconnaissance Orbiter (MRO) is a spacecraft designed to study the geology and climate of Mars, to provide reconnaissance of future landing sites, and to relay data from surface missions back to Earth. It was launched on August 12, 2005, and reached Mars on March 10, 2006.

NASA’s Jet Propulsion Laboratory (JPL), a division of the California Institute of Technology in Pasadena, Calif., manages the Mars Reconnaissance Orbiter for NASA’s Science Mission Directorate, Washington. The HiRISE camera was built by Ball Aerospace and Technology Corporation and is operated by the University of Arizona.

Credit: NASA/JPL/University of Arizona

Image Date: Feb. 17, 2021

Duration: 1 minute

Narration: Tre Gibbs

Release Date: March 15, 2021

#NASA #Astronomy #Space #Science #Mars #Planet #RedPlanet #Geology #NorthernPlains #SandDunes #Crater #Landscape #Terrain #MRO #HiRISE #Spacecraft #JPL #Caltech #UA #UniversityOfArizona #UnitedStates #SolarSystem #STEM #Education #HD #Video

Smoke from Wildfires in Canada Reaches Europe | NASA Terra Earth Satellite

Smoke from Wildfires in Canada Reaches Europe | NASA Terra Earth Satellite




Smoke from wildland fires, which have been burning in the Canadian province of Quebec for weeks, has crossed the Atlantic Ocean and darkened skies in southwestern Europe.

The Moderate Resolution Imaging Spectroradiometer (MODIS) on NASA’s Terra satellite acquired this image in the morning (11:10 Universal Time) on June 26, 2023. At the time, smoke drifted over northern Portugal and Spain. It also reached northward over other European countries beyond the scope of this image.

The smoke’s widespread reach is apparent in the map above. It shows a plume of black carbon particles—commonly called soot—spanning eastward from North America and across more than 2,000 miles of the Atlantic Ocean. The black carbon density data come from NASA’s GEOS forward processing (GEOS-FP) model, which assimilates data from satellite, aircraft, and ground-based observing systems. In addition to making use of satellite observations of aerosols and fires, GEOS-FP incorporates meteorological data like air temperature, moisture, and winds to project the plume’s behavior.

Hazy skies in Europe were also observed by a global network of ground sensors called the Aerosols Robotic Network, or AERONET. The network contains more than 500 Sun photometer instruments that measure aerosol optical depth (AOD) around the world. On the morning of June 26, AERONET sensors in northern Spain and France measured AODs greater than 0.5. The AOD in these areas is typically close to 0.1. (For reference, a perfectly clear sky would have an AOD of less than 0.05, while an AOD of 3 would make it difficult to see the Sun.)

Yet air quality in the smoke-covered parts of Europe on June 26 remained mostly fair, compared to unhealthy and hazardous air quality in the smoke-affected parts of Canada and the United States. This is because most of the smoke that reached Europe was higher in the atmosphere, where it is less likely to affect human health.

Still, the smoke over Europe will likely be noticed by people. According to the UK Met Office, the smoke aerosols could contribute to vivid sunrises and sunsets.


Image Credit: NASA Earth Observatory images by Lauren Dauphin, using MODIS data from NASA EOSDIS LANCE and GIBS/Worldview and GEOS-5 data from the Global Modeling and Assimilation Office at NASA GSFC 

Story Credit: Kathryn Hansen

Image Date: June 26, 2023

Release Date: June 27, 2023


#NASA #Space #Satellites #TerraSatellite #Science #Earth #Planet #Canada #Ontario #Quebec #Wildfires #Smoke #AtlanticOcean #Portugal #Spain #ClimateChange #GlobalWarming #GlobalHeating #Atmosphere #AirQuality #Weather #Meteorology #EarthObservation #RemoteSensing #GSFC #UnitedStates #STEM #Education

Aurora Borealis over Icelandic Waterfall

Aurora Borealis over Icelandic Waterfall

Cari Letelier: "It seemed like the sky exploded. The original idea was to photograph an aurora over a waterfall. After waiting for hours under opaque clouds, though, hope was running out. Others left. Then, unexpectedly, the clouds moved away. Suddenly, particles from a large solar magnetic storm were visible impacting the Earth's upper atmosphere with full effect. The night sky filled with colors and motion in a thrilling auroral display. Struggling to steady the camera from high Earthly winds, the 34 exposures that compose the featured image were taken. The resulting featured composite image shows the photogenic Godafoss (Goðafoss) waterfall in northern Iceland in front of a very active aurora in late February." 

"The solar surface explosion that expelled the energetic particles occurred a few days before. Our Sun is showing an impressive amount of surface activity as it approaches solar maximum, indicating that more impressive auroras are likely to appear in Earth's northern and southern sky over the next few years."


Image Credit & Copyright: Cari Letelier

Cari's Instagram Page: 

https://www.instagram.com/cariletelier/

Release Date: July 4, 2023


#NASA #Space #Astronomy #Science #Earth #Planet #Atmosphere #Aurora #AuroraBorealis #MagneticField #Magnetosphere #SolarWind #Sun #Iceland #Ísland #GodafossWaterfall #GoðafossWaterfall #CariLetelier #Photography #Astrophotography #CitizenScience #STEM #Education #APoD

Star AB Aurigae & Reflection Nebula vdB31: Wide-field View | ESO

Star AB Aurigae & Reflection Nebula vdB31: Wide-field View | ESO

This wide-field view shows the region of the sky, in the constellation of Auriga, where AB Aurigae and reflection nebula vdB31 can be found. This view was created from images forming part of the Digitized Sky Survey 2.

Credit: ESO/Digitized Sky Survey 2

Acknowledgement: Davide De Martin

Release Date: May 20, 2020


#NASA #ESO #Astronomy #Space #Stars #Nebulae #Nebula #ReflectionNebula #vdB31 #Star #ABAurigae #Auriga #Constellation #MilkyWayGalaxy #Cosmos #Universe #Chile #SouthAmerica #Europe #STEM #Education

Happy July Fourth! Pan over Celestial Fireworks in Galaxy NGC 1569 | Hubble

Happy July Fourth! Pan over Celestial Fireworks in Galaxy NGC 1569 | Hubble

The nearby dwarf galaxy NGC 1569 is a hotbed of vigorous star birth activity which blows huge bubbles and super-bubbles that riddle the main body of the galaxy. The galaxy's vigorous star factories are also manufacturing brilliant blue star clusters. This galaxy had a sudden and relatively recent onset of star birth 25 million years ago, which subsided about the time the very earliest human ancestors appeared on Earth.

In this image, taken with the NASA/European Space Agency Hubble Space Telescope, the bubble structure is sculpted by the galactic super-winds and outflows caused by a colossal input of energy from collective supernova explosions that are linked with a massive episode of star birth.The bubble-like structures seen in this image are made of hydrogen gas that glows when hit by the fierce winds and radiation from hot young stars and is racked by supernovae shocks. The first supernovae blew up when the most massive stars reached the end of their lifetimes roughly 20-25 million years ago. The environment in NGC 1569 is still turbulent and the supernovae may not only deliver the gaseous raw material needed for the formation of further stars and star clusters, but also actually trigger their birth in the tortured swirls of gas.


Credit: European Space Agency (ESA)/Hubble (M. Kornmesser & L. L. Christensen)

Duration: 24 seconds

Release Date: Oct. 24, 2017


#NASA #ESA #Astronomy #Space #FourthOfJuly #Science #Galaxy #DwarfGalaxy #NGC1569 #Stars #StarClusters #Supernovae #Camelopardalis #Constellation #Cosmos #Universe #SpaceTelescope #GSFC #STScI #UnitedStates #Europe #STEM #Education #HD #Video

Happy Fourth of July! Celestial Fireworks in Starburst Galaxy NGC 1569 | Hubble

Happy Fourth of July! Celestial Fireworks in Starburst Galaxy NGC 1569 | Hubble


This NASA/European Space Agency Hubble Space Telescope image reveals the iridescent interior of one of the most active galaxies in our local neighborhood—NGC 1569, a small galaxy located about eleven million light-years away in the constellation of Camelopardalis (The Giraffe).

Distance: 11 million light years

This galaxy is currently a hotbed of vigorous star formation. NGC 1569 is a starburst galaxy, meaning that—as the name suggests—it is bursting at the seams with stars, and is currently producing them at a rate far higher than that observed in most other galaxies. For almost 100 million years, NGC 1569 has pumped out stars over 100 times faster than the Milky Way!

As a result, this glittering galaxy is home to super star clusters, three of which are visible in this image—one of the two bright clusters is actually  the superposition of two massive clusters. Each containing more than a million stars, these brilliant blue clusters reside within a large cavity of gas carved out by multiple supernovae, the energetic remnants of massive stars.

In 2008, Hubble observed the galaxy's cluttered core and sparsely populated outer fringes. By pinpointing individual red giant stars, Hubble’s Advanced Camera for Surveys enabled astronomers to calculate a new—and much more precise—estimate for NGC 1569’s distance. This revealed that the galaxy is actually one and a half times further away than previously thought, and a member of the IC 342 galaxy group.

Astronomers suspect that the IC 342 cosmic congregation is responsible for the star-forming frenzy observed in NGC 1569. Gravitational interactions between this galactic group are believed to be compressing the gas within NGC 1569. As it is compressed, the gas collapses, heats up and forms new stars.


Credit: European Space Agency (ESA)/Hubble & NASA, Aloisi, Ford

Acknowledgement: Judy Schmidt (Geckzilla)

Release Date: June 27, 2016


#NASA #ESA #Astronomy #Space #Science #Galaxy #DwarfGalaxy #NGC1569 #Stars #StarClusters #Supernovae #Camelopardalis #Constellation #Cosmos #Universe #HST #SpaceTelescope #GSFC #STScI #UnitedStates #Europe #STEM #Education