The International Space Station orbits toward the sun to experience one of the 16 sunrises the crew has every day. | July 31, 2017: On July 26, 2017, a member of the Expedition 52 crew aboard the International Space Station took this photograph of one of the 16 sunrises they experience every day, as the orbiting laboratory travels around Earth. One of the solar panels that provides power to the station is seen in the upper left.
The station's solar arrays produce more power than it needs at one time for station systems and experiments. When the station is in sunlight, about 60 percent of the electricity that the solar arrays generate is used to charge the station's batteries. The batteries power the station when it is not in the Sun.
Credit: NASARelease Date: July 31, 2017#NASA #ISS #Earth #Science #Sunrise #MondayMotivation #Solar#SolarPanels #SolarArrays #Renewable #Energy #EarthObservation#Astronauts #Cosmonauts #Human #Spaceflight #Expedition52#UnitedStates #JSC #STEM
#Education
This image from the Wide-Field Imager on the MPG/ESO 2.2-meter telescope shows the starry skies around a galaxy cluster named PLCKESZ G286.6-31.3. The cluster itself is difficult to spot initially, but shows up as a subtle clustering of yellowish galaxies near the centre of the frame.
PLCKESZ G286.6-31.3 houses up to 1000 galaxies, in addition to large quantities of hot gas and dark matter. As such, the cluster has a total mass of 530 trillion (530 000 000 000 000) times the mass of the Sun.
When viewed from Earth, PLCKESZ G286.6-31.3 is seen through the outer fringes of the Large Magellanic Cloud (LMC)—one of the Milky Way’s satellite galaxies. The LMC hosts over 700 star clusters, in addition to hundreds of thousands of giant and supergiant stars. The majority of the cosmic objects captured in this image are stars and star clusters located inside the LMC.
The MPG/ESO 2.2-meter telescope has been in operation at ESO’s La Silla Observatory since 1984. The telescope has been utilized for a variety of cutting-edge scientific studies, including ground-breaking research into gamma-ray bursts, the most powerful explosions in the Universe. The 67-million-pixel Wide Field Imager (WFI)—mounted on the telescope’s Cassegrain focus—has been obtaining detailed views of faint, distant objects since 1999.
The data to create this image was selected from the ESO archive as part of the Hidden Treasures competition.
Credit: European Southern Observatory (ESO)
Acknowledgements: Flickr user hdahle70
Release Date: July 31, 2017#ESO #Astronomy #Science #Space #Galaxy #PLCKESZG2866313 #Magellanic #Cloud #LMC #Star #Clusters #Mensa #Cosmos #Universe #LaSilla #Observatory #Chile #Atacama #SouthAmerica #Europe #STEM #Education
The star of this Hubble Picture of the Week is a galaxy known as NGC 4656, located in the constellation of Canes Venatici (The Hunting Dogs). However, it also has a somewhat more interesting and intriguing name: the Hockey Stick Galaxy! The reason for this is a little unclear from this partial view, which shows the bright central region, but the galaxy is actually shaped like an elongated, warped stick, stretching out through space until it curls around at one end to form a striking imitation of a celestial hockey stick.
This unusual shape is thought to be due to an interaction between NGC 4656 and a couple of near neighbors, NGC 4631 (otherwise known as The Whale Galaxy) and NGC 4627 (a small elliptical). Galactic interactions can completely reshape a celestial object, shifting and warping its constituent gas, stars, and dust into bizarre and beautiful configurations. The NASA/ESA Hubble Space Telescope has spied a large number of interacting galaxies over the years, from the cosmic rose of Arp 273 to the egg-penguin duo of Arp 142 and the pinwheel swirls of Arp 240. More Hubble images of interacting galaxies can be seen here.
Credit: ESA/Hubble & NASA
Release Date: July 31, 2017#NASA #Hubble #Astronomy #Science #Space #Galaxy #HockeyStick #NGC4656 #CanesVenatici #Cosmos #Universe #Telescope #ESA #GSFC #Goddard #STScI #STEM #Education
July 27, 2017: This image of Jupiter’s iconic Great Red Spot was created by citizen scientist Björn Jónsson using data from the JunoCam imager on NASA’s Juno spacecraft.
This true-color image offers a natural color rendition of what the Great Red Spot and surrounding areas would look like to human eyes from Juno’s position. The tumultuous atmospheric zones in and around the Great Red Spot are clearly visible.
The image was taken on July 10, 2017 at 07:10 p.m. PDT (10:10 p.m. EDT), as the Juno spacecraft performed its seventh close flyby of Jupiter. At the time the image was taken, the spacecraft was about 8,648 miles (13,917 kilometers) from the tops of the clouds of the planet at a latitude of -32.6 degrees.
JunoCam's raw images are available for the public to peruse and process into image products at: www.missionjuno.swri.edu/junocam
Credit: NASA/JPL-Caltech/SwRI/MSSS/Björn Jónsson
Release Date: July 27, 2017#NASA #Astronomy #Space #Science #Jupiter #Planet #Atmosphere #GreatRedSpot #GRS #Juno #Spacecraft #SwRI #JPL #Pasadena #California #UnitedStates #STEM #Education
#CitizenScience
July 27, 2017: Using new observations from ESO’s VLT Survey Telescope, astronomers have discovered three different populations of young stars within the Orion Nebula Cluster. This unexpected discovery adds very valuable new insights for the understanding of how such clusters form. It suggests that star formation might proceed in bursts, where each burst occurs on a much faster time-scale than previously thought.
OmegaCAM—the wide-field optical camera on ESO’s VLT Survey Telescope (VST)—has captured the spectacular Orion Nebula and its associated cluster of young stars in great detail, producing a beautiful new image. This object is one of the closest stellar nurseries for both low and high-mass stars, at a distance of about 1350 light-years [1].
But this is more than just a pretty picture. A team led by ESO astronomer Giacomo Beccari has used these data of unparallelled quality to precisely measure the brightness and colors of all the stars in the Orion Nebula Cluster. These measurements allowed the astronomers to determine the mass and ages of the stars. To their surprise, the data revealed three different sequences of potentially different ages.
“Looking at the data for the first time was one of those ‘Wow!’ moments that happen only once or twice in an astronomer's lifetime,” says Beccari, lead author of the paper presenting the results. “The incredible quality of the OmegaCAM images revealed without any doubt that we were seeing three distinct populations of stars in the central parts of Orion.”
Monika Petr-Gotzens, co-author and also based at ESO Garching, continues, “This is an important result. What we are witnessing is that the stars of a cluster at the beginning of their lives didn’t form altogether simultaneously. This may mean that our understanding of how stars form in clusters needs to be modified.”
The astronomers looked carefully at the possibility that instead of indicating different ages, the different brightnesses and colours of some of the stars were due to hidden companion stars, which would make the stars appear brighter and redder than they really were. But this idea would imply quite unusual properties of the pairs, which have never before been observed. Other measurements of the stars, such as their rotation speeds and spectra, also indicated that they must have different ages [2].
“Although we cannot yet formally disprove the possibility that these stars are binaries, it seems much more natural to accept that what we see are three generations of stars that formed in succession, within less than three million years,” concludes Beccari.
The new results strongly suggest that star formation in the Orion Nebula Cluster is proceeding in bursts, and more quickly than had been previously thought.
Notes
[1] The Orion Nebula has been studied by many of ESO’s telescopes, including images in visible light from the MPG/ESO 2.2-meter telescope (eso1103) and infrared images from VISTA (eso1701) and the HAWK-I instrument on the Very Large Telescope (eso1625).
[2] The group also found that each of the three different generations rotate at different speeds — the youngest stars rotate the fastest, and the oldest stars rotate the slowest. In this scenario, the stars would have formed in quick succession, within a time frame of three million years.
Research paper
https://www.eso.org/public/archives/releases/sciencepapers/eso1723/eso1723a.pdf
Credit: ESO/G. Beccari
Release Date: July 27, 2017#ESO #Astronomy #Science #Space #Nebula #Orion #Star #Cluster #Cosmos #Universe #Telescope #VLT #OmegaCAM #STEM #Education
July 27, 2017: The gravitational dance between two galaxies in our local neighborhood has led to intriguing visual features in both as witnessed in this new NASA/ESA Hubble Space Telescope image. The tiny NGC 1510 and its colossal neighbor NGC 1512 are at the beginning of a lengthy merger, a crucial process in galaxy evolution. Despite its diminutive size, NGC 1510 has had a significant effect on NGC 1512’s structure and amount of star formation.
Galaxies come in a range of shapes and sizes, and astronomers use this fact to classify them based on their appearance. NGC 1512, the large galaxy to the left in this image, is classified as a barred spiral, named after the bar composed of stars, gas and dust slicing through its centre. The tiny NGC 1510 to the right, on the other hand, is a dwarf galaxy. Despite their very different sizes, each galaxy affects the other through gravity, causing slow changes in their appearances.
The bar in NGC 1512 acts as a cosmic funnel, channelling the raw materials required for star formation from the outer ring into the heart of the galaxy. This pipeline of gas and dust in NGC 1512 fuels intense star birth in the bright, blue, shimmering inner disc known as a circumnuclear starburst ring, which spans 2400 light-years.
Both the bar and the starburst ring are thought to be at least in part the result of the cosmic scuffle between the two galaxies—a merger that has been going on for 400 million years.
NGC 1512, which has been observed by Hubble in the past, is also home to a second, more serene, star-forming region in its outer ring. This ring is dotted with dozens of HII regions, where large swathes of hydrogen gas are subject to intense radiation from nearby, newly formed stars. This radiation causes the gas to glow and creates the bright knots of light seen throughout the ring.
Remarkably, NGC 1512 extends even further than we can see in this image—beyond the outer ring—displaying malformed, tendril-like spiral arms enveloping NGC 1510. These huge arms are thought to be warped by strong gravitational interactions with NGC 1510 and the accretion of material from it. But these interactions are not just affecting NGC 1512; they have also taken their toll on the smaller of the pair.
The constant tidal tugging from its neighbor has swirled up the gas and dust in NGC 1510 and kick-started star formation that is even more intense than in NGC 1512. This causes the galaxy to glow with the blue hue that is indicative of hot new stars.
NGC 1510 is not the only galaxy to have experienced the massive gravitational tidal forces of NGC 1512. Observations made in 2015 showed that the outer regions of the spiral arms of NGC 1512 were indeed once part of a separate, older galaxy. This galaxy was ripped apart and absorbed by NGC 1512, just as it is doing now to NGC 1510.
Together, the pair demonstrate how interactions between galaxies, even if they are of very different sizes, can have a significant influence on their structures, changing the dynamics of their constituent gas and dust and even triggering starbursts. Such interactions between galaxies, and galaxy mergers in particular, play a key role in galactic evolution.
Credit: NASA, ESA
Release Date: July 27, 2017#NASA #Hubble #Astronomy #Science #Space #Galaxy #NGC1510 #NGC1512 #Galaxies #Cosmos #Universe #Telescope #ESA #STScI #Goddard #GSFC #STEM #Education
Image: Soyuz spacecraft at launchpad
July 26, 2017: The Soyuz MS-05 spacecraft is seen as it is raised into a vertical position on the launch pad at the Baikonur Cosmodrome, Kazakhstan, Wednesday, July 26, 2017. Expedition 52 flight engineer Sergei Ryazanskiy of Roscosmos, flight engineer Randy Bresnik of NASA, and flight engineer Paolo Nespoli of ESA (European Space Agency), are scheduled to launch to the International Space Station aboard the Soyuz spacecraft from the Baikonur Cosmodrome on Friday, July 28, at 11:41 a.m. EDT (9:41 p.m. Baikonur time).
Credit: NASA/Joel Kowsky
Release Date: July 26, 2017#NASA #ISS #Earth #Science #Soyuz #Rocket #SoyuzMS05 #Spacecraft #Cosmonaut #Commander #SergeyRyazanskiy #Astronaut #Astronauts #PaoloNespoli #RandyBresnik #ASI #ESA #Europe #Russia #Россия #Baikonur #Cosmodrome #Kazakhstan #Human #Spaceflight #Expedition52 #UnitedStates #JSC #STEM
#Education
In the heart of baseball season, NASA completed its equivalent of a clean inning, successfully testing the third RS-25 flight controller for use on the new Space Launch System (SLS) deep space rocket. Engineers conducted a 500-second test of RS-25 Engine Controller Unit No. 5 on the A-1 Test Stand at NASA’s Stennis Space Center near Bay St. Louis, Mississippi, July 25, 2017. The test involved installing the controller unit on an RS-25 development engine and firing it in the same manner, and for the same length of time, as needed during launch.
With this latest test, NASA continues to set the stage for deep-space exploration missions, achieving another milestone toward launch of the first integrated flight of SLS and the Orion spacecraft, known as Exploration Mission-1. SLS will be powered at launch by four RS-25 engines, firing simultaneously to provide 2 million pounds of thrust and working in conjunction with a pair of solid rocket boosters to produce up to 8 million pounds of thrust. The four RS-25 engines for the initial flight are former space shuttle main engines, modified to perform at a higher thrust level and with new controllers. The controller is the key modification to the engines and is characterized as the “brain” that provides precision control of engine operation and internal health diagnostics, and allows communication between the RS-25 engine and the SLS. During launch and flight, the controller communicates with the SLS flight computers, receiving critical commands and returning engine health and status data. Early tests at Stennis provided critical data for development of the new controller by NASA, RS-25 prime contractor Aerojet Rocketdyne and subcontractor Honeywell.
NASA tested the first flight controller on the A-1 Test Stand at Stennis in March. The second flight controller was tested in May. Following review of test data, both controllers were designated for use on RS-25 engines that will power the SLS launch. RS-25 tests at Stennis are conducted by a team of NASA, Aerojet Rocketdyne and Syncom Space Services engineers and operators. Aerojet Rocketdyne is the RS-25 prime contractor. Syncom Space Services is the prime contractor for Stennis facilities and operations.
Image Credit: NASA
Release Date: July 25, 2017#NASA #Space #Rocket #SLS #Engine #RS25 #Mars #SpaceLaunchSystem #JourneyToMars #DeepSpace #Propulsion #Engineering #Technology #Stennis #Mississippi #USA #UnitedStates #Marshall #AerojetRocketdyne #Asteroid #Moon #Lunar
#Exploration #STEM #Education
Hilary is a small but strengthening hurricane, with hurricane-force winds extending outward up to 10 miles (20 km) from the center. Tropical-storm-force winds extending outward up to 60 miles (95 km).
Hilary began when Tropical Depression 9E formed on July 21. By July 22 at 11 p.m. EDT, the depression strengthened into a tropical storm and was re-named Hilary. At 5 a.m. EDT on Monday, July 24, 2017, Hilary rapidly intensified into a hurricane.
NASA's Moderate Resolution Imaging Spectroradiometer, or MODIS, instrument aboard NASA’s Terra satellite captured a true color image of Hurricane Hilary on July 24 at 11 a.m. EDT. The image revealed a better organized tropical cyclone. The National Hurricane Center (NHC) noted "Satellite images indicate that Hilary has a small central core of convection, with both the visible and infrared channels suggesting that an eye is trying to form. Microwave data also show an incomplete eyewall."
At 11 a.m. EDT (1500 UTC), the center of Hurricane Hilary was located near 14.1 degrees north latitude and 104.2 degrees west longitude. That's about 340 miles (545 km) south of Manzanillo, Mexico. Hilary is moving toward the west-northwest near 8 mph (13 kph), and the National Hurricane Center said this general motion with some increase in forward speed is expected over the next 48 hours. Maximum sustained winds have increased to near 80 mph (130 kph) with higher gusts. The estimated minimum central pressure is 989 millibars.
The National Hurricane Center expects Hilary to become a major hurricane on Tuesday, July 25.
For updated forecasts, visit: www.nhc.noaa.gov
Credit: NASA
Release Date: July 24, 2017#NASA #Earth #Science #Satellite #Space #Hurricane #Hilary #Pacific #Ocean #Mexico #EarthObservation #Aqua #MODIS #Goddard #GSFC #UnitedStates #STEM #Education
Numerous arches of magnetic field lines danced and swayed above a large active region over about a 30-hour period (July 17-18, 2017). We can also see the magnetic field lines from the large active region reached out and connected with a smaller active region. Those linked lines then strengthened (become brighter), but soon began to develop a kink in them and rather swiftly faded from view. All of this activity is driven by strong magnetic forces associated with the active regions. The images were taken in a wavelength of extreme ultraviolet light.
Credit: Solar Dynamics Observatory, NASA
Capture Date: July 17, 2017
Release Date: July 24, 2017#NASA #Astronomy #Science #Space #Sun #Solar #Magnetic #Loops #ActiveRegion #Magnetism #Physics #Astrophysics #Ultraviolet #SDO #GSFC #Goddard #STEM #Education
In the Integration Facility at the Baikonur Cosmodrome in Kazakhstan, the Expedition 52-53 prime and backup crews pose for pictures in front of the first stage engines of the Soyuz booster rocket July 24 as part of their final fit check dress rehearsal. From left to right are prime crewmembers Paolo Nespoli of the European Space Agency, Sergey Ryazanskiy of the Russian Federal Space Agency (Roscosmos) and Randy Bresnik of NASA and backup crew members Norishige Kanai of the Japan Aerospace Exploration Agency (JAXA), Alexander Misurkin of Roscosmos and Mark Vande Hei of NASA. Nespoli, Bresnik and Ryazanskiy will launch July 28 aboard the Soyuz MS-05 spacecraft for a five-month mission on the International Space Station.
Credit: Andrey Shelepin/Gagarin Cosmonaut Training Center
Image Date: July 24, 2017#NASA #ISS #Earth #Science #Cosmonauts #Soyuz #Commander #SergeyRyazanskiy #AlexanderMisurkin #Astronauts #NorishigeKanai #Japan #日本 #JAXA #MarkVandeHei #PaoloNespoli #RandyBresnik #ASI #ESA #Europe #Russia #Россия #Baikonur #Cosmodrome #Kazakhstan #Human #Spaceflight #Expedition52 #UnitedStates #JSC #STEM
#Education
This beautiful clump of glowing gas, dark dust, and glittering stars is the spiral galaxy NGC 4248, located about 24 million light-years away in the constellation of Canes Venatici (The Hunting Dogs).
This image was produced by the NASA/ESA Hubble Space Telescope as it embarked upon compiling the first Hubble ultraviolet “atlas”, for which the telescope targeted 50 nearby star-forming galaxies. A sample spanning all kinds of different morphologies, masses, and structures. Studying this sample can help us to piece together the star-formation history of the Universe.
By exploring how massive stars form and evolve within such galaxies, astronomers can learn more about how, when, and where star formation occurs, how star clusters change over time, and how the process of forming new stars is related to the properties of both the host galaxy and the surrounding interstellar medium (the “stuff” that fills the space between individual stars).
This image is formed of observations from Hubble’s Wide Field Camera 3.
Credit: ESA/Hubble & NASA
Release Date: July 24, 2017#NASA #Hubble #Astronomy #Science #Space #Galaxy #Spiral #NGC4248 #CanesVenatici #Cosmos #Universe #Telescope #Goddard #GSFC #STScI #STEM #Education
Approximately 95 million light-years away, in the southern constellation of Octans (The Octant), lies NGC 7098—an intriguing spiral galaxy with numerous sets of double features. The first of NGC 7098’s double features is a duo of distinct ring-like structures that loop around the galaxy’s hazy heart. These are NGC 7098’s spiral arms, which have wound themselves around the galaxy’s luminous core. This central region hosts a second double feature: a double bar.
NGC 7098 has also developed features known as ansae, visible as small, bright streaks at each end of the central region. Ansae are visible areas of overdensity—they commonly take looping, linear, or circular shapes, and can be found at the extremities of planetary ring systems, in nebulous clouds, and, as is the case with NGC 7098, in parts of galaxies that are packed to the brim with stars.
This image is formed from data gathered by the FOcal Reducer and low dispersion Spectrograph (FORS) instrument, installed on ESO’s Very Large Telescope at Paranal Observatory. An array of distant galaxies are also visible throughout the frame, the most prominent being the small, edge-on, spiral galaxy visible to the left of NGC 7098, known as ESO 048-G007.
Credit: European Southern Observatory (ESO)
Release Date: July 24, 2017#ESO #Astronomy #Science #Space #Galaxy #Spiral #Ansae #NGC7098 #Octans #Cosmos #Universe #VLT #Telescope #Paranal #Observatory #Chile #SouthAmerica #STEM #Education
July 20, 2017: While photographing Mars, NASA’s Hubble Space Telescope captured a cameo appearance of the tiny moon Phobos on its trek around the Red Planet. Discovered in 1877, the diminutive, potato-shaped moon is so small that it appears star-like in the Hubble pictures. Phobos orbits Mars in just 7 hours and 39 minutes, which is faster than Mars rotates. The moon’s orbit is very slowly shrinking, meaning it will eventually shatter under Mars’ gravitational pull, or crash into the planet.
Credit: NASA, ESA, and Z. Levay (STScI)
Release Date: July 20, 2017#NASA #Hubble #Astronomy #Science #Mars #Planet #Moon #Phobos #RedPlanet #SolarSystem #Exploration #Space #Telescope #ESA #Goddard #GSFC #STScI #Astrophotography #Timelapse #STEM #Education
NASA's Aqua satellite passed over the Eastern Pacific Ocean's Hurricane Fernanda as it continued to track toward the Central Pacific. The storm continues to move over cooler waters and is on a weakening trend.
The storm's eye is now cloud-filled.
July 18, 2017: On July 17 at 6:10 p.m. EDT (2210 UTC) the Moderate Resolution Imaging Spectroradiometer or MODIS instrument aboard NASA's Aqua satellite provided a visible picture of Fernanda. The image revealed strong thunderstorms continued to circle the low-level center of circulation, and the eye of the storm had become filled in from clouds.
At 5 a.m. EDT (0900 UTC), the center of Hurricane Fernanda was located near 15.4 degrees north latitude and 132.8 degrees west longitude. That's about 1,495 miles (2,410 km) east of Hilo, Hawaii. Fernanda was moving toward the northwest near 9 mph (15 kph) and this general motion is expected during the next day or so. A turn to the west-northwest is expected on Wednesday. The estimated minimum central pressure is 971 millibars.
Maximum sustained winds are near 105 mph (165 kph) with higher gusts. Continued gradual weakening is forecast during the next couple of days.
For updated forecasts, visit: www.nhc.noaa.gov
Credit: NASA Goddard MODIS Rapid Response
Release Date: July 18, 2017#NASA #Earth #Science #Satellite #Weather #Storm #Hurricane #Pacific #Ocean #Aqua #MODIS #GSFC #Goddard #NOAA #STEM #Education
A flare medium-sized (M2) flare and a coronal mass ejection erupted from the same, large active region (July 14, 2017). The flare lasted almost two hours, quite a long duration. Coronagraphs on the SOHO spacecraft show a substantial cloud of charged particles blasting into space just after the blast. The coils arcing over this active region are particles spiraling along magnetic field lines, which were reorganizing themselves after the magnetic field was disrupted by the blast. Images were taken in a wavelength of extreme ultraviolet light.
Credit: Solar Dynamics Observatory, NASA
Image Date: July 14, 2017
Release Date: July 17, 2017#NASA #Astronomy #Science #Space #Sun #Solar #Flare #M2 #SolarFlare #CME #Magnetic #Loops #Magnetism #Physics #Astrophysics #Ultraviolet #SDO #SOHO #GSFC #Goddard #STEM #Education
#France #BastilleDay
