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Tuesday, February 06, 2018
SpaceX Falcon Heavy's Historic Blastoff!
Congratulations to Team SpaceX & Elon Musk!
"Falcon Heavy is the most powerful operational rocket in the world by a factor of two. With the ability to lift into orbit nearly 64 metric tons (141,000 lb)—a mass greater than a 737 jetliner loaded with passengers, crew, luggage and fuel—Falcon Heavy can lift more than twice the payload of the next closest operational vehicle, the Delta IV Heavy, at one-third the cost. Falcon Heavy draws upon the proven heritage and reliability of Falcon 9."
"Its first stage is composed of three Falcon 9 nine-engine cores whose 27 Merlin engines together generate more than 5 million pounds of thrust at liftoff, equal to approximately eighteen 747 aircraft. Only the Saturn V moon rocket, last flown in 1973, delivered more payload to orbit. Falcon Heavy was designed from the outset to carry humans into space and restores the possibility of flying missions with crew to the Moon or Mars."
Steve Jurvetson: "Success!!!! I was so excited while taking these photos! Congrats SpaceX for your persistence of vision and bold mission to change the worlds!!!"
Learn more: www.spacex.com/falcon-heavy
Image & Caption Credit: Steve Jurvetson
Image Date: February 6, 2018
#SpaceX #ElonMusk #Mars #JourneyToMars #NASA #Science #Technology #Engineering #KSC #Kennedy #UnitedStates #History #Apollo #SolarSystem #Exploration #Moon
Monday, October 30, 2017
Antares & The Milky Way | ESO
Brilliant blue stars litter the southern sky and the galactic bulge of our home galaxy, the Milky Way, hangs serenely above the horizon in this spectacular shot of ESO’s Paranal Observatory.
This image was taken atop Cerro Paranal in Chile, home to ESO’s Very Large Telescope (VLT). In the foreground, the open dome of one of the four 1.8-meter Auxiliary Telescopes can be seen. The four Auxiliary Telescopes can be utilized together, to form the Very Large Telescope Interferometer (VLTI).
The plane of the Milky Way is dotted with bright regions of hot gas. The very bright star towards the upper left corner of the frame is Antares—the brightest star in Scorpius and the fifteenth brightest star in the night sky.
Credit: ESO/B. Tafreshi (twanight.org)
Release Date: October 30, 2017
#ESO #Astronomy #Science #Space #Galaxy #MilkyWay #Antares #Cosmos #Universe #Paranal #Observatory #CerroParanal #Chile #SouthAmerica #Astrophotography #Photography #STEM #Education
Abell’s richest cluster | Hubble Space Telescope
The Universe contains some truly massive objects. Although we are still unsure how such gigantic things come to be, the current leading theory is known as hierarchical clustering, whereby small clumps of matter collide and merge to grow ever larger. The 14-billion-year history of the Universe has seen the formation of some enormous cosmic structures, including galaxy groups, clusters, and superclusters—the largest known structures in the cosmos!
This particular cluster is called Abell 665. It was named after its discoverer, George O. Abell, who included it in his seminal 1958 cluster catalog. Abell 665 is located in the well-known northern constellation of Ursa Major (The Great Bear). This incredible image combines visible and infrared light gathered by the NASA/ESA Hubble Space Telescope using two of its cameras: the Advanced Camera for Surveys and the Wide Field Camera 3.
Abell 665 is the only galaxy cluster in Abell’s entire catalog to be given a richness class of 5, indicating that the cluster contains at least 300 individual galaxies. Because of this richness, the cluster has been studied extensively at all wavelengths, resulting in a number of fascinating discoveries—among other research, Abell 665 has been found to host a giant radio halo, powerful shockwaves, and has been used to calculate an updated value for the Hubble constant (a measure of how fast the Universe is expanding).
Credit: ESA/Hubble & NASA
Release Date: October 30, 2017
#NASA #Hubble #Astronomy #Science #Space #Abell665 #Cluster #Cosmos #Universe #UrsaMajor #Telescope #ESA #Goddard #GSFC #STScI #STEM #Education
This particular cluster is called Abell 665. It was named after its discoverer, George O. Abell, who included it in his seminal 1958 cluster catalog. Abell 665 is located in the well-known northern constellation of Ursa Major (The Great Bear). This incredible image combines visible and infrared light gathered by the NASA/ESA Hubble Space Telescope using two of its cameras: the Advanced Camera for Surveys and the Wide Field Camera 3.
Abell 665 is the only galaxy cluster in Abell’s entire catalog to be given a richness class of 5, indicating that the cluster contains at least 300 individual galaxies. Because of this richness, the cluster has been studied extensively at all wavelengths, resulting in a number of fascinating discoveries—among other research, Abell 665 has been found to host a giant radio halo, powerful shockwaves, and has been used to calculate an updated value for the Hubble constant (a measure of how fast the Universe is expanding).
Credit: ESA/Hubble & NASA
Release Date: October 30, 2017
#NASA #Hubble #Astronomy #Science #Space #Abell665 #Cluster #Cosmos #Universe #UrsaMajor #Telescope #ESA #Goddard #GSFC #STScI #STEM #Education
Friday, October 27, 2017
Here Comes The Sun | International Space Station
Cosmonaut Sergey Ryazanskiy: "We see 16 sunsets every day, here's just one of them // Так выглядел один из 16 уникальных закатов, которые наш экипаж наблюдает за сутки."
Credit: Roscosmos, Cosmonaut Сергей Рязанский
Release Date: October 23, 2017
#NASA #ISS #Earth #Science #Sun #Sunshine #Sunset #EarthObservation #Cosmonaut #FlightEngineer #SergeyRyazanskiy #космонавт #Роскосмос #Roscosmos #Russia #Россия #Human #Spaceflight #Expedition53 #UnitedStates #JSC #STEM #Education
Monday, October 23, 2017
Our gleaming Milky Way
This image taken at Paranal shows our beautifully gleaming Milky Way galaxy. The thick strip of glimmering stars is the plane of the Galaxy. The dark center may look empty, but it is filled with masses of dust and gas blocking visible light and leaving a shadow through the galaxy's core.
Credit: Juan Carlos Muñoz-Mateos/ESO
Image Date: October 6, 2017
#ESO #Astronomy #Science #Stars #MilkyWay #Galaxy #Space #Earth #Chile #Atacama #Desert #Paranal #Observatory #VLT #Telescope #Panorama #Astrophotography #Photography #Art #STEM #Education
Cosmic archaeology: A galaxy cluster | Hubble
This NASA/ESA Hubble Space Telescope image is chock-full of galaxies—each glowing speck is a different galaxy, bar the bright flash in the middle of the image which is actually a star lying within our own galaxy that just happened to be in the way. At the center of the image lies something especially interesting, the center of the massive galaxy cluster called WHL J24.3324-8.477, including the brightest galaxy of the cluster.
The Universe contains structures on various scales—planets collect around stars, stars collect into galaxies, galaxies collect into groups, and galaxy groups collect into clusters. Galaxy clusters contain hundreds to thousands of galaxies bound together by gravity. Dark matter and dark energy play key roles in the formation and evolution of these clusters, so studying massive galaxy clusters can help scientists to unravel the mysteries of these elusive phenomena.
This infrared image was taken by Hubble’s Advanced Camera for Surveys and Wide-Field Camera 3 as part of an observing program called RELICS (Reionization Lensing Cluster Survey). RELICS imaged 41 massive galaxy clusters with the aim of finding the brightest distant galaxies for the forthcoming NASA/ESA/CSA James Webb Space Telescope (JWST) to study. Such research will tell us more about our cosmic origins.
Credit: ESA/Hubble & NASA
Release Date: October 23, 2017
#NASA #Hubble #Science #Space #Galaxy #Galaxies #GalaxyCluster #WHLJ2433248477 #Cetus #Cosmos #Universe #Telescope #ESA #Goddard #GSFC #STEM #Education
Saturn's Grandeur | NASA Cassini Mission
The Cassini mission was a cooperative project of NASA, ESA (the European Space Agency) and the Italian Space Agency. The Jet Propulsion Laboratory, a division of Caltech in Pasadena, manages the mission for NASA's Science Mission Directorate, Washington. The Cassini orbiter and its two onboard cameras were designed, developed and assembled at JPL. The imaging operations center is based at the Space Science Institute in Boulder, Colorado.
For more information about the Cassini-Huygens mission visit: https://saturn.jpl.nasa.gov and https://www.nasa.gov/cassini.
The Cassini imaging team homepage is at https://ciclops.org.
Technical details:
Processed using RGB filtered images of Saturn taken by Cassini on March 23, 2016.
Credit: NASA/JPL-Caltech/SSI/Kevin M. Gill
Image Date: March 23, 2016
#NASA #Astronomy #Science #Space #Saturn #Planet #Rings #SolarSystem #Exploration #Cassini #Spacecraft #GrandFinale #JPL #Caltech #Pasadena #California #UnitedStates #ESA #ASI #STEM #Education
Thursday, October 19, 2017
From Africa to Eastern Europe | International Space Station
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A series of night photos were taken by ESA astronaut Paolo Nespoli of Italy every second to create this timelapse of the Earth (Africa to Eastern Europe) as seen from the International Space Station.
ESA astronaut Paolo Nespoli in currently working and living on board the International Space Station as part of his long duration VITA mission
Credit: European Space Agency (ESA)
Duration: 35 seconds
Release Date: October 15, 2017
#NASA #ISS #Earth #Science #Africa #Europe #EasternEurope #Night #EarthObservation #Astronaut #PaoloNespoli #ASI #ESA #Europe #Italy #Italia #Human #Spaceflight #Expedition53 #VITAMission #UnitedStates #JSC #OverviewEffect #OrbitalPerspective #STEM #Education #HD #Video #Timelapse
A series of night photos were taken by ESA astronaut Paolo Nespoli of Italy every second to create this timelapse of the Earth (Africa to Eastern Europe) as seen from the International Space Station.
ESA astronaut Paolo Nespoli in currently working and living on board the International Space Station as part of his long duration VITA mission
Credit: European Space Agency (ESA)
Duration: 35 seconds
Release Date: October 15, 2017
#NASA #ISS #Earth #Science #Africa #Europe #EasternEurope #Night #EarthObservation #Astronaut #PaoloNespoli #ASI #ESA #Europe #Italy #Italia #Human #Spaceflight #Expedition53 #VITAMission #UnitedStates #JSC #OverviewEffect #OrbitalPerspective #STEM #Education #HD #Video #Timelapse
Monday, October 16, 2017
Hubble observes first kilonova | NASA/ESA
Hubble observes source of gravitational waves for the first time | Hubblecast 103: Astronomers using the NASA/ESA Hubble Space Telescope have observed a visible counterpart to gravitational waves for the first time: a kilonova from merging neutron stars.
For the first time, Hubble has observed the source of a gravitational wave: the merging of two neutron stars. This merger created a kilonova—an object first predicted by theory more than 30 ago. This event also provides the strongest evidence yet that short duration gamma-ray bursts are caused by mergers of neutron stars. These observations may help solve another long-standing question in astronomy: the origin of heavy chemical elements, like gold and platinum. In the merger of two neutron stars, the conditions appear just right for their production.
Credit: NASA and ESA
Duration: 4 minutes, 19 seconds
Release Date: October 16, 2017
#ESO #Astronomy #Science #Space #Stars #Neutron #GravitationalWaves #Kilonovae #Kilonova #LIGO #Virgo #Astrophysics #Physics #Telescopes #Chile #Atacama #Desert #SouthAmerica #Europe #History #STEM #Education #Art #Illustration #HD #Video
First Light from Gravitational Wave Source | European Southern Observatory
Artist Illustration: Merging neutron stars scatter gold and platinum into space
Oct. 16, 2017: ESO’s fleet of telescopes in Chile have detected the first visible counterpart to a gravitational wave source. These historic observations suggest that this unique object is the result of the merger of two neutron stars. The cataclysmic aftermaths of this kind of merger—long-predicted events called kilonovae—disperse heavy elements such as gold and platinum throughout the Universe. This discovery, published in several papers in the journal Nature and elsewhere, also provides the strongest evidence yet that short-duration gamma-ray bursts are caused by mergers of neutron stars.
For the first time ever, astronomers have observed both gravitational waves and light (electromagnetic radiation) from the same event, thanks to a global collaborative effort and the quick reactions of both ESO’s facilities and others around the world.
On August 17, 2017 the NSF's Laser Interferometer Gravitational-Wave Observatory (LIGO) in the United States, working with the Virgo Interferometer in Italy, detected gravitational waves passing the Earth. This event, the fifth ever detected, was named GW170817. About two seconds later, two space observatories, NASA’s Fermi Gamma-ray Space Telescope and ESA’s INTErnational Gamma Ray Astrophysics Laboratory (INTEGRAL), detected a short gamma-ray burst from the same area of the sky.
The LIGO–Virgo observatory network positioned the source within a large region of the southern sky, the size of several hundred full Moons and containing millions of stars [1]. As night fell in Chile many telescopes peered at this patch of sky, searching for new sources. These included ESO’s Visible and Infrared Survey Telescope for Astronomy (VISTA) and VLT Survey Telescope (VST) at the Paranal Observatory, the Italian Rapid Eye Mount (REM) telescope at ESO’s La Silla Observatory, the LCO 0.4-meter telescope at Las Cumbres Observatory, and the American DECam at Cerro Tololo Inter-American Observatory. The Swope 1-metre telescope was the first to announce a new point of light. It appeared very close to NGC 4993, a lenticular galaxy in the constellation of Hydra, and VISTA observations pinpointed this source at infrared wavelengths almost at the same time. As night marched west across the globe, the Hawaiian island telescopes Pan-STARRS and Subaru also picked it up and watched it evolve rapidly.
“There are rare occasions when a scientist has the chance to witness a new era at its beginning,” said Elena Pian, astronomer with INAF, Italy, and lead author of one of the Nature papers. “This is one such time!”
ESO launched one of the biggest ever “target of opportunity” observing campaigns and many ESO and ESO-partnered telescopes observed the object over the weeks following the detection [2]. ESO’s Very Large Telescope (VLT), New Technology Telescope (NTT), VST, the MPG/ESO 2.2-metre telescope, and the Atacama Large Millimeter/submillimeter Array (ALMA) [3] all observed the event and its after-effects over a wide range of wavelengths. About 70 observatories around the world also observed the event, including the NASA/ESA Hubble Space Telescope.
Distance estimates from both the gravitational wave data and other observations agree that GW170817 was at the same distance as NGC 4993, about 130 million light-years from Earth. This makes the source both the closest gravitational wave event detected so far and also one of the closest gamma-ray burst sources ever seen [4].
The ripples in spacetime known as gravitational waves are created by moving masses, but only the most intense, created by rapid changes in the speed of very massive objects, can currently be detected. One such event is the merging of neutron stars, the extremely dense, collapsed cores of high-mass stars left behind after supernovae [5]. These mergers have so far been the leading hypothesis to explain short gamma-ray bursts. An explosive event 1000 times brighter than a typical nova—known as a kilonova—is expected to follow this type of event.
The almost simultaneous detections of both gravitational waves and gamma rays from GW170817 raised hopes that this object was indeed a long-sought kilonova and observations with ESO facilities have revealed properties remarkably close to theoretical predictions. Kilonovae were suggested more than 30 years ago but this marks the first confirmed observation.
Following the merger of the two neutron stars, a burst of rapidly expanding radioactive heavy chemical elements left the kilonova, moving as fast as one-fifth of the speed of light. The colour of the kilonova shifted from very blue to very red over the next few days, a faster change than that seen in any other observed stellar explosion.
“When the spectrum appeared on our screens I realised that this was the most unusual transient event I’d ever seen,” remarked Stephen Smartt, who led observations with ESO’s NTT as part of the extended Public ESO Spectroscopic Survey of Transient Objects (ePESSTO) observing programme. “I had never seen anything like it. Our data, along with data from other groups, proved to everyone that this was not a supernova or a foreground variable star, but was something quite remarkable.”
Spectra from ePESSTO and the VLT’s X-shooter instrument suggest the presence of caesium and tellurium ejected from the merging neutron stars. These and other heavy elements, produced during the neutron star merger, would be blown into space by the subsequent kilonova. These observations pin down the formation of elements heavier than iron through nuclear reactions within high-density stellar objects, known as r-process nucleosynthesis, something which was only theorised before.
“The data we have so far are an amazingly close match to theory. It is a triumph for the theorists, a confirmation that the LIGO–VIRGO events are absolutely real, and an achievement for ESO to have gathered such an astonishing data set on the kilonova,” adds Stefano Covino, lead author of one of the Nature Astronomy papers.
“ESO’s great strength is that it has a wide range of telescopes and instruments to tackle big and complex astronomical projects, and at short notice. We have entered a new era of multi-messenger astronomy!” concludes Andrew Levan, lead author of one of the papers.
Notes
[1] The LIGO–Virgo detection localised the source to an area on the sky of about 35 square degrees.
[2 The galaxy was only observable in the evening in August and then was too close to the Sun in the sky to be observed by September.
[3] On the VLT, observations were taken with: the X-shooter spectrograph located on Unit Telescope 2 (UT2); the FOcal Reducer and low dispersion Spectrograph 2 (FORS2) and Nasmyth Adaptive Optics System (NAOS) – Near-Infrared Imager and Spectrograph (CONICA) (NACO) on Unit Telescope 1 (UT1); VIsible Multi-Object Spectrograph (VIMOS) and VLT Imager and Spectrometer for mid-Infrared (VISIR) located on Unit Telescope 3 (UT3); and the Multi Unit Spectroscopic Explorer (MUSE) and High Acuity Wide-field K-band Imager (HAWK-I) on Unit Telescope 4 (UT4). The VST observed using the OmegaCAM and VISTA observed with the VISTA InfraRed CAMera (VIRCAM). Through the ePESSTO programme, the NTT collected visible spectra with the ESO Faint Object Spectrograph and Camera 2 (EFOSC2) spectrograph and infrared spectra with the Son of ISAAC (SOFI) spectrograph. The MPG/ESO 2.2-metre telescope observed using the Gamma-Ray burst Optical/Near-infrared Detector (GROND) instrument.
[4] The comparatively small distance between Earth and the neutron star merger, 130 million light-years, made the observations possible, since merging neutron stars create weaker gravitational waves than merging black holes, which were the likely case of the first four gravitational wave detections.
[5] When neutron stars orbit one another in a binary system, they lose energy by emitting gravitational waves. They get closer together until, when they finally meet, some of the mass of the stellar remnants is converted into energy in a violent burst of gravitational waves, as described by Einstein’s famous equation E=mc2.
More information
This research was presented in a series of papers to appear in Nature, Nature Astronomy and Astrophysical Journal Letters.
Article Credit: European Southern Observatory (ESO)
Image Credit: ESO/L. Calçada/M. Kornmesser
Release Date: October 16, 2017
#ESO #Astronomy #Science #Space #Stars #Neutron #GravitationalWaves #Kilonovae #LIGO #Virgo #Astrophysics #Physics #Telescopes #Chile #Atacama #Desert #SouthAmerica #Europe #History #STEM #Education #Art #Illustration
A Glimpse of Our Galaxy's Future | Hubble
This image, captured by the NASA/ESA Hubble Space Telescope, shows what happens when two galaxies become one. The twisted cosmic knot seen here is NGC 2623—or Arp 243—and is located about 250 million light-years away in the constellation of Cancer (The Crab).
NGC 2623 gained its unusual and distinctive shape as the result of a major collision and subsequent merger between two separate galaxies. This violent encounter caused clouds of gas within the two galaxies to become compressed and stirred up, in turn triggering a sharp spike of star formation. This active star formation is marked by speckled patches of bright blue; these can be seen clustered both in the center and along the trails of dust and gas forming NGC 2623’s sweeping curves (known as tidal tails). These tails extend for roughly 50,000 light-years from end to end. Many young, hot, newborn stars form in bright stellar clusters—at least 170 such clusters are known to exist within NGC 2623.
NGC 2623 is in a late stage of merging. It is thought that the Milky Way will eventually resemble NGC 2623 when it collides with our neighboring galaxy, the Andromeda Galaxy, in four billion years time.
In contrast to the image of NGC 2623 released in 2009, this new version contains data from recent narrow-band and infrared observations that make more features of the galaxy visible.
Credit: ESA/Hubble & NASA
Release Date: October 16, 2017
#NASA #Hubble #Astronomy #Science #Space #Galaxy #NGC2623 #Arp243 #Galaxies #Stars #Cancer #Cosmos #Universe #Telescope #ESA #Goddard #GSFC #STScI #STEM #Education
Thursday, October 12, 2017
ALMA looks to the night sky
This photo shows ALMA hard at work in the Atacama desert, looking up at the Nights Sky. ALMA (Atacama Large Millimeter/submillimeter Array) is the most powerful telescope for observing the cool Universe—molecular gas and dust as well the distant Universe. ALMA is studying the building blocks of stars, planetary systems, galaxies and life itself.
Credit: D. Kordan/ESO
Release Date: October 6, 2017
#ESO #Astronomy #Science #Space #Stars #MilkyWay #Galaxy #ALMA #Telescope #Astrophotography #Photography #Chile #Atacama #Desert #SouthAmerica #Europe #STEM #Education
Wednesday, October 11, 2017
Our Way
This beautiful image of the Milky Way was taken by ESO Photo Ambassador Juan Carlos Muñoz-Mateos. it clearly shows the interstellar dust that blocks visible light from many stars in our Galaxy. Fortunately, other types of radiation can penetrate this dust, so we are able to observe the hidden stars with telescopes that detect a variety of different types of emission.
This image was taken from ESO's Paranal Residencia in the Chilean Atacama desert, home to several world-class telescopes, including ESO's Very Large Telescope.
ESO Hotel at Cerro Paranal (or Residencia) is the accommodation for Paranal Observatory in Chile since 2002. It is mainly used for the ESO (European Southern Observatory) scientists and engineers who work there on a roster system. It has been called a "boarding house on Mars", because the desert surroundings are Mars-like, and an "Oasis for astronomers". It is not a commercial hotel, and the public cannot book rooms. (Source: Wikipedia)
Learn more about the ALMA Residencia (ESO Hotel):
https://www.eso.org/public/teles-instr/alma/residencia/
Credit: Juan Carlos Muñoz-Mateos/ESO
Release Date: October 6, 2017
#ESO #Earth #Astronomy #Science #Space #MilkyWay #Galaxy #Stars #Paranal #Observatory #Residencia #ALMA #Chile #Atacama #Desert #CerroParanal #SouthAmerica #SolarSystem #Cosmos #Universe #Astrophotography #Photography #STEM #Education
Monday, October 09, 2017
Dwarf Galaxy ESO 553-46 | Hubble Space Telescope
Clusters of young, hot stars are speckling the galaxy, burning with a fierce blue glow. The intense radiation they produce also causes surrounding gas to light up, which is bright red in this image. The small mass and distinctive coloring of galaxies of this type prompted astronomers to classify them, appropriately, as blue compact dwarfs (BCD).
Lacking the clear core and structure that many larger galaxies—such as the Milky Way—have, BCDs such as ESO 553-46 are composed of many large clusters of stars bound together by gravity. Their chemical makeup is interesting to astronomers, since they contain relatively little dust and few elements heavier than helium, which are produced in stars and distributed via supernova explosions. Such conditions are strikingly similar to those that existed in the early Universe, when the first galaxies were beginning to form.
Credit: ESA/Hubble & NASA
Release Date: October 10, 2017
#NASA #Hubble #Astronomy #Science #Space #Galaxy #Dwarf #ESO55346 #Stars #Lepus #Cosmos #Universe #Telescope #ESA #Goddard #GSFC #STScI #STEM #Education
Earth by Moonlight | International Space Station
Cosmonaut Sergey Ryazanskiy:
"Night planet Earth illuminated by the Aurora and Moonlight."
"Ночная планета Земля в лунном свете и сиянии Авроры."
Credit: Roscosmos, Cosmonaut Сергей Рязанский
Release Date: October 7, 2017
#NASA #ISS #Earth #Science #Moon #Moonlight #Aurora #EarthObservation #Cosmonaut #FlightEngineer #SergeyRyazanskiy #космонавт #Роскосмос #Roscosmos #Russia #Россия #Human #Spaceflight #Expedition53 #UnitedStates #JSC #STEM #Education
Thursday, October 05, 2017
ASPIRE Successfully Launches from NASA Wallops
Oct. 4, 2017: A NASA Black Brant IX sounding rocket carrying a parachute test platform was successfully launched at 6:45 a.m. EST, October 4, from the agency’s Wallops Flight Facility in Virginia.
The 58-foot tall rocket carried the Advanced Supersonic Parachute Inflation Research Experiment (ASPIRE) from NASA’s Jet Propulsion Laboratory in Pasadena, California. The mission is to evaluate the performance of the ASPIRE payload, which is designed to test parachute systems in a low-density, supersonic environment.
The flight was conducted through NASA’s Space Mission Directorate.
The payload flew to an altitude of approximately 31.62 miles and then landed in the Atlantic Ocean. The payload is being recovered for data retrieval and inspection.
NASA's Sounding Rocket Program is conducted at the agency's Wallops Flight Facility. Orbital ATK provides mission planning, engineering services and field operations through the NASA Sounding Rocket Operations Contract. NASA's Heliophysics Division manages the sounding-rocket program for the agency.
The next launch currently scheduled from Wallops is Orbital ATK’s Antares rocket carrying the Cygnus spacecraft with supplies and experiments to the International Space Station. Antares is scheduled for launch no earlier than November 10.
Credit: NASA/Terry Zapeach/Jamie Adkins
Release Date: October 4, 2017
#NASA #Space #Earth #Science #Astronomy #Rocket #SoundingRocket #ASPIRE #BlackBrantIX #SubOrbital #Flight #Instruments #Experiments #Research #University #Atmosphere #Aurora #Planets #SolarSystem #Exploration #JPL #Wallops #Virginia #Spaceport #UnitedStates #STEM #Education
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