JunoCam images aren’t just for art and science—sometimes they are processed to bring a chuckle. This image, processed by citizen scientist Jason Major, is titled “Jovey McJupiterface.” By rotating the image 180 degrees and orienting it from south up, two white oval storms turn into eyeballs, and the “face” of Jupiter is revealed.
The original image was acquired by JunoCam on NASA’s Juno spacecraft on May 19, 2017 at 11:20 a.m. PT (2: 20 p.m. ET) from an altitude of 12,075 miles (19,433 kilometers).
JunoCam's raw images are available for the public to peruse and process into image products at: www.missionjuno.swri.edu/junocam
More information about Juno is at:
https://www.nasa.gov/juno and http://missionjuno.swri.edu
Credit: NASA/JPL-Caltech/SwRI/MSSS/Jason Major
Release Date: June 29, 2017#NASA #Astronomy #Science #Space #Jupiter #Planet #Atmosphere #Cyclones #Clouds #Storms #Juno #JunoCam #Spacecraft #Exploration #SolarSystem #Technology #Engineering #JPL #Pasadena #California #USA #UnitedStates #LockheedMartin #MSFC #Marshall #SwRI #STEM #Education
A NASA Terrier-Improved Malemute sounding rocket was successfully launched at 4:25 a.m., Thursday, June 29. The rocket flew to an altitude of about 118 miles. The mission was a test of a new multi-canister ejection system for deploying vapors in ionosphere or aurora sounding rocket missions.
Credit: NASA Wallops Flight Facility
Release Date: June 29, 2017#NASA #Earth #Science #Artificial #Clouds #Vapor #Wallops #Malemute #Terrier #Sounding #Rocket #Launch #Technology #WFF #Flight #Virginia #UnitedStates #Photography #STEM #Education
Image: NASA Terrier-Improved Malemute sounding rocket launch | June 29, 2017: July 4 fireworks came early when a NASA Terrier-Improved Malemute sounding rocket was successfully launched at 4:25 a.m., Thursday, June 29, from the agency’s Wallops Flight Facility in Virginia.
During the 8-minute flight, 10 canisters about the size of a soft drink can were ejected in space, 6 to 12 miles away from the 670-pound main payload.
The canisters deployed blue-green and red vapor that formed artificial clouds visible from New York to North Carolina.
During an ionosphere or aurora science mission, these clouds, or vapor tracers, allow scientists on the ground to visually track particle motions in space.
The development of the multi-canister ampoule ejection system will allow scientists to gather information over a much larger area than previously possible when deploying the tracers just from the main payload.
The rocket, after being delayed multiple times over the last 30 days, flew to an altitude of about 118 miles.
Wallops received nearly 2,000 reports and photos of the cloud sightings from areas as far north as New York, south to North Carolina, and inland throughout Virginia, Maryland, Pennsylvania, and points in-between.
NASA's Wallops Flight Facility provides agile, low-cost flight and launch range services to meet government and commercial sector needs for accessing flight regimes worldwide from the Earth’s surface to the moon. Wallops' flight assets ranging from research aircraft, unmanned aerial systems and high-altitude balloons to suborbital and orbital rockets provide a full-range of capability, while operational launch range and airfield capabilities meet ongoing and emerging needs in the science, aerospace, defense, and commercial industries.
Article Credit: NASA/Wallops
Image Credit: NASA/Terry Zaperach#NASA #Earth #Science #Artificial #Clouds #Wallops #Malemute #Terrier #Sounding #Rocket #Launch #Technology #WFF #Flight #Virginia #UnitedStates #STEM #Education
June 22, 2017: This image was acquired by the High Resolution Imaging Science Experiment (HiRISE) camera aboard NASA's Mars Reconnaissance Orbiter on April 18, 2017, at 14:04 local Mars time. It reminded the HiRISE team of the rugged and open terrain of a stark shore-line, perhaps of the British Isles. A close-up in enhanced color produces a striking effect, giving the impression of a cloud-covered cliff edge with foamy waves crashing against it.
The reality is that the surface of Mars is much dryer than our imaginations might want to suggest. This is only a tiny part of a much larger structure; an inverted crater—a crater that has been infilled by material that is more resistant to erosion than the rocks around it—surrounded by bluish basaltic dunes. The edge of these elevated light-toned deposits are degraded, irregular and cliff-forming.
Dunes visible below the cliff, give the impression of an ocean surface, complete with foam capped waves crashing against the “shore line,” demonstrating the abstract similarity between the nature of a turbulent ocean and a Martian dune field.
Meridiani Planum has an overall smooth terrain, which starkly contrasts with the more common boulder- and crater-laden landscapes observed over much of the rest of Mars. This makes it relatively younger in character than many other areas of the planet. Meridiani is one of the Mars Exploration Rover landing sites, and, is known for its layers and sediments. The orbital detection of hematite was one of the main reasons for sending Opportunity to this area.
Salt-bearing rocks—also called sulphates—were observed in the very first image from Opportunity, so perhaps it’s apt that this HiRISE image reminds us of the turmoil and rugged beauty of a cliff-face, a coastline, being worn down by a relentless sea.
NASA’s Jet Propulsion Laboratory, 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.
Image Credit: NASA/JPL/University of Arizona
Article Credit: Jon Kissi, Livio L. Tornabene, Zach Morse, Eric Pilles and Gavin Tolometti
Release Date: June 22, 2017#NASA #Astronomy #Science #Space #Mars #MeridianiPlanum #Crater #Dunes #Basalt #MRO #HiRISE #Spacecraft #Opportunity #Rover #JPL #Pasadena #California #UnitedStates #SolarSystem #STEM #Education
June 22, 2017: NASA’s James Webb Space Telescope was placed in Johnson Space Center’s historic Chamber A on June 20, 2017, to prepare for its final three months of testing in a cryogenic vacuum that mimics temperatures in space.
Engineers will perform the test to prove that the telescope can operate in space at these temperatures. Chamber A will simulate an environment where the telescope will experience extreme cold -- around 37 Kelvin (minus 236 degrees Celsius or minus 393 degrees Fahrenheit).
In space, the telescope must be kept extremely cold, in order to be able to detect the infrared light from very faint, distant objects. To protect the telescope from external sources of light and heat (like the sun, Earth, and moon), as well as from heat emitted by the observatory, a five-layer, tennis court-sized sunshield acts like a parasol that provides shade. The sunshield separates the observatory into a warm, sun-facing side (reaching temperatures close to 400 degrees Fahrenheit) and a cold side (185 degrees below zero). The sunshield blocks sunlight from interfering with the sensitive telescope instruments.
The James Webb Space Telescope is the scientific successor to NASA's Hubble Space Telescope. It will be the most powerful space telescope ever built. Webb is an international project led by NASA with its partners, ESA (European Space Agency) and the Canadian Space Agency.
For more information about Chamber A, visit: https://www.nasa.gov/feature/goddard/2017/nasas-apollo-era-test-chamber-now-james-webb-space-telescope-ready
For more information about the Webb telescope visit: www.jwst.nasa.gov or www.nasa.gov/webb
Credit: NASA/Chris Gunn
Image Date: June 21, 2017
Release Date: June 22, 2017#NASA #Astronomy #Science #Space #Telescope #JWST #JamesWebb #Galaxies #Stars #Exoplanets #Planets #Enceladus #Europa #SolarSystem #Astrophysics #Cosmos #Universe #ESA #CSA #Goddard #GSFC #JSC #Testing #UnitedStates #STScI #STEM #Education
June 22, 2017: Like the Nile River Valley, the Indus River Basin in Pakistan is an ancient seat of civilization. People have lived and farmed in the river’s fertile floodplain for millennia, in spite of the arid conditions that make it difficult to grow food in the rest of the region.
In modern times, the sinuous shape of the Indus River emerges even in nighttime satellite imagery. Though the river itself is only barely visible, the dark crops and vegetation growing along its banks help reveal the general shape of the river. The brighter, more reflective land beyond the dark band of farmed land is desert.
The image is based on data collected in 2016 by the Visible Infrared Imaging Radiometer Suite (VIIRS) on the NASA-NOAA Suomi NPP satellite. It is part of a global composite that was made by selecting the best cloud-free nights in each month over each landmass on Earth. VIIRS includes a special “day/night band,” a low-light sensor that measures light emissions and reflections, allowing researchers to distinguish the intensity, types, and sources of night lights and to observe how they change over time.
Many of the largest cities and towns in Pakistan are clustered along the Indus. Karachi, a city of 9.3 million people, lies along the southernmost stretch of the river, near where it empties into the Arabian Sea at the Indus River Delta. Other bright cities along the river include Hyderabad (1.1 million people), Larkana (270,000 people), and Sukkur (300,000 people).
The border between Pakistan and India stands out among the night lights of this region. For security purposes, India has installed thousands of kilometers of floodlights along it, a feature bright enough to be seen from the International Space Station. According to news reports, Indian authorities are in the process of transitioning to LED floodlights.
Image Credit: NASA Earth Observatory image by Joshua Stevens, using Suomi NPP VIIRS data from Miguel Román, NASA GSFC
Article Credit: Adam Voiland
Instrument(s): Suomi NPP - VIIRS
Image Date: 2016
Release Date: June 22, 2017#NASA #Earth #Science #Space #Satellite #Indus #River #Night #Pakistan #Karachi #Hyderabad #Larkana #Sukkur #India #Bhārat #Gaṇarājya #Agriculture #ArabianSea #Asia #SouthAsia #SuomiNPP #VIIRS #EarthObservation #LightPollution #STEM #Education #پاکستان
Image: The total solar eclipse of Aug. 21, 2017, stretches across the U.S. from coast to coast, providing scientists with a unique opportunity to study the eclipse from different vantage points.
June 21, 2017: The first total solar eclipse in the continental United States in nearly 40 years takes place on Aug. 21, 2017. Beyond providing a brilliant sight in the daytime sky, total solar eclipses provide a rare chance for scientists to collect data only available during eclipses. NASA is funding 11 scientific studies that will take advantage of this opportunity.
“When the moon blocks out the sun during a total eclipse, those regions of Earth that are in the direct path of totality become dark as night for almost three minutes,” said Steve Clarke, director of the Heliophysics Division at NASA Headquarters in Washington, D.C. “This will be one of the best-observed eclipses to date, and we plan to take advantage of this unique opportunity to learn as much as we can about the sun and its effects on Earth.”
The August 2017 total solar eclipse will provide a unique opportunity to study Earth, the sun, and their interaction because of the eclipse’s long path over land. The path of the total eclipse crosses the U.S. from coast to coast, so scientists will be able to take ground-based observations over a period of more than an hour to complement the wealth of data provided by NASA satellites.
The 11 NASA-funded studies across a range of disciplines, using the total solar eclipse to observe our sun and Earth, test new instruments, and even leverage the skills of citizen scientists to expand our understanding of the sun-Earth system. The studies are listed below, followed by the name of the principal investigator and their home institution.
Studying the sun
During a total solar eclipse, the moon blocks out the sun’s overwhelmingly bright face, revealing the relatively faint solar atmosphere, called the corona. Scientists can also use an instrument called a coronagraph—which uses a disk to block out the light of the sun—to create an artificial eclipse. However, a phenomenon called diffraction blurs the light near the disk in a coronagraph, making it difficult to get clear pictures of the inner parts of the corona, so total solar eclipses remain the only opportunity to study these regions in clear detail in visible light. In many ways, these inner regions of the corona are the missing link in understanding the sources of space weather—so total solar eclipses are truly invaluable in our quest to understand the sun-Earth connection.
The sun-focused studies are:
Exploring the Physics of the Coronal Plasma through Imaging Spectroscopy during the 21 August 2017 Total Solar Eclipse (Shadia Habbal, University of Hawaii)
Testing a Polarization Sensor for Measuring Temperature and Flow Speed in the Solar Corona during the Total Solar Eclipse of 2017 August 21 (Nat Gopalswamy, NASA’s Goddard Space Flight Center)
Chasing the 2017 Eclipse: Interdisciplinary Airborne Science from NASA's WB-57 (Amir Caspi, Southwest Research Institute)
Measuring the Infrared Solar Corona During the 2017 Eclipse (Paul Bryans, University Corporation for Atmospheric Research)
Citizen Science Approach to Measuring the Polarization of Solar Corona During Eclipse 2017 (Padma Yanamandra-Fisher, Space Science Institute)
Rosetta-stone experiments at infrared and visible wavelengths during the August 21 2017 Eclipse (Philip Judge, University Corporation for Atmospheric Research)
Studying Earth
Total solar eclipses are also an opportunity to study Earth under uncommon conditions. The sudden blocking of the sun during an eclipse reduces the light and temperature on the ground, and these quick-changing conditions can affect weather, vegetation and animal behavior.
The Earth-focused studies are:
Solar eclipse-induced changes in the ionosphere over the continental US (Philip Erickson, Massachusetts Institute of Technology)
Quantifying the contributions of ionization sources on the formation of the D-region ionosphere during the 2017 solar eclipse (Robert Marshall, University of Colorado Boulder)
Empirically-Guided Solar Eclipse Modeling Study (Gregory Earle, Virginia Tech)
Using the 2017 Eclipse viewed by DSCOVR/EPIC & NISTAR from above and spectral radiance and broadband irradiance instruments from below to perform a 3-D radiative transfer closure experiment (Guoyong Wen, NASA’s Goddard Space Flight Center)
Land and Atmospheric Responses to the 2017 Total Solar Eclipse (Bohumil Svoma, University of Missouri)
Article Credit: NASA Goddard
Image Credit: NASA’s Scientific Visualization Studio
Release Date: June 21, 2017#NASA #Astronomy #Science #Space #Solar #Eclipse #Eclipse2017 #Sun #Moon #Corona #Atmosphere #SolarEclipse #Heliophysics #Coronagraph #NorthAmerica #Canada #UnitedStates #Mexico #Totality #STEM #Education
Still image showing the Earth, moon, and sun aligned during solar eclipse | June 21, 2017: On August 21, 2017, the Earth will cross the shadow of the moon, creating a total solar eclipse. Eclipses happen about every six months, but this one is special. For the first time in almost 40 years, the path of the moon's shadow passes through the continental United States. This visualization shows the Earth, moon, and sun at 17:05:40 UTC during the eclipse.
In the animation from which this still was taken, the Earth, moon, sun, and shadow cones are viewed through a telescopic lens on a virtual camera located far behind the Earth. Long focal lengths like the one used here appear to compress the distance between near and far objects. Despite appearances, the geometry of the scene is correct. The moon's umbra cone is roughly 30 Earth diameters long, barely enough to reach the Earth, while the sun is almost 400 times farther away.
Credit: NASA's Scientific Visualization Studio
Release Date: June 21, 2017#NASA #Astronomy #Science #Space #Solar #Eclipse #Eclipse2017 #Sun #Moon #Corona #Atmosphere #SolarEclipse #NorthAmerica #Canada #UnitedStates #Mexico #Totality #STEM #Education #Visualization
Assembled using calibrated red, green, and violet filtered images taken by the Cassini spacecraft on May 27, 2015.
Tethys (or Saturn III) is a mid-sized moon of Saturn about 1,060 km (660 mi) across. It was discovered by G. D. Cassini in 1684 and is named after the titan Tethys of Greek mythology.
Tethys has a low density of 0.98 g/cm3, the lowest of all the major moons in the Solar System, indicating that it is made of water ice with just a small fraction of rock. This is confirmed by the spectroscopy of its surface, which identified water ice as the dominant surface material. A small amount of an unidentified dark material is present as well. The surface of Tethys is very bright, being the second-brightest of the moons of Saturn after Enceladus, and neutral in color.
(Source: Wikipedia)
The Cassini mission is a cooperative project of NASA, ESA (the European Space Agency) and the Italian Space Agency. The Jet Propulsion Laboratory, a division of the California Institute of Technology 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: http://saturn.jpl.nasa.gov and http://www.nasa.gov/cassini
The Cassini imaging team homepage is at http://ciclops.org
Credit: NASA/JPL-Caltech/SSI/Kevin M. Gill
Image Date: May 27, 2015
Release Date: June 20, 2017#NASA #ESA #Astronomy #Science #Space #Saturn #Planet #Rings #Moon #Tethys #SolarSystem #Exploration #Cassini #Spacecraft #JPL #Pasadena #California #UnitedStates #ASI #STEM #Education
Image: The feature that appears bright blue at the center of this scene is NASA's Curiosity Mars rover amid tan rocks and dark sand on Mount Sharp, as viewed by the HiRISE camera on NASA's Mars Reconnaissance Orbiter on June 5, 2017.
June 20, 2017: Using the most powerful telescope ever sent to Mars, NASA's Mars Reconnaissance Orbiter caught a view of the Curiosity rover this month amid rocky mountainside terrain.
The car-size rover, climbing up lower Mount Sharp toward its next destination, appears as a blue dab against a background of tan rocks and dark sand in the enhanced-color image from the orbiter's High Resolution Imaging Science Experiment (HiRISE) camera. The exaggerated color, showing differences in Mars surface materials, makes Curiosity appear bluer than it really looks.
The image was taken on June 5, 2017, two months before the fifth anniversary of Curiosity's landing near Mount Sharp on Aug. 5 PDT (Aug. 6, 2017, EDT and Universal Time).
When the image was taken, Curiosity was part way between its investigation of active sand dunes lower on Mount Sharp, and "Vera Rubin Ridge," a destination uphill where the rover team intends to examine outcrops where hematite has been identified from Mars orbit.
HiRISE obtains images of Curiosity a few times each year. The University of Arizona, Tucson, operates HiRISE, which was built by Ball Aerospace & Technologies Corp., Boulder, Colorado. NASA's Jet Propulsion Laboratory, a division of Caltech in Pasadena, California, manages the Mars Reconnaissance Orbiter Project and Mars Science Laboratory Project for NASA's Science Mission Directorate, Washington.
For more information about NASA's Mars Reconnaissance Orbiter, visit:
https://mars.nasa.gov/mro/
For more information about NASA's Mars Science Laboratory Project and Curiosity, visit: https://mars.nasa.gov/msl/
Credit: NASA/JPL-Caltech/Univ. of Arizona
Release Date: June 20, 2017
The Roll-Out Solar Array (ROSA) was deployed from the end of the Canadarm2 robotic arm Sunday, June 18 outside the International Space Station. ROSA is an experiment to test a new type of solar array that rolls open in space like a party favor and is more compact than current rigid panel designs.
Learn more about this new U.S. technology at:
Deployable Space Systems, Inc. (DSS)
http://www.dss-space.com
Image Credit: Deployable Space Systems
Release Date: June 20, 2017#NASA #Science #Space #ISS #Technology #Solar #SolarArray #ROSA #DSS #Testing #Experiment #Renewable #Energy #Power #Engineering #Canadarm2 #Robotic #Arm #Robotics #CSA #JSC #UnitedStates #Satellite #Aerospace #SpaceX #Dragon #Spacecraft #STEM #Education
The Roll-Out Solar Array (ROSA) was deployed from the end of the Canadarm2 robotic arm Sunday, June 18 outside the International Space Station. ROSA is an experiment to test a new type of solar array that rolls open in space like a party favor and is more compact than current rigid panel designs.
Learn more about this new U.S. technology at:
Deployable Space Systems, Inc. (DSS)
http://www.dss-space.com
Credits: NASA Johnson
Release Date: June 20, 2017#NASA #Science #Space #ISS #Technology #Solar #SolarArray #ROSA #Testing #Experiment #Renewable #Energy #Power #Engineering #Canadarm2 #Robotic #Arm #Robotics #CSA #JSC #UnitedStates #Satellite #Aerospace #SpaceX #Dragon #Spacecraft #STEM #Education #Animation #GIF
Image: Solar array unrolled with Earth visible below and end of Canadarm at right | June 20, 2017: Over the weekend of June 17-18, 2017, engineers on the ground remotely operated the International Space Station's robotic Canadarm2 to extract the Roll Out Solar Array (ROSA) experiment from the SpaceX Dragon resupply ship. The experiment will remain attached to the Canadarm2 over seven days to test the effectiveness of ROSA, an advanced, flexible solar array that rolls out like a tape measure.
Traditional solar panels used to power satellites can be bulky with heavy panels folded together using mechanical hinges. This new solar array's design rolls up to form a compact cylinder for launch with significantly less mass and volume, potentially offering substantial cost savings as well as an increase in power for satellites.
ROSA was developed as part of the Solar Electric Propulsion project sponsored by NASA’s Space Technology Mission Directorate. NASA tested the ROSA technology in vacuum chambers on Earth several years ago, and this is its first test in space. This solar array technology was developed to power large spacecraft using highly-efficient electric propulsion on missions to deep space including Mars and the moon.
Credit: NASA
Release Date: June 20, 2017#NASA #Science #Space #ISS #Technology #Solar #SolarArray #ROSA #Testing #Experiment #Renewable #Energy #Power #Engineering #Canadarm2 #Robotic #Arm #Robotics #CSA #JSC #UnitedStates #Satellite #Aerospace #SpaceX #Dragon #Spacecraft #STEM #Education
The crew taking part in NEEMO 22, the 22nd NASA Extreme Environment Mission Operations mission, consists of astronauts, technicians and scientists who are now on board the Aquarius underwater habitat off the coast of Florida.
The habitat acts as a makeshift ‘space base’ for the aquanauts to make regular ‘waterwalks’ in full scuba gear and, by adjusting their buoyancy, they can simulate the gravity levels found on the Moon, Mars or asteroids.
NASA astronaut Kjell Lindgren will be commander for this mission that will focus on exploration spacewalks as well as tasks based on the International Space Station. He is joined by ESA astronaut Pedro Duque, planetary scientist Trevor Gradd and research scientist Dom D’Agostino, along with two support technicians.
An international crew "splashed down" to the undersea Aquarius laboratory on the floor of the Atlantic Ocean on June 18, 2017, to prepare for future deep space missions during the 10-day NEEMO 22 expedition. NEEMO 22 will focus on both exploration spacewalks and objectives related to the International Space Station and deep space missions.
What is NEEMO?
NASA Extreme Environment Mission Operations (NEEMO) is a NASA mission that sends groups of astronauts, engineers and scientists to live in Aquarius, the world's only undersea research station, for up to three weeks at a time. The Aquarius habitat and its surroundings provide a convincing analog for space exploration. On a mission, the NEEMO crew and professional habitat technicians live 60 feet below the surface of the Atlantic Ocean in Florida International University’s Aquarius Reef Base undersea research habitat 6.2 miles off the coast of Key Largo, Florida.
For more information about NEEMO, visit: www.nasa.gov/neemo
Credit: NASA/Kjell Lindgren
Release Date: June 19, 2017 #NASA #ESA #NEEMO22 #Aquanauts #Astronauts #KjellLindgren #PedroDuque #Scientists #TrevorGradd #DomDAgostino #NEEMO #Aquarius #Underwater #Research #Station #Environment #Analog #Simulation #Science #Mars #JourneyToMars #ISS #Technology #Engineering #Human #Exploration #Physiology #Health #Experiments #International #Florida #USA #UnitedStates #Europe #Spacewalk #EVA #SolarSystem
The crew taking part in NEEMO 22, the 22nd NASA Extreme Environment Mission Operations mission, consists of astronauts, technicians and scientists who are now on board the Aquarius underwater habitat off the coast of Florida.
The habitat acts as a makeshift ‘space base’ for the aquanauts to make regular ‘waterwalks’ in full scuba gear and, by adjusting their buoyancy, they can simulate the gravity levels found on the Moon, Mars or asteroids.
NASA astronaut Kjell Lindgren will be commander for this mission that will focus on exploration spacewalks as well as tasks based on the International Space Station. He is joined by ESA astronaut Pedro Duque, planetary scientist Trevor Gradd and research scientist Dom D’Agostino, along with two support technicians.
An international crew "splashed down" to the undersea Aquarius laboratory on the floor of the Atlantic Ocean on June 18, 2017, to prepare for future deep space missions during the 10-day NEEMO 22 expedition. NEEMO 22 will focus on both exploration spacewalks and objectives related to the International Space Station and deep space missions.
What is NEEMO?
NASA Extreme Environment Mission Operations (NEEMO) is a NASA mission that sends groups of astronauts, engineers and scientists to live in Aquarius, the world's only undersea research station, for up to three weeks at a time. The Aquarius habitat and its surroundings provide a convincing analog for space exploration. On a mission, the NEEMO crew and professional habitat technicians live 60 feet below the surface of the Atlantic Ocean in Florida International University’s Aquarius Reef Base undersea research habitat 6.2 miles off the coast of Key Largo, Florida.
For more information about NEEMO, visit: www.nasa.gov/neemo
Credit: NASA
Release Date: June 19, 2017 #NASA #ESA #NEEMO22 #Aquanauts #Astronauts #KjellLindgren #PedroDuque #Scientists #TrevorGradd #DomDAgostino #NEEMO #Aquarius #Underwater #Research #Station #Environment #Analog #Simulation #Science #Mars #JourneyToMars #ISS #Technology #Engineering #Human #Exploration #Physiology #Health #Experiments #International #Florida #USA #UnitedStates #Europe #Spacewalk #EVA #SolarSystem