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NASAâs New Planet Hunter Reveals a Sky Full of Stars
NASAâs newest planet-hunting satellite â the Transiting Exoplanet Survey Satellite, or TESS for short â has just released its first science image using all of its cameras to capture a huge swath of the sky! TESS is NASAâs next step in the search for planets outside our solar system, called exoplanets.
This spectacular image, the first released using all four of TESSâ cameras, shows the satelliteâs full field of view. It captures parts of a dozen constellations, from Capricornus (the Sea Goat) to Pictor (the Painterâs Easel) â though it might be hard to find familiar constellations among all these stars! The image even includes the Large and Small Magellanic Clouds, our galaxyâs two largest companion galaxies.
The science community calls this image âfirst light,â but donât let that fool you â TESS has been seeing light since it launched in April. A first light image like this is released to show off the first science-quality image taken after a mission starts collecting science data, highlighting a spacecraftâs capabilities.
TESS has been busy since it launched from NASAâs Kennedy Space Center in Cape Canaveral, Florida. First TESS needed to get into position, which required a push from the Moon. After nearly a month in space, the satellite passed about 5,000 miles from the Moon, whose gravity gave it the boost it needed to get into a special orbit that will keep it stable and maximize its view of the sky.
During those first few weeks, we also got a sneak peek of the sky through one of TESSâs four cameras. This test image captured over 200,000 stars in just two seconds! The spacecraft was pointed toward the constellation Centaurus when it snapped this picture. The bright star Beta Centauri is visible at the lower left edge, and the edge of the Coalsack Nebula is in the right upper corner.
After settling into orbit, scientists ran a number of checks on TESS, including testing its ability to collect a set of stable images over a prolonged period of time. TESS not only proved its ability to perform this task, it also got a surprise! A comet named C/2018 N1 passed through TESSâs cameras for about 17 hours in July.
The images show a treasure trove of cosmic curiosities. There are some stars whose brightness changes over time and asteroids visible as small moving white dots. You can even see an arc of stray light from Mars, which is located outside the image, moving across the screen.
Now that TESS has settled into orbit and has been thoroughly tested, itâs digging into its main mission of finding planets around other stars. How will it spot something as tiny and faint as a planet trillions of miles away? The trick is to look at the star!
So far, most of the exoplanets weâve found were detected by looking for tiny dips in the brightness of their host stars. These dips are caused by the planet passing between us and its star â an event called a transit. Over its first two years, TESS will stare at 200,000 of the nearest and brightest stars in the sky to look for transits to identify stars with planets.
TESS will be building on the legacy of NASAâs Kepler spacecraft, which also used transits to find exoplanets. TESSâs target stars are about 10 times closer than Keplerâs, so theyâll tend to be brighter. Because theyâre closer and brighter, TESSâs target stars will be ideal candidates for follow-up studies with current and future observatories.
TESS is challenging over 200,000 of our stellar neighbors to a staring contest! Who knows what new amazing planets weâll find?
The TESS mission is led by MIT and came together with the help of many different partners. You can keep up with the latest from the TESS mission by following mission updates.
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10 Things to Know About Parker Solar Probe
On Aug. 12, 2018, we launched Parker Solar Probe to the Sun, where it will fly closer than any spacecraft before and uncover new secrets about our star. Hereâs what you need to know.
1. Getting to the Sun takes a lot of power
At about 1,400 pounds, Parker Solar Probe is relatively light for a spacecraft, but it launched to space aboard one of the most powerful rockets in the world, the United Launch Alliance Delta IV Heavy. Thatâs because it takes a lot of energy to go to the Sun â in fact, 55 times more energy than it takes to go to Mars.
Any object launched from Earth starts out traveling at about the same speed and in the same direction as Earth â 67,000 mph sideways. To get close to the Sun, Parker Solar Probe has to shed much of that sideways speed, and a strong launch is good start.
2. First stop: Venus!
Parker Solar Probe is headed for the Sun, but itâs flying by Venus along the way. This isnât to see the sights â Parker will perform a gravity assist at Venus to help draw its orbit closer to the Sun. Unlike most gravity assists, Parker will actually slow down, giving some orbital energy to Venus, so that it can swing closer to the Sun.
Oneâs not enough, though. Parker Solar Probe will perform similar maneuvers six more times throughout its seven-year mission!
3. Closer to the Sun than ever before
At its closest approach toward the end of its seven-year prime mission, Parker Solar Probe will swoop within 3.83 million miles of the solar surface. That may sound pretty far, but think of it this way: If you put Earth and the Sun on opposite ends of an American football field, Parker Solar Probe would get within four yards of the Sunâs end zone. The current record-holder was a spacecraft called Helios 2, which came within 27 million miles, or about the 30 yard line. Mercury orbits at about 36 million miles from the Sun.
This will place Parker well within the Sunâs corona, a dynamic part of its atmosphere that scientists think holds the keys to understanding much of the Sunâs activity.
4. Faster than any human-made object
Parker Solar Probe will also break the record for the fastest spacecraft in history. On its final orbits, closest to the Sun, the spacecraft will reach speeds up to 430,000 mph. Thatâs fast enough to travel from New York to Tokyo in less than a minute!
5. Dr. Eugene Parker, mission namesake
Parker Solar Probe is named for Dr. Eugene Parker, the first person to predict the existence of the solar wind. In 1958, Parker developed a theory showing how the Sunâs hot corona â by then known to be millions of degrees Fahrenheit â is so hot that it overcomes the Sunâs gravity. According to the theory, the material in the corona expands continuously outwards in all directions, forming a solar wind.
This is the first NASA mission to be named for a living person, and Dr. Parker watched the launch with the mission team from Kennedy Space Center in Florida.
6. Unlocking the secrets of the solar wind
Even though Dr. Parker predicted the existence of the solar wind 60 years ago, thereâs a lot about it we still donât understand. We know now that the solar wind comes in two distinct streams, fast and slow. Weâve identified the source of the fast solar wind, but the slow solar wind is a bigger mystery.
Right now, our only measurements of the solar wind happen near Earth, after it has had tens of millions of miles to blur together, cool down and intermix. Parkerâs measurements of the solar wind, just a few million miles from the Sunâs surface, will reveal new details that should help shed light on the processes that send it speeding out into space.
7. Studying near-light speed particles
Another question we hope to answer with Parker Solar Probe is how some particles can accelerate away from the Sun at mind-boggling speeds â more than half the speed of light, or upwards of 90,000 miles per second. These particles move so fast that they can reach Earth in under half an hour, so they can interfere with electronics on board satellites with very little warning.
8. The mystery of the coronaâs high heat
The third big question we hope to answer with this mission is something scientists call the coronal heating problem. Temperatures in the Sunâs corona, where Parker Solar Probe will fly, spike upwards of 2 million degrees Fahrenheit, while the Sunâs surface below simmers at a balmy 10,000 F. How the corona gets so much hotter than the surface remains one of the greatest unanswered questions in astrophysics.
Though scientists have been working on this problem for decades with measurements taken from afar, we hope measurements from within the corona itself will help us solve the coronal heating problem once and for all.
9. Why wonât Parker Solar Probe melt?
The corona reaches millions of degrees Fahrenheit, so how can we send a spacecraft there without it melting?
The key lies in the distinction between heat and temperature. Temperature measures how fast particles are moving, while heat is the total amount of energy that they transfer. The corona is incredibly thin, and there are very few particles there to transfer energy â so while the particles are moving fast (high temperature), they donât actually transfer much energy to the spacecraft (low heat).
Itâs like the difference between putting your hand in a hot oven versus putting it in a pot of boiling water (donât try this at home!). In the air of the oven, your hand doesnât get nearly as hot as it would in the much denser water of the boiling pot.
10. Engineered to thrive in an extreme environment
Make no mistake, the environment in the Sunâs atmosphere is extreme â hot, awash in radiation, and very far from home â but Parker Solar Probe is engineered to survive.
The spacecraft is outfitted with a cutting-edge heat shield made of a carbon composite foam sandwiched between two carbon plates. The heat shield is so good at its job that, even though the front side will receive the full brunt of the Sunâs intense light, reaching 2,500 F, the instruments behind it, in its shadow, will remain at a cozy 85 F.
Even though Parker Solar Probeâs solar panels â which provide the spacecraftâs power â are retractable, even the small bit of surface area that peeks out near the Sun is enough to make them prone to overheating. So, to keep its cool, Parker Solar Probe circulates a single gallon of water through the solar arrays. The water absorbs heat as it passes behind the arrays, then radiates that heat out into space as it flows into the spacecraftâs radiator.
For much of its journey, Parker Solar Probe will be too far from home and too close to the Sun for us to command it in real time â but donât worry, Parker Solar Probe can think on its feet. Along the edges of the heat shieldâs shadow are seven sensors. If any of these sensors detect sunlight, they alert the central computer and the spacecraft can correct its position to keep the sensors â and the rest of the instruments â safely protected behind the heat shield.
Read the web version of this weekâs âSolar System: 10 Things to Knowâ article HERE.
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Solar System 10 Things: Looking Back at Pluto
In July 2015, we saw Pluto up close for the first time andâafter three years of intense studyâthe surprises keep coming. âItâs clear,â says Jeffery Moore, New Horizonsâ geology team lead, âPluto is one of the most amazing and complex objects in our solar system.â
1. An Improving View
These are combined observations of Pluto over the course of several decades. The first frame is a digital zoom-in on Pluto as it appeared upon its discovery by Clyde Tombaugh in 1930. More frames show of Pluto as seen by the Hubble Space Telescope. The final sequence zooms in to a close-up frame of Pluto taken by our New Horizons spacecraft on July 14, 2015.
2. The Heart
Plutoâs surface sports a remarkable range of subtle colors are enhanced in this view to a rainbow of pale blues, yellows, oranges, and deep reds. Many landforms have their own distinct colors, telling a complex geological and climatological story that scientists have only just begun to decode. The image resolves details and colors on scales as small as 0.8 miles (1.3 kilometers). Zoom in on the full resolution image on a larger screen to fully appreciate the complexity of Plutoâs surface features.
3. The Smiles
July 14, 2015: New Horizons team members Cristina Dalle Ore, Alissa Earle and Rick Binzel react to seeing the spacecraftâs last and sharpest image of Pluto before closest approach.
4. Majestic Mountains
Just 15 minutes after its closest approach to Pluto, the New Horizons spacecraft captured this near-sunset view of the rugged, icy mountains and flat ice plains extending to Plutoâs horizon. The backlighting highlights more than a dozen layers of haze in Plutoâs tenuous atmosphere. The image was taken from a distance of 11,000 miles (18,000 kilometers) to Pluto; the scene is 780 miles (1,250 kilometers) wide.
5. Icy Dunes
Found near the mountains that encircle Plutoâs Sputnik Planitia plain, newly discovered ridges appear to have formed out of particles of methane ice as small as grains of sand, arranged into dunes by wind from the nearby mountains.
6. Glacial Plains
The vast nitrogen ice plains of Plutoâs Sputnik Planitia â the western half of Plutoâs âheartââcontinue to give up secrets. Scientists processed images of Sputnik Planitia to bring out intricate, never-before-seen patterns in the surface textures of these glacial plains.
7. Colorful and Violent Charon
High resolution images of Plutoâs largest moon, Charon, show a surprisingly complex and violent history. Scientists expected Charon to be a monotonous, crater-battered world; instead, they found a landscape covered with mountains, canyons, landslides, surface-color variations and more.
8. Ice Volcanoes
One of two potential cryovolcanoes spotted on the surface of Pluto by the New Horizons spacecraft. This feature, known as Wright Mons, was informally named by the New Horizons team in honor of the Wright brothers. At about 90 miles (150 kilometers) across and 2.5 miles (4 kilometers) high, this feature is enormous. If it is in fact an ice volcano, as suspected, it would be the largest such feature discovered in the outer solar system.
9. Blue Rays
Plutoâs receding crescent as seen by New Horizons at a distance of 120,000 miles (200,000 kilometers). Scientists believe the spectacular blue haze is a photochemical smog resulting from the action of sunlight on methane and other molecules in Plutoâs atmosphere. These hydrocarbons accumulate into small haze particles, which scatter blue sunlightâthe same process that can make haze appear bluish on Earth.
10. Encore
On Jan. 1, 2019, New Horizons will fly past a small Kuiper Belt Object named MU69 (nicknamed Ultima Thule)âa billion miles (1.5 billion kilometers) beyond Pluto and more than four billion miles (6.5 billion kilometers) from Earth. It will be the most distant encounter of an object in historyâso farâand the second time New Horizons has revealed never-before-seen landscapes.
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Seekofel by Isabella Tabacchi

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Moon phases over Mount Saint Helens
by Filip ZrnzeviÄ
French astronaut Thomas Pesquet has some thoughts on Trumpâs environmentally policy - Like BRUT on FB for more content
-This program has no disk. Another stray.
-Wait! Iâm not a program!
Tron Legacy (2010) by Joseph Kosinski

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Solar System 10 Things to Know: Planetary Atmospheres
Every time you take a breath of fresh air, itâs easy to forget you can safely do so because of Earthâs atmosphere. Life on Earth could not exist without that protective cover that keeps us warm, allows us to breathe and protects us from harmful radiationâamong other things.
What makes Earthâs atmosphere special, and how do other planetsâ atmospheres compare? Here are 10 tidbits:
1. On Earth, we live in the troposphere, the closest atmospheric layer to Earthâs surface. âTroposâ means âchange,â and the name reflects our constantly changing weather and mixture of gases.Â
Itâs 5 to 9 miles (8 to 14 kilometers) thick, depending on where you are on Earth, and itâs the densest layer of atmosphere. When we breathe, weâre taking in an air mixture of about 78 percent nitrogen, 21 percent oxygen and 1 percent argon, water vapor and carbon dioxide. More on Earthâs atmosphereâş
2. Mars has a very thin atmosphere, nearly all carbon dioxide. Because of the Red Planetâs low atmospheric pressure, and with little methane or water vapor to reinforce the weak greenhouse effect (warming that results when the atmosphere traps heat radiating from the planet toward space), Marsâ surface remains quite cold, the average surface temperature being about -82 degrees Fahrenheit (minus 63 degrees Celsius). More on the greenhouse effectâş
3. Venusâ atmosphere, like Marsâ, is nearly all carbon dioxide. However, Venus has about 154,000 times more carbon dioxide in its atmosphere than Earth (and about 19,000 times more than Mars does), producing a runaway greenhouse effect and a surface temperature hot enough to melt lead. A runaway greenhouse effect is when a planetâs atmosphere and surface temperature keep increasing until the surface gets so hot that its oceans boil away. More on the greenhouse effectâş
4. Jupiter likely has three distinct cloud layers (composed of ammonia, ammonium hydrosulfide and water) in its âskiesâ that, taken together, span an altitude range of about 44 miles (71 kilometers). The planetâs fast rotationâspinning once every 10 hoursâcreates strong jet streams, separating its clouds into dark belts and bright zones wrapping around the circumference of the planet. More on Jupiterâş
5. Saturnâs atmosphereâwhere our Cassini spacecraft ended its 13 extraordinary years of exploration of the planetâhas a few unusual features. Its winds are among the fastest in the solar system, reaching speeds of 1,118 miles (1,800 kilometers) per hour. Saturn may be the only planet in our solar system with a warm polar vortex (a mass of swirling atmospheric gas around the pole) at both the North and South poles. Also, the vortices have âeye-wall clouds,â making them hurricane-like systems like those on Earth.
Another uniquely striking feature is a hexagon-shaped jet streamencircling the North Pole. In addition, about every 20 to 30 Earth years, Saturn hosts a megastorm (a great storm that can last many months). More on Saturnâş
6. Uranus gets its signature blue-green color from the cold methane gas in its atmosphere and a lack of high clouds. The planetâs minimum troposphere temperature is 49 Kelvin (minus 224.2 degrees Celsius), making it even colder than Neptune in some places. Its winds move backward at the equator, blowing against the planetâs rotation. Closer to the poles, winds shift forward and flow with the planetâs rotation. More on Uranusâş
7. Neptune is the windiest planet in our solar system. Despite its great distance and low energy input from the Sun, wind speeds at Neptune surpass 1,200 miles per hour (2,000 kilometers per hour), making them three times stronger than Jupiterâs and nine times stronger than Earthâs. Even Earthâs most powerful winds hit only about 250 miles per hour (400 kilometers per hour). Also, Neptuneâs atmosphere is blue for the very same reasons as Uranusâ atmosphere. More on Neptuneâş
8. WASP-39b, a hot, bloated, Saturn-like exoplanet (planet outside of our solar system) some 700 light-years away, apparently has a lot of water in its atmosphere. In fact, scientists estimate that it has about three times as much water as Saturn does. More on this exoplanetâş
9. A weather forecast on âhot Jupitersââblistering, Jupiter-like exoplanets that orbit very close to their starsâmight mention cloudy nights and sunny days, with highs of 2,400 degrees Fahrenheit (about 1,300 degrees Celsius, or 1,600 Kelvin). Their cloud composition depends on their temperature, and studies suggest that the clouds are unevenly distributed. More on these exoplanetsâş
10. 55 Cancri e, a âsuper Earthâ exoplanet (a planet outside of our solar system with a diameter between Earthâs and Neptuneâs) that may be covered in lava, likely has an atmosphere containing nitrogen, water and even oxygenâmolecules found in our atmosphereâbut with much higher temperatures throughout. Orbiting so close to its host star, the planet could not maintain liquid water and likely would not be able to support life. More on this exoplanetâş
Read the full version of this weekâs Solar System 10 Things to Know HERE.
Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com. Â
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by Pedro Gabriel
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10 Things:Â Journey to the Center of Mars
May the fifth be with you because history is about to be made: As early as May 5, 2018, weâre set to launch Mars InSight, the very first mission to study the deep interior of Mars. Weâve been roaming the surface of Mars for a while now, but when InSight lands on Nov. 26, 2018, weâre going in for a deeper look. Below, 10 things to know as we head to the heart of Mars.
Coverage of prelaunch and launch activities begins Thursday, May 3, on NASA Television and our homepage.
1. Whatâs in a name?Â
âInsightâ is to see the inner nature of something, and the InSight landerâa.k.a. Interior Exploration using Seismic Investigations, Geodesy and Heat Transportâwill do just that. InSight will take the âvital signsâ of Mars: its pulse (seismology), temperature (heat flow) and reflexes (radio science). It will be the first thorough check-up since the planet formed 4.5 billion years ago.
2. Marsquakes.Â
You read that right: earthquakes, except on Mars. Scientists have seen a lot of evidence suggesting Mars has quakes, and InSight will try to detect marsquakes for the first time. By studying how seismic waves pass through the different layers of the planet (the crust, mantle and core), scientists can deduce the depths of these layers and what theyâre made of. In this way, seismology is like taking an X-ray of the interior of Mars.
Want to know more? Check out this one-minute video.
3. More than Mars.Â
InSight is a Mars mission, but itâs also so much more than that. By studying the deep interior of Mars, we hope to learn how other rocky planets form. Earth and Mars were molded from the same primordial stuff more than 4.5 billion years ago, but then became quite different. Why didnât they share the same fate? When it comes to rocky planets, weâve only studied one in great detail: Earth. By comparing Earthâs interior to that of Mars, InSightâs team hopes to better understand our solar system. What they learn might even aid the search for Earth-like planets outside our solar system, narrowing down which ones might be able to support life.
4. Robot testing.Â
InSight looks a bit like an oversized crane game: When it lands on Mars this November, its robotic arm will be used to grasp and move objects on another planet for the first time. And like any crane game, practice makes it easier to capture the prize.
Want to see what a Mars robot test lab is like? Take a 360 tour.
5. The gangâs all here.Â
InSight will be traveling with a number of instruments, from cameras and antennas to the heat flow probe. Get up close and personal with each one in our instrument profiles.
6. Trifecta.Â
InSight has three major parts that make up the spacecraft: Cruise Stage; Entry, Descent, and Landing System; and the Lander. Find out what each one does here.
7. Solar wings.Â
Mars has weak sunlight because of its long distance from the Sun and a dusty, thin atmosphere. So InSightâs fan-like solar panels were specially designed to power InSight in this environment for at least one Martian year, or two Earth years.
8. Clues in the crust.Â
Our scientists have found evidence that Marsâ crust is not as dense as previously thought, a clue that could help researchers better understand the Red Planetâs interior structure and evolution. âThe crust is the end-result of everything that happened during a planetâs history, so a lower density could have important implications about Marsâ formation and evolution,â said Sander Goossens of our Goddard Space Flight Center in Greenbelt, Maryland.
9. Passengers.Â
InSight wonât be flying soloâit will have two microchips on board inscribed with more than 2.4 million names submitted by the public. âItâs a fun way for the public to feel personally invested in the mission,â said Bruce Banerdt of our Jet Propulsion Laboratory, the missionâs principal investigator. âWeâre happy to have them along for the ride.â
10. Tiny CubeSats, huge firsts.Â
The rocket that will loft InSight beyond Earth will also launch a separate NASA technology experiment: two mini-spacecraft called Mars Cube One, or MarCO. These suitcase-sized CubeSats will fly on their own path to Mars behindInSight. Their goal is to test new miniaturized deep space communication equipment and, if the MarCOs make it to Mars, may relay back InSight data as it enters the Martian atmosphere and lands. This will be a first test of miniaturized CubeSat technology at another planet, which researchers hope can offer new capabilities to future missions.
Check out the full version of âSolar System: 10 Thing to Know This Weekâ HERE.Â
Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com.Â
Seinäjoki, Finland by Mika Luoma

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by Dmitry Bayer
Earth: Your Home, Our Mission
We pioneer and support an amazing range of advanced technologies and tools to help us better understand our home planet, the solar system and far beyond.
Here are 5 ways our tech improves life here on EarthâŚ
1. Eyes in the Sky Spot Fires on the Ground
Our Earth observing satellites enable conservation groups to spot and monitor fires across vast rainforests, helping them protect our planet on Earth Day and every day.
2. Helping Tractors Drive Themselves
There has been a lot of talk about self-driving cars, but farmers have already been making good use of self-driving tractors for more than a decade - due in part to a partnership between John Deere and our Jet Propulsion Laboratory.
Growing food sustainably requires smart technology - our GPS correction algorithms help self-driving tractors steer with precision, cutting down on water and fertilizer waste.Â
3. Turning Smartphones into Satellites
On Earth Day (and every day), we get nonstop âEarth selfiesâ thanks to Planet Labsâ small satellites, inspired by smartphones and created by a team at our Ames Research Center. The high res imagery helps conservation efforts worldwide.
4. Early Flood Warnings
Monsoons, perhaps the least understood and most erratic weather pattern in the United States, bring rain vital to agriculture and ecosystems, but also threaten lives and property. Severe flash-flooding is common. Roads are washed out. Miles away from the cloudburst, dry gulches become raging torrents in seconds. The storms are often accompanied by driving winds, hail and barrages of lightning.
We are working to get better forecasting information to the National Oceanic and Atmospheric Administration (NOAA). Our satellites can track moisture in the air - helping forecasters provide an early warning of flash floods from monsoons.
5. Watching the Worldâs Water
Around the world, agriculture is by far the biggest user of freshwater. Thanks in part to infrared imagery from Landsat, operated by the U.S. Geological Survey (USGS), we can now map, in real time, how much water a field is using, helping conserve that precious resource.
We use the vantage point of space to understand and explore our home planet, improve lives and safeguard our future. Our observations of Earthâs complex natural environment are critical to understanding how our planetâs natural resources and climate are changing now and could change in the future.
Join the celebration online by using #NASA4Earth.Â
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