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Tuesday, July 31, 2018

DAY IN REVIEW

 

DAY IN REVIEW
NASA JPL latest news release
NASA's MISR Views Raging Fires in California

More than a dozen wildfires are burning in the state of California, with several of them threatening life and property. The Ferguson Fire ignited July 13 in the Sierra National Forest west of Yosemite National Park. Much of the forest in this area suffered extreme stress due to the extended drought of 2012 through 2017, and bark beetle damage, leaving many dead trees through which the fire has burned rapidly. Many surrounding towns have been under evacuation orders, and many popular areas of the national park were closed on July 25.

On July 23, another fire ignited northwest of Whiskeytown Lake, a reservoir in northern California. Dubbed the Carr Fire, it remained relatively small through July 25, but advanced rapidly toward the city of Redding the following day, prompting mass evacuations.

The Multi-angle Imaging SpectroRadiometer (MISR) instrument on NASA's Terra satellite passed over California on July 27 and July 29, observing the Carr Fire on July 27 and the Ferguson Fire on July 29. The MISR instrument has nine cameras that view Earth at different angles.

It collected images from MISR's nadir (downward-pointing) camera on each day. The angular information from MISR's images is used to calculate the height of the smoke plume, results of which are superimposed on the right-hand side of each figure. The results show that smoke from both fires remained relatively close to the ground, leading to a greater impact on local air quality on these days. The San Joaquin Valley Air Pollution Control District issued an air quality alert July 25 for the entire California Central Valley. A pair of stereo anaglyphs provides a three-dimensional view of the plume. Red-blue glasses with the red lens placed over your left eye are required to observe the 3D effect.

These data were acquired during Terra orbit 98973 and 99002. The smoke plume height calculation was performed using the MISR INteractive eXplorer (MINX) software tool, which is publicly available at:

https://github.com/nasa/MINX

The MISR Plume Height Project maintains a database of global smoke plume heights, accessible at:

https://www-misr.jpl.nasa.gov/getData/accessData/MisrMinxPlumes2/

MISR was built and is managed by NASA's Jet Propulsion Laboratory in Pasadena, California, for NASA's Science Mission Directorate in Washington. The Terra spacecraft is managed by NASA's Goddard Space Flight Center in Greenbelt, Maryland. The MISR data were obtained from the NASA Langley Research Center Atmospheric Science Data Center in Hampton, Virginia. JPL is a division of Caltech in Pasadena.

 

Friday, July 27, 2018

DAY IN REVIEW

 

LATEST NEWS
NASA JPL latest news release
Space Station Experiment Reaches Ultracold Milestone

The International Space Station is officially home to the coolest experiment in space.

NASA's Cold Atom Laboratory (CAL) was installed in the station's U.S. science lab in late May and is now producing clouds of ultracold atoms known as Bose-Einstein condensates. These "BECs" reach temperatures just above absolute zero, the point at which atoms should theoretically stop moving entirely. This is the first time BECs have ever been produced in orbit.

CAL is a multiuser facility dedicated to the study of fundamental laws of nature using ultracold quantum gases in microgravity. Cold atoms are long-lived, precisely controlled quantum particles that provide an ideal platform for the study of quantum phenomena and potential applications of quantum technologies. This NASA facility is the first of its kind in space. It is designed to advance scientists' ability to make precision measurements of gravity, probing long-standing problems in quantum physics (the study of the universe at the very smallest scales), and exploring the wavelike nature of matter.

"Having a BEC experiment operating on the space station is a dream come true," said Robert Thompson, CAL project scientist and a physicist at NASA's Jet Propulsion Laboratory in Pasadena, California. "It's been a long, hard road to get here, but completely worth the struggle, because there's so much we're going to be able to do with this facility."

CAL scientists confirmed last week that the facility has produced BECs from atoms of rubidium, with temperatures as low as 100 nanoKelvin, or one ten-millionth of one Kelvin above absolute zero. (Absolute zero, or zero Kelvin, is equal to minu 459 degrees Fahrenheit, or minus 273 degrees Celsius). That's colder than the average temperature of space, which is about 3 Kelvin (minus 454 degrees Fahrenheit/minus 270 degrees Celsius). But the CAL scientists have their sights set even lower, and expect to reach temperatures colder than what any BEC experiments have achieved on Earth.

At these ultracold temperatures, the atoms in a BEC begin to behave unlike anything else on Earth. In fact, BECs are characterized as a fifth state of matter, distinct from gases, liquids, solids and plasma. In a BEC, atoms act more like waves than particles. The wave nature of atoms is typically only observable at microscopic scales, but BECs make this phenomenon macroscopic, and thus much easier to study. The ultracold atoms all assume their lowest energy state, and take on the same wave identity, becoming indistinguishable from one another. Together, the atom clouds are like a single "super atom," instead of individual atoms.

Not a simple instrument

"CAL is an extremely complicated instrument," said Robert Shotwell, chief engineer of JPL's astronomy and physics directorate, who has overseen the challenging project since February 2017. "Typically, BEC experiments involve enough equipment to fill a room and require near-constant monitoring by scientists, whereas CAL is about the size of a small refrigerator and can be operated remotely from Earth. It was a struggle and required significant effort to overcome all the hurdles necessary to produce the sophisticated facility that's operating on the space station today."

The first laboratory BECs were produced in 1995, but the phenomenon was first predicted 71 years earlier by physicists Satyendra Nath Bose and Albert Einstein. Eric Cornell, Carl Wienman and Wolfgang Ketterle shared the 2001 Nobel Prize in Physics for being the first to create and characterize BECs in the lab. Five science groups, including groups led by Cornell and Ketterle, will conduct experiments with CAL during its first year. Hundreds of BEC experiments have been operated on Earth since the mid-1990s, and a few BEC experiments have even made brief trips to space aboard sounding rockets. But CAL is the first facility of its kind on the space station, where scientists can conduct daily studies of BECs over long periods.

BECs are created in atom traps, or frictionless containers made out of magnetic fields or focused lasers. On Earth, when these traps are shut off, gravity pulls on the ultracold atoms and they can only be studied for fractions of a second. The persistent microgravity of the space station allows scientists to observe individual BECs for five to 10 seconds at a time, with the ability to repeat these measurements for up to six hours per day. As the atom cloud decompresses inside the atom trap, its temperature naturally drops, and the longer the cloud stays in the trap, the colder it gets. This natural phenomenon (that a drop in pressure also means a drop in temperature) is also the reason that a can of spray paint gets cold when the paint is sprayed out: the can's internal pressure is dropping. In microgravity, the BECs can decompress to colder temperatures than any earthbound instrument. Day-to-day operations of CAL require no intervention from the astronauts aboard the station.

In addition to the BECs made from rubidium atoms, the CAL team is working toward making BECs using two different isotopes of potassium atoms.

CAL is currently in a commissioning phase, in which the operations team conducts a long series of tests to fully understand how the CAL facility operates in microgravity.

"There is a globe-spanning team of scientists ready and excited to use this facility," said Kamal Oudrhiri, JPL's mission manager for CAL. "The diverse range of experiments they plan to perform means there are many techniques for manipulating and cooling the atoms that we need to adapt for microgravity, before we turn the instrument over to the principal investigators to begin science operations." The science phase is expected to begin in early September and will last three years.

The Cold Atom Laboratory launched to the space station on May 21, 2018, aboard a Northrop Grumman (formerly Orbital ATK) Cygnus spacecraft from NASA's Wallops Flight Facility in Virginia. Designed and built at JPL, CAL is sponsored by the International Space Station Program at NASA's Johnson Space Center in Houston, and the Space Life and Physical Sciences Research and Applications (SLPSRA) Division of NASA's Human Exploration and Operations Mission Directorate at NASA Headquarters in Washington.

For more information about the Cold Atom Lab, visit:

https://coldatomlab.jpl.nasa.gov/

 

Thursday, July 26, 2018

DAY IN REVIEW

 

DAY IN REVIEW
NASA JPL latest news release
NASA Satellite Image Shows Lava Flow from Hawaii Volcano

New NASA satellite imagery captured a hot lava flow from fissure 8 of Hawaii's Kilauea volcano. The flow from fissure 8 extends from the Leilani Estates to the Pacific Ocean -- with main ocean entry points near Ahalanui.

The imagery, from the Advanced Spaceborne Thermal Emission and Reflection (ASTER) radiometer instrument on NASA's Terra satellite, was taken on Wednesday, July 25. Vegetation is shown in red, and clouds are white. The hot lava flows detected by ASTER's thermal infrared channels are overlaid in yellow. The image covers an area of 9.5 by 11.5 miles (15.3 by 18.6 kilometers).

Fissure 8 is one of the most active fissures of many that have broken ground since Kilauea began erupting in early May. Flying debris from the explosive interaction between lava and water is a serious hazard near ocean entry points. The interaction also creates laze -- plumes laden with hydrochloric acid and volcanic particles -- that can irritate the eyes, lungs and skin.

Kilauea is one of the world's most active volcanoes. It is the youngest and southeastern-most volcano on the Island of Hawaii.

 

Wednesday, July 25, 2018

DAY IN REVIEW

 

DAY IN REVIEW
JPL's 'Martians' Are Coming to Griffith Observatory
On July 30, when Mars and Earth are closer than they've been since 2003, JPL scientists and engineers will be at a free public event at Griffith Observatory in Los Angeles.
› Read the full story
Local Winds Play Key Role in Some Megafires
Drought and overgrown forests are often blamed for major wildfires, but new research shows that localized winds may play a larger role.
› Read the full story

 

Tuesday, July 24, 2018

DAY IN REVIEW

 

DAY IN REVIEW
NASA JPL latest news release
What Looks Like Ceres on Earth?

With its dark, heavily cratered surface interrupted by tantalizing bright spots, Ceres may not remind you of our home planet Earth at first glance. The dwarf planet, which orbits the Sun in the vast asteroid belt between Mars and Jupiter, is also far smaller than Earth (in both mass and diameter). With its frigid temperature and lack of atmosphere, we're pretty sure Ceres can't support life as we know it.

But these two bodies, Ceres and Earth, formed from similar materials in our solar system. And, after combing through thousands of images from NASA's Dawn spacecraft, which has been orbiting Ceres since 2015, scientists have spotted many features on Ceres that look like formations they've seen on Earth.

By looking at similar features on different bodies -- what scientists call "analogs" -- we can learn more about the origins and evolution of these bodies over time. Check out these prominent features of Ceres, and see if you recognize any of their earthly cousins!

Occator Crater on Ceres
Occator Crater on Ceres, with its central bright area called Cerealia Facula. Credit: NASA/JPL-Caltech/UCLA/MPS/DLR/IDA/PSI
Full image and caption

On Ceres: Occator Crater

As Dawn approached Ceres in early 2015, two mysterious gleaming beacons stood out in images: the "bright spots" of Occator Crater. When the spacecraft spiraled into orbits closer to Ceres, higher-resolution images revealed that there are not just two spots, but many. The center of Occator contains a bright, 2,000-foot-high (500-meter-high) dome called the Cerealia Dome, which is covered with bright material. The bright material on top of the dome is called the Cerealia Facula. A collection of smaller bright regions called Vinalia Faculae is clustered on the eastern side of the crater floor.

Thanks to Dawn's observations, scientists think the bright material is made of sodium carbonate and mineral salts. Moreover, Dawn scientists think the Cerealia Dome formed from briny liquid or mushy ice rising from below the surface -- what we call "hydrothermal" activity -- because it involves heat (thermal) and water (hydro).

Scientists have two theories about how this hydrothermal activity happened: either the heat from the impact that formed the crater caused briny liquid or mushy ice to push up on the surface -- so much that it popped out -- or alternatively, the heat from the impact could have enhanced activity related to pre-existing liquid reservoirs just below the surface.

Ibyuk
Ibyuk, an example of a pingo in Canada. Credit: Adam Jones/Flickr user adam_jones/Creative Commons CC BY-NC 2.0
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On Earth: Pingos

When groundwater on Earth freezes, it can push up against the overlying soil, creating a dome-like structure called a "pingo." These structures appear near the Arctic regions of Earth, including Canada's Pingo National Landmark. "The dimensions, shape and 'fractured' top of a pingo resemble the Cerealia Dome, which may have formed from alternating cycles of ice 'punching' up and effusing onto the surface of Ceres," said Lynnae Quick, planetary scientist at the Smithsonian Institution's National Air and Space Museum in Washington.

Panum Crater in the Sierra Nevada Mountains
Panum Crater in the Sierra Nevada Mountains, California. Credit: USGS
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On Earth: Volcanic Domes

Panum Crater at the foot of the Sierra Nevada Mountains in California has rounded edges and fractured summits that remind scientists of the Cerealia Dome, too. Both the Panum dome and the Cerealia dome sit inside pits. Lassen Peak in California, a lava dome, also has a similar shape, as does the dome in the Mount Saint Helens caldera in the state of Washington.

Searles Lake, California
Searles Lake, California. Credit: NASA
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On Earth: Searles Lake

Like Occator Crater, Searles Lake in California's Mojave Desert is famous for bright evaporite minerals -- that is, minerals that remain long after the evaporation of saltwater. Once a lake fed by water from the Sierra Nevada mountains, today Searles is a dried-out lakebed with white mineral deposits. Mining operations collect minerals rich in sodium and potassium for industrial use. These minerals are mostly found in subsurface brines that are pumped to the surface.

Ahuna Mons, Ceres
Ahuna Mons, Ceres' "Lonely Mountain," shown with a vertical exaggeration factor of two. Credit: NASA/JPL-Caltech/UCLA/MPS/DLR/IDA
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On Ceres: Ahuna Mons

Ahuna Mons sticks out on Ceres as a tall, lonely mountain with bright material dusting its slopes. Similar to the material found in Occator, the bright coating is made of sodium carbonate. The leading hypothesis is that Ahuna Mons is a cryovolcano -- a very cold volcano that has erupted with salty water, mud and volatile materials instead of molten rock. Ahuna Mons rises an average of 2.5 miles (4 kilometers) above the surrounding surface, about the same as the height of the summit of Mount Rainier in Washington State. Ahuna Mons doesn't appear to be associated with any impacts, suggesting that Ceres must have had cryovolcanic activity in the recent past.

Hlíðarfjall dome, Iceland
Hlíðarfjall dome, Iceland. Credit: Hansueli Krapf/Wikimedia Commons contributor Simisa/CC BY-SA 3.0
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On Earth: Hlíðarfjall dome, Iceland

While nothing in the solar system is exactly like Ahuna Mons, the Hlíðarfjall dome in Iceland has a similar shape. Both have loose, fine-grained material, and are similar in their proportion of heights and widths. But these mountains are very different in composition. The Icelandic dome formed by silicate volcanic material, whereas Ahuna Mons formed primarily from water and salt, with a minor contribution from silicate minerals. "Despite the chemical differences, however, the materials on Earth and Ceres behave similarly when they protrude out of the crust to form volcanoes," said Ottaviano Ruesch, research scientist at the European Space Agency in the Netherlands.

Chaiten Dome in Chile
Chaiten Dome in Chile. Credit: NASA
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On Earth: Chaitén Dome, Chile

Another volcanic structure reminiscent of Ahuna Mons is Chaitén Dome in Chile, located within a caldera, a cauldron-like volcanic feature. Beyond Earth, the Compton-Belkovich volcanic complex on the Moon contains a dome that seems to have formed by silicate materials erupting. "This means that silicic dome formation is a process not limited to Earth," Ruesch said.

Samhain Catenae pit chains on Ceres
Samhain Catenae pit chains on Ceres. Credit: NASA/JPL-Caltech/UCLA/MPS/DLR/IDA/PSI/LPI
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On Ceres: Samhain Catenae Pit Chains

Ceres is full of craters large and small, but it also has chains of small bowl-shaped or elliptical pits that did not result from impacts. Pit chains, such as Samhain Catenae, are caused by fractures or faults in the subsurface, which formed up to a billion years ago. When the fractures or faults leave behind empty space under the surface, loose material falls in from above -- forming the pits at the surface.

Pit chains in northern Iceland
Pit chains in northern Iceland, just north of the Krafla Volcano. Credit: Google Earth/Emily Martin/Jennifer Whitten
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On Earth: Iceland Pit Chains

Northern Iceland has a system of pit chains related to faults and fractures. Scientists believe these pit chains formed because of seismic events in the 1970s. A 2011 study led by David Ferrill of the Southwest Research Institute in San Antonio finds that the pits resulted from poorly consolidated material falling down into subterranean cavities, which were produced by faults and fractures. "It's possible that stresses derived from material upwelling from deeper within Ceres resulted in parts of the crust being pulled apart, which may have formed the Samhain Catenae," said Jennifer Scully, Dawn scientist at NASA's Jet Propulsion Laboratory, Pasadena, California. Scientists also have mapped similar pit chains on Mars and other solar system bodies.

Haulani Crater on Ceres
Haulani Crater on Ceres. Credit: NASA/JPL-Caltech/UCLA/MPS/DLR/IDA
Full image and caption

On Ceres: Haulani Crater

Haulani Crater, 21 miles (34 kilometers) in diameter, with sharp rims and bright material, is one of the youngest craters on Ceres. Some flow features are associated with a mountainous ridge in the center, while other flow features run outward from the crater's rim toward the surrounding area. Pitted terrain on the crater's floor and northern rim probably formed when an impacting body caused water under the surface -- which had been locked in Ceres' crust -- to vaporize. That's why pitted terrain is additional evidence for water ice as a key component of the crust.

Ries Crater, Germany
Ries Crater, Germany. Credit: Wikimedia Commons contributor Vesta/NASA WorldWind
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On Earth: Ries Crater, Germany

Ries Crater in southern Germany was formed from an impacting meteorite about 15 million years ago. It is an example of a "rampart crater," a crater whose material flowed due to the presence of volatile materials, such as water, when the meteorite hit. Although Ceres does not have craters that are exactly "rampart" in nature, some of the craters on Ceres such as Haulani do have flow features in their ejecta blankets -- the layers of rock that were overturned and deposited around the crater as during the impact event. "Ries also has clusters of pipe-like structures in the bedrock that are the basis for our understanding of the formation of pitted materials on Mars, Vesta, and Ceres," said Hanna Sizemore, research scientist at the Planetary Science Institute, Tucson, Arizona.

Three kinds of landslides on Ceres
Three kinds of landslides on Ceres. Credit: NASA/JPL-Caltech/UCLA/MPS/DLR/IDA
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On Ceres: Landslides

Dawn has revealed many landslides on Ceres, which may have been shaped by the presence of water ice. This image shows three different kinds of landslides on Ceres. At left, Ghanan Crater hosts an example of a Type I landslide, which is relatively round and large and has thick deposits, or "toes," at its end. Type II and Type III features are shown in the middle and right of this image respectively. Scientists think Type I landslides form in areas where the ground is rich in ice, which may occur near Ceres' poles. Type II landslides are often thinner and longer than Type 1. Type III landslides form in ice-rich ejected material from impacts.

The Mud Creek landslide, California
The Mud Creek landslide, California. Credit: USGS
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On Earth:

Landslides can occur anywhere on Earth where the ground along a slope becomes unstable, such as last year's landslide in northern California. A hillside called Mud Creek collapsed in May 2017 after the area had received substantial rainfall, increasing the amount of groundwater in the area. The way the rock and dirt slid down over Highway 1 into the ocean resembles the way the mixture of ice and rock skidded down Ghanan Crater on Ceres. In some cases, water or ice in the ground can increase the likeliness of landslide occurrence

The Dawn mission is managed by JPL for NASA's Science Mission Directorate in Washington. Dawn is a project of the directorate's Discovery Program, managed by NASA's Marshall Space Flight Center in Huntsville, Alabama. JPL is responsible for overall Dawn mission science. Orbital ATK Inc., in Dulles, Virginia, designed and built the spacecraft. The German Aerospace Center, Max Planck Institute for Solar System Research, Italian Space Agency and Italian National Astrophysical Institute are international partners on the mission team.

For a complete list of mission participants, visit:

https://dawn.jpl.nasa.gov/mission

More information about Dawn is available at the following sites:

https://www.nasa.gov/dawn

https://dawn.jpl.nasa.gov

 

Monday, July 23, 2018

DAY IN REVIEW

 

DAY IN REVIEW
Radiation Maps of Jupiter's Moon Europa: Key to Future Missions
New comprehensive mapping of the radiation pummeling Jupiter's icy moon Europa reveals where scientists should look.
› Read the full story
Twenty Years of Planetary Defense
NASA's Center for Near-Earth Object Studies enters its third decade of predicting possible impacts.
› Read the full story
NASA's 'Space Botanist' Gathers First Data
Days after its successful installation on the International Space Station, ECOSTRESS has collected its first science data on Earth's surface temperature.
› Read the full story

 

Thursday, July 19, 2018

'Storm Chasers' on Mars Searching for Dusty Secrets

 

DAY IN REVIEW
NASA JPL latest news release
'Storm Chasers' on Mars Searching for Dusty Secrets

Storm chasing takes luck and patience on Earth -- and even more so on Mars.

For scientists watching the Red Planet from data gathered by NASA's orbiters, the past month has been a windfall. "Global" dust storms, where a runaway series of storms creates a dust cloud so large it envelops the planet, only appear every six to eight years (that's three to four Mars years). Scientists still don't understand why or how exactly these storms form and evolve.

In June, one of these dust events rapidly engulfed the planet. Scientists first observed a smaller-scale dust storm on May 30. By June 20, it had gone global.

For the Opportunity rover, that meant a sudden drop in visibility from a clear, sunny day to that of an overcast one. Because Opportunity runs on solar energy, scientists had to suspend science activities to preserve the rover's batteries. As of July 18th, no response has been received from the rover.

Luckily, all that dust acts as an atmospheric insulator, keeping nighttime temperatures from dropping down to lower than what Opportunity can handle. But the nearly 15-year-old rover isn't out of the woods yet: it could take weeks, or even months, for the dust to start settling. Based on the longevity of a 2001 global storm, NASA scientists estimate it may be early September before the haze has cleared enough for Opportunity to power up and call home.

When the skies begin to clear, Opportunity's solar panels may be covered by a fine film of dust. That could delay a recovery of the rover as it gathers energy to recharge its batteries. A gust of wind would help, but isn't a requirement for a full recovery..

While the Opportunity team waits in earnest to hear from the rover, scientists on other Mars missions have gotten a rare chance to study this head-scratching phenomenon.

The Mars Reconnaissance Orbiter, Mars Odyssey, and Mars Atmosphere and Volatile EvolutioN (MAVEN) orbiters are all tailoring their observations of the Red Planet to study this global storm and learn more about Mars' weather patterns. Meanwhile, the Curiosity rover is studying the dust storm from the Martian surface.

Here's Here's how each mission is currently studying the dust storm, and what we might learn from it:

 

Mars Odyssey

With the THEMIS instrument (Thermal Emission Imaging System), scientists can track Mars' surface temperature, atmospheric temperature, and the amount of dust in the atmosphere. This allows them to watch the dust storm grow, evolve, and dissipate over time.

"This is one of the largest weather events that we've seen on Mars," since spacecraft observations began in the 1960s, said Michael Smith, a scientist at NASA's Goddard Spaceflight Center in Greenbelt, Maryland who works on the THEMIS instrument. "Having another example of a dust storm really helps us to understand what's going on."

Since the dust storm began, the THEMIS team has increased the frequency of global atmospheric observations from every 10 days to twice per week, Smith said. One mystery they're still trying to solve: How these dust storms go global. "Every Mars year, during the dusty season, there are a lot of local- or regional-scale storms that cover one area of the planet," Smith said. But scientists aren't yet sure how these smaller storms sometimes grow to end up encircling the entire planet.

Mars Reconnaissance Orbiter (MRO)

Mars Reconnaissance Orbiter has two instruments studying the dust storm. Each day, the Mars Color Imager (MARCI) maps the entire planet in mid-afternoon to track the evolution of the storm. Meanwhile, MRO's Mars Climate Sounder (MCS) instrument measures how the atmosphere's temperature changes with altitude. Since the end of May, the instruments have observed the onset and rapid expansion of a dust storm on Mars.

With these data, scientists are studying how the dust storm changes the planet's atmospheric temperatures. Just as in Earth's atmosphere, changing temperature on Mars can affect wind patterns and even the circulation of the entire atmosphere. This provides a powerful feedback: Solar heating of the dust lofted into the atmosphere changes temperatures, which changes winds, which may amplify the storm by lifting more dust from the surface.

Scientists want to know the details of the storm -- where is the air rising or falling? How do the atmospheric temperatures now compare to a storm-less year? And as with Mars Odyssey, the MRO team wants to know how these dust storms go global.

"The very fact that you can start with something that's a local storm, no bigger than a small [U.S.] state, and then trigger something that raises more dust and produces a haze that covers almost the entire planet is remarkable," said Rich Zurek of NASA's Jet Propulsion Laboratory, Pasadena, California, the project scientist for MRO.

Scientists want to find out why these storms arise every few years, which is hard to do without a long record of such events. It'd be as if aliens were observing Earth and seeing the climate effects of El Niño over many years of observations -- they'd wonder why some regions get extra rainy and some areas get extra dry in a seemingly regular pattern.

MAVEN

Ever since the MAVEN orbiter entered Mars' orbit, "one of the things we've been waiting for is a global dust storm," said Bruce Jakosky, the MAVEN orbiter's principle investigator.

But MAVEN isn't studying the dust storm itself. Rather, the MAVEN team wants to study how the dust storm affects Mars' upper atmosphere, about 62 miles (more than 100 kilometers) above the surface -- where the dust doesn't even reach. MAVEN's mission is to figure out what happened to Mars' early atmosphere. We know that at some point billions of years ago, liquid water pooled and ran along Mars' surface, which means that its atmosphere must have been thicker and more insulating, similar to Earth's. Since MAVEN arrived at Mars in 2014, its investigations have found that this atmosphere may have been stripped away by a torrent of solar wind over several hundred million years, between 3.5 and 4.0 billion years ago.

But there are still nuances to figure out, such as how dust storms like the current one affect how atmospheric molecules escape into space, Jakosky said. For instance, the dust storm acts as an atmospheric insulator, trapping heat from the Sun. Does this heating change the way molecules escape the atmosphere? It is also likely that, as the atmosphere warms, more water vapor rises high enough to be broken down by sunlight, with the solar wind sweeping the hydrogen atoms into space, Jakosky said.

The team won't have answers for a while yet, but each of MAVEN's five orbits per day will continue to provide invaluable data.

Curiosity

Most of NASA's spacecraft are studying the dust storm from above. The Mars Science Laboratory mission's Curiosity rover has a unique perspective: the nuclear-powered science machine is largely immune to the darkened skies, allowing it to collect science from within the beige veil enveloping the planet.

"We're working double-duty right now," said JPL's Ashwin Vasavada, Curiosity's project scientist. "Our newly recommissioned drill is acquiring a fresh rock sample. But we are also using instruments to study how the dust storm evolves."

Curiosity has a number of "eyes" that can determine the abundance and size of dust particles based on how they scatter and absorb light. That includes its Mastcam, ChemCam, and an ultraviolet sensor on REMS, its suite of weather instruments. REMS can also help study atmospheric tides -- shifts in pressure that move as waves across the entire planet's thin air. These tides change drastically based on where the dust is globally, not just inside Gale crater.

The global storm may also reveal secrets about Martian dust devils and winds. Dust devils can occur when the planet's surface is hotter than the air above it. Heating generates whirls of air, some of which pick up dust and become dust devils. During a dust storm, there's less direct sunlight and lower daytime temperatures; this might mean fewer devils swirling across the surface.

Even new drilling can advance dust storm science: watching the small piles of loose material created by Curiosity's drill is the best way of monitoring winds.

Scientists think the dust storm will last at least a couple of months. Every time you spot Mars in the sky in the weeks ahead, remember how much data scientists are gathering to better understand the mysterious weather of the Red Planet.

 

Wednesday, July 18, 2018

NASA Online Toolkit: Commercial Use of Satellite Data

 

DAY IN REVIEW
NASA JPL latest news release
NASA Online Toolkit: Commercial Use of Satellite Data

While NASA's policy of free and open remote-sensing data has long benefited the scientific community, other government agencies and nonprofit organizations, it has significant untapped potential for commercialization. NASA's Technology Transfer program has created an online resource to promote commercial use of this data and the software tools needed to work with it.

With the Remote Sensing Toolkit, users will now be able to find, analyze and utilize the most relevant data for their research, business projects or conservation efforts. The toolkit provides a simple system that quickly identifies relevant sources based on user input. The toolkit will help users search for data, as well as ready-to-use tools and code to build new tools.

"This new tool makes finding and using NASA satellite data easier than ever before, and we hope it sparks innovation among the entrepreneurial community and leads to further commercialization of NASA technology and benefits people across the world," said Daniel Lockney, NASA's Technology Transfer program executive. "Our mission to bring NASA technology down to Earth is expanding with the release of this remote sensing toolkit."

Through its constellation of Earth observation satellites, NASA collects petabytes of data each year. The variety of open source tools created to access, analyze and utilize the data from these satellites is familiar to millions of science users, but accessing and utilizing this data remains daunting for many potential commercial users.

For example, NASA's remote sensing data and tools are spread out across dozens of sites. The NASA Technology Transfer program reviewed more than 50 websites and found that no source provided a comprehensive collection of information or a single access point to begin a search.

While the Remote Sensing Toolkit is new, using NASA satellite data to create commercial products isn't.

"Over the years, many organizations around the world have found innovative ways to turn NASA satellite data into beneficial information products here on Earth," said Kevin Murphy of NASA's Earth Science Division in Washington. "Remote Sensing Toolkit will help grow the number of users who put NASA's free and open data archive to work for people."

NASA Spinoff LandViewer, a subscription-based software, relies on a variety of data, including NASA satellite data, to provide daily updates on the state of corn vegetation. The result is a prediction of future corn production on national, state and county scales.

The Technology Transfer program will host a tutorial of Remote Sensing Toolkit. To participate, potential users should sign up to be notified of future webinars.

NASA's Technology Transfer program, managed by the agency's Space Technology Mission Directorate, ensures technologies developed for missions in exploration and discovery are broadly available to the public, maximizing the benefit to the nation.

Examples of some of these technologies include data from NASA's Jet Propulsion Laboratory, Pasadena, California, from the ASTER mission, that's being used in a snowboarding game to create real-life mountains. This and other examples are featured in a Tumblr post at:

https://nasa.tumblr.com/post/176030762329/5-examples-of-how-our-satellite-data-is-helping

When Electronic Arts (EA) decided to make SSX, a snowboarding video game, it faced challenges in creating realistic-looking mountains. The solution was our ASTER Global Digital Elevation Map, made available by our Jet Propulsion Laboratory, which EA used to create 28 real-life mountains from 9 different ranges for its award-winning game.

For more information about the Remote Sensing Toolkit and NASA's Technology Transfer program, visit:

https://technology.nasa.gov/

 

Monday, July 16, 2018

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DAY IN REVIEW

 

DAY IN REVIEW
NASA JPL latest news release
Dusk for Dawn: Mission of Many Firsts to Gather More Data in Home Stretch

Pasadena Conference to Include New Insight into Dwarf Planet Ceres

As NASA's Dawn spacecraft prepares to wrap up its groundbreaking 11-year mission, which has included two successful extended missions at Ceres, it will continue to explore -- collecting images and other data.

Within a few months, Dawn is expected to run out of a key fuel, hydrazine, which feeds thrusters that control its orientation and keeps it communicating with Earth. When that happens, sometime between August and October, the spacecraft will stop operating, but it will remain in orbit around dwarf planet Ceres.

Dawn is the only spacecraft to orbit two deep-space destinations. It has given us new, up-close views of Ceres and Vesta, the largest bodies between Mars and Jupiter. During 14 months in orbit from 2011 to 2012, Dawn studied Vesta from its surface to its core. It then pulled off an unprecedented maneuver by leaving orbit and traveling through the main asteroid belt for more than two years to reach and orbit Ceres, which it has been investigating since 2015.

At Ceres, the spacecraft discovered brilliant, salty deposits decorating the dwarf planet like a smattering of diamonds. The science behind these bright spots is even more compelling: they are mainly sodium carbonate and ammonium chloride that somehow made their way to the surface in a slushy brine from within or below the crust.

These discoveries were fueled by the tremendous efficiency of ion propulsion. Dawn wasn't the first spacecraft to use ion propulsion, familiar to science-fiction fans as well as space enthusiasts, but it pushed the limits of this advanced propulsion's capabilities and stamina.

"Dawn's unique mission to orbit and explore two strange new worlds would have been impossible without ion propulsion," said Marc Rayman of NASA's Jet Propulsion Laboratory, Pasadena, California, who has served as Dawn's mission director, chief engineer and project manager. "Dawn is truly an interplanetary spaceship, and it has been outstandingly productive as it introduced these fascinating and mysterious worlds to Earth."

These days, near the end of Dawn's second extended mission at Ceres, the spacecraft continues to wow us week after week, with very close photos shot from only 22 miles (35 kilometers) above the dwarf planet -- about three times the altitude of a passenger jet.

But Wait, There's More: New Science to Come

Although the Dawn mission is winding down, the science is not. Besides the high-resolution images, the spacecraft is collecting gamma ray and neutron spectra, infrared and visible spectra, and gravity data. The observations focus on the area around Occator and Urvara craters, with the main goal of understanding the evolution of Ceres, and testing for possible ongoing geology.

"The new images of Occator Crater and the surrounding areas have exceeded expectations, revealing beautiful, alien landscapes," said Carol Raymond of JPL, principal investigator of the Dawn mission. "Ceres' unique surface appears to be shaped by impacts into its volatile-rich crust, resulting in intriguing, complex geology, as we can see in the new high-resolution mosaics of Cerealia Facula and Vinalia Faculae."

The first results of this mission phase, which started in early June, are being presented this week at the Committee on SPAce Research (COSPAR) meeting in Pasadena. Raymond and JPL scientist Jennifer Scully will offer new information on the relationships between bright and dark materials on the floor of Occator Crater, which show impact processes, landslides and cryovolcanism.

Dawn scientists are using new high-resolution data from Dawn to test and refine hypotheses about Occator crater's formation and evolution."Observations, modeling and laboratory studies helped us conclude that the bright spots are either formed by impacts interacting with the crust, or that a reservoir of briny melt contributed to their formation," said Scully.

The new images so far support the hypothesis that exposure of subsurface material in that region is ongoing, and that it is geologically active, feeding from a deep reservoir. Eleonora Ammannito of the Italian Space Agency, deputy lead for the Dawn visible and infrared mapping spectrometer, will present updated maps at the conference showing the distribution of briny materials across Ceres' surface.

Also at COSPAR, Dawn flight team member Dan Grebow of JPL will describe Dawn's final orbit, designed to abide by NASA's planetary protection protocols.

Low-altitude images collected by Dawn are posted regularly to the mission's web page here.

The Dawn mission is managed by JPL for NASA's Science Mission Directorate in Washington. Dawn is a project of the directorate's Discovery Program, managed by NASA's Marshall Space Flight Center in Huntsville, Alabama. JPL is responsible for overall Dawn mission science. Orbital ATK Inc., in Dulles, Virginia, designed and built the spacecraft. The German Aerospace Center, Max Planck Institute for Solar System Research, Italian Space Agency and Italian National Astrophysical Institute are international partners on the mission team.

For a complete list of mission participants, visit:

https://dawn.jpl.nasa.gov/mission

More information about Dawn is available at the following sites:

https://www.nasa.gov/dawn

https://dawn.jpl.nasa.gov