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Friday, July 30, 2021

Day in Review

 

DAY IN REVIEW
NASA’s ECOSTRESS instrument captured ground-surface temperature data over southern Oregon’s Bootleg Fire from July 7 to July 22. Areas in red – the hottest pixels detected – show the fire front, where resources are needed most.
ECOSTRESS Data Incorporated Into New Wildfire Response Tool

The instrument on the International Space Station is uniquely positioned to provide wildfire responders with a high-resolution look at fire progression.

NASA’s ECOsystem Spaceborne Thermal Radiometer Experiment on Space Station (ECOSTRESS) is aiding in the fight against fires in the Western U.S.

As of July 28, 2021, the size of the Bootleg Fire in southern Oregon was more than 410,000 acres, making it the largest wildfire currently burning in the U.S. So far, some 400 buildings and more than 340 vehicles have been destroyed. Wildfire responders have managed to contain about 53% of the fire, and new data from ECOSTRESS is helping.

ECOSTRESS measures surface temperature from the vantage point of the International Space Station, and its ability to observe fires of the Northwest US often twice per day at a high spatial resolution (around 70 meters) makes it ideal for tracking fires. Researchers on the RADR-Fire team at Pacific Northwest National Laboratory have been experimenting with ECOSTRESS data as part of a new tool now being implemented for first responders like the U.S. Forest Service.

In the above visualization, ECOSTRESS is tracking the movement of the Bootleg Fire and identifying its proximity to critical infrastructure -- areas in red represent the hottest pixels ECOSTRESS detected. The extreme heat in those areas indicates the fire front, or where resources are most needed.

The capabilities of ECOSTRESS are unique. Satellites that acquire data more frequently don’t have high-enough resolution to track the fine line of the fire front, and satellites with higher resolution than ECOSTRESS cross over the same area much less frequently (every 5 to 16 days).

Dixie Fire

ECOSTRESS also captured data over Northern California’s Dixie Fire, which has doubled in size to more than 220,000 acres over the last few days. In the Dixie Fire data visualization above, the red areas show the hottest pixels – and fire movement – from July 15 to July 24. The most heavily affected areas are south of Lake Almanor in Plumas County. As of July 27, the Dixie Fire was 23% contained.

More than 7,000 personnel are involved in the wildfire response to the two fires. Although they have many tools in their arsenal, the use of spaceborne data like that provided by ECOSTRESS is still relatively new – and also serves as a good example of the versatility and real-world impact satellite data can provide.

More information about ECOSTRESS can be found at:

https://ecostress.jpl.nasa.gov/

 

Thursday, July 29, 2021

Day in Review

 

DAY IN REVIEW
Metallic Glass Gears Up for ‘Cobots,’ Coatings, and More
Bulk metallic glass could slash prices of collaborative robots and lead to advanced 3D printed metals.
› Read the full story
Clays, Not Water, Are Likely Source of Mars ‘Lakes’
Three studies published in the past month have cast doubt on the premise of subsurface lakes below the Martian south pole.
› Read the full story

 

Monday, July 26, 2021

Day in Review

 

DAY IN REVIEW
A rainforest in Malaysia.
Index Ranks Rainforests’ Vulnerability to Climate and Human Impacts

A new index shows that the world’s rainforests are responding differently to threats like a warming climate and deforestation.

Scientists from NASA’s Jet Propulsion Laboratory in Southern California and other international research institutions have created a tropical rainforest vulnerability index. It will detect and evaluate the vulnerability of these diverse ecosystems to two main categories of threats: the warming and drying climate, and the consequences of human land use such as deforestation and fragmentation from encroaching roads, agricultural fields, and logging.

The index shows that the world’s three major rainforest areas have different degrees of susceptibility to these threats. The Amazon Basin in South America is extremely vulnerable to both climate change and changes in human land use. The Congo Basin in Africa is undergoing the same warming and drying trends as the Amazon but is more resilient. Most Asian rainforests appear to be suffering more from changes in land use than from the changing climate.

“Rainforests are perhaps the most endangered habitat on Earth – the canary in the climate-change coal mine,” said Sassan Saatchi, a JPL scientist and lead author of the new study published today in the journal OneEarth.

These diverse ecosystems are home to more than half of the planet’s life forms and contain more than half of all the carbon in land vegetation. They serve as a natural brake on the rise of carbon dioxide in the atmosphere from fossil fuel burning because they “breathe in” carbon dioxide and store carbon as they grow.

But in the last century, 15 to 20% of rainforests have been cut down, and another 10% have been degraded. Today’s warmer climate, which has led to increasingly frequent and widespread forest fires, is limiting the forests’ capacity to absorb carbon dioxide as they grow while also increasing the rate at which forests release carbon to the atmosphere as they decay or burn.

The National Geographic Society convened a team of scientists and conservationists in 2019 to develop the new index. The index is based on multiple satellite observations and ground-based data from 1982 through 2018, such as Landsat and the Global Precipitation Measurement mission, covering climate conditions, land use, and forest characteristics.

When an ecosystem can no longer recover from stress as quickly or as completely as it used to, that’s a sign of its vulnerability. The researchers correlated data on stressors, such as temperature, water availability, and the extent of degradation with data on how well the forests are functioning: the amount of live biomass, the amount of carbon dioxide plants were absorbing, the amount of water the forests transpire into the atmosphere, the intactness of a forest’s biodiversity, and more. The correlations show how different forests have responded to stressors and how vulnerable the forests are now.

The team then used statistical models to extend trends over time, looking for areas with increasing vulnerability and possible tipping points where rainforests will transition into dry forests or grassy plains.

The data from the tropical rainforest vulnerability index provides scientists with an opportunity to perform more in-depth examinations of natural rainforest processes, such as carbon storage and productivity, changes in energy and water cycles, and changes in biodiversity. Those studies will help scientists understand whether there are tipping points and what they are likely to be. The information can also help policy makers who are planning for conservation and forest restoration activities.

 

Sunday, July 25, 2021

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Thursday, July 22, 2021

Day in Review

 

DAY IN REVIEW
NASA's InSight 'Hears' Peculiar Sounds on Mars
NASA’s InSight Reveals the Deep Interior of Mars

Three papers published today share new details on the crust, mantle, and molten core of the Red Planet.

Before NASA’s InSight spacecraft touched down on Mars in 2018, the rovers and orbiters studying the Red Planet concentrated on its surface. The stationary lander’s seismometer has changed that, revealing details about the planet’s deep interior for the first time.

Three papers based on the seismometer’s data were published today in Science, providing details on the depth and composition of Mars’ crust, mantle, and core, including confirmation that the planet’s center is molten. Earth’s outer core is molten, while its inner core is solid; scientists will continue to use InSight’s data to determine whether the same holds true for Mars.

“When we first started putting together the concept of the mission more than a decade ago, the information in these papers is what we hoped to get at the end,” said InSight’s principal investigator Bruce Banerdt of NASA’s Jet Propulsion Laboratory in Southern California, which leads the mission. “This represents the culmination of all the work and worry over the past decade.”

InSight’s seismometer, called the Seismic Experiment for Interior Structure (SEIS), has recorded 733 distinct marsquakes. About 35 of those – all between magnitudes 3.0 and 4.0 – provided the data for the three papers. The ultrasensitive seismometer enables scientists to “hear” seismic events from hundreds to thousands of miles away.

Peering Into Mars

Seismic waves vary in speed and shape when traveling through different materials inside a planet. Those variations on Mars have given seismologists a way to study the planet’s inner structure. In turn, what the scientists learn about Mars can help improve the understanding of how all rocky planets – including Earth – formed.

Like Earth, Mars heated up as it formed from the dust and larger clumps of meteoritic material orbiting the Sun that helped to shape our early solar system. Over the first tens of millions of years, the planet separated into three distinct layers – the crust, mantle, and core – in a process called differentiation. Part of InSight’s mission was to measure the depth, size, and structure of these three layers.

Each of the papers in Science focuses on a different layer. The scientists found the crust was thinner than expected and may have two or even three sub-layers. It goes as deep as 12 miles (20 kilometers) if there are two sub-layers, or 23 miles (37 kilometers) if there are three.

Beneath that is the mantle, which extends 969 miles (1,560 kilometers) below the surface.

At the heart of Mars is the core, which has a radius of 1,137 miles (1,830 kilometers). Confirming the size of the molten core was especially exciting for the team. “This study is a once-in-a-lifetime chance,” said Simon Stähler of the Swiss research university ETH Zurich, lead author of the core paper. “It took scientists hundreds of years to measure Earth’s core; after the Apollo missions, it took them 40 years to measure the Moon’s core. InSight took just two years to measure Mars’ core.”

Hunting for Wiggles

The earthquakes most people feel come from faults caused by tectonic plates shifting. Unlike Earth, Mars has no tectonic plates; its crust is instead like one giant plate. But faults, or rock fractures, still form in the Martian crust due to stresses caused by the slight shrinking of the planet as it continues to cool.

InSight scientists spend much of their time searching for bursts of vibration in seismograms, where the tiniest wiggle on a line can represent a quake or, for that matter, noise created by wind. If seismogram wiggles follow certain known patterns (and if the wind is not gusting at the same time), there’s a chance they could be a quake.

The initial wiggles are primary, or P, waves, which are followed by secondary, or S, waves. These waves can also show up again later in the seismogram after reflecting off layers inside the planet.

“What we’re looking for is an echo,” said Amir Khan of ETH Zurich, lead author of the paper on the mantle. “We’re detecting a direct sound – the quake – and then listening for an echo off a reflector deep underground.”

These echoes can even help scientists find changes within a single layer, like the sub-layers within the crust.

“Layering within the crust is something we see all the time on Earth,” said Brigitte Knapmeyer-Endrun of the University of Cologne, lead author on the paper about the crust. “A seismogram’s wiggles can reveal properties like a change in porosity or a more fractured layer.”

One surprise is that all of InSight’s most significant quakes appear to have come from one area, Cerberus Fossae, a region volcanically active enough that lava may have flowed there within the last few million years. Orbiting spacecraft have spotted the tracks of boulders that may have rolled down steep slopes after being shaken loose by marsquakes.

Curiously, no quakes have been detected from more prominent volcanic regions, like Tharsis, home to three of the biggest volcanoes on Mars. But it’s possible many quakes – including larger ones – are occurring that InSight can’t detect. That’s because of shadow zones caused by the core refracting seismic waves away from certain areas, preventing a quake’s echo from reaching InSight.

Waiting for the Big One

These results are only the beginning. Scientists now have hard data to refine their models of Mars and its formation, and SEIS detects new marsquakes every day. While InSight’s energy level is being managed, its seismometer is still listening and scientists are hopeful they’ll detect a quake bigger than 4.0.

“We’d still love to see the big one,” said JPL’s Mark Panning, co-lead author of the paper on the crust. “We have to do lots of careful processing to pull the things we want from this data. Having a bigger event would make all of this easier.”

Panning and other InSight scientists will share their findings at 9 a.m. PDT (12 p.m. EDT) on July 23 in a livestreamed discussion on NASA Television, the NASA app, the agency’s website, and multiple agency social media platforms, including the JPL YouTube and Facebook channels.

More About the Mission

JPL manages InSight for NASA’s Science Mission Directorate. InSight is part of NASA’s Discovery Program, managed by the agency’s Marshall Space Flight Center in Huntsville, Alabama. Lockheed Martin Space in Denver built the InSight spacecraft, including its cruise stage and lander, and supports spacecraft operations for the mission.

A number of European partners, including France’s Centre National d’Études Spatiales (CNES) and the German Aerospace Center (DLR), are supporting the InSight mission. CNES provided the Seismic Experiment for Interior Structure (SEIS) instrument to NASA, with the principal investigator at IPGP (Institut de Physique du Globe de Paris). Significant contributions for SEIS came from IPGP; the Max Planck Institute for Solar System Research (MPS) in Germany; the Swiss Federal Institute of Technology (ETH Zurich) in Switzerland; Imperial College London and Oxford University in the United Kingdom; and JPL. DLR provided the Heat Flow and Physical Properties Package (HP3) instrument, with significant contributions from the Space Research Center (CBK) of the Polish Academy of Sciences and Astronika in Poland. Spain’s Centro de Astrobiología (CAB) supplied the temperature and wind sensors.

 

WATCH LIVE TONIGHT: Science + Art: Picturing Discovery - July 22 at 7:00 p.m. (PT)

 

Von Karman Lecture Series - July 2021
Von Karman Lecture Series - July 2021
Science + Art: Picturing Discovery

A scientist and an artist walk into a room… In this STEAM inspired chat, we’ll discuss how science influences art and art, in turn, influences science. We’ll discuss how JPL artists collaborate with scientists to create artistic renderings of scientific discoveries and how artists take information and enhance it through data visualization.

More details

 

Wednesday, July 21, 2021

Day in Review

 

DAY IN REVIEW
A light-colored “paver stone” like the ones seen in this mosaic will be the likely target for first sampling by the Perseverance rover.
NASA Perseverance Mars Rover to Acquire First Sample

The six-wheeler’s science campaign has laid the groundwork for the mission’s next major milestone.

NASA is making final preparations for its Perseverance Mars rover to collect its first-ever sample of Martian rock, which future planned missions will transport to Earth. The six-wheeled geologist is searching for a scientifically interesting target in a part of Jezero Crater called the “Cratered Floor Fractured Rough.”

This important mission milestone is expected to begin within the next two weeks. Perseverance landed in Jezero Crater Feb. 18, and NASA kicked off the rover mission’s science phase June 1, exploring a 1.5-square-mile (4-square-kilometer) patch of crater floor that may contain Jezero’s deepest and most ancient layers of exposed bedrock.

“When Neil Armstrong took the first sample from the Sea of Tranquility 52 years ago, he began a process that would rewrite what humanity knew about the Moon,” said Thomas Zurbuchen, associate administrator for science at NASA Headquarters. “I have every expectation that Perseverance’s first sample from Jezero Crater, and those that come after, will do the same for Mars. We are on the threshold of a new era of planetary science and discovery.”

It took Armstrong 3 minutes and 35 seconds to collect that first Moon sample. Perseverance will require about 11 days to complete its first sampling, as it must receive its instructions from hundreds of millions of miles away while relying on the most complex and capable, as well as the cleanest, mechanism ever to be sent into space – the Sampling and Caching System.

Precision Instruments Working Together

The sampling sequence begins with the rover placing everything necessary for sampling within reach of its 7-foot-long (2-meter-long) robotic arm. It will then perform an imagery survey, so NASA’s science team can determine the exact location for taking the first sample and a separate target site in the same area for “proximity science.”

“The idea is to get valuable data on the rock we are about to sample by finding its geologic twin and performing detailed in-situ analysis,” said science campaign co-lead Vivian Sun, from NASA's Jet Propulsion Laboratory in Southern California. “On the geologic double, first we use an abrading bit to scrape off the top layers of rock and dust to expose fresh, unweathered surfaces, blow it clean with our Gas Dust Removal Tool, and then get up close and personal with our turret-mounted proximity science instruments SHERLOC, PIXL, and WATSON.”

SHERLOC (Scanning Habitable Environments with Raman & Luminescence for Organics & Chemicals), PIXL (Planetary Instrument for X-ray Lithochemistry), and the WATSON (Wide Angle Topographic Sensor for Operations and eNgineering) camera will provide mineral and chemical analysis of the abraded target.

Perseverance’s SuperCam and Mastcam-Z instruments, both located on the rover’s mast, will also participate. While SuperCam fires its laser at the abraded surface, spectroscopically measuring the resulting plume and collecting other data, Mastcam-Z will capture high-resolution imagery.

Working together, these five instruments will enable unprecedented analysis of geological materials at the worksite.

“After our pre-coring science is complete, we will limit rover tasks for a sol, or a Martian day,” said Sun. “This will allow the rover to fully charge its battery for the events of the following day.”

Sampling day kicks off with the sample-handling arm within the Adaptive Caching Assembly retrieving a sample tube, heating it, and then inserting it into a coring bit. A device called the bit carousel transports the tube and bit to a rotary-percussive drill on Perseverance’s robotic arm, which will then drill the untouched geologic “twin” of the rock studied the previous sol, filling the tube with a core sample roughly the size of a piece of chalk.

Perseverance’s arm will then move the bit-and-tube combination back into bit carousel, which will transfer it back into the Adaptive Caching Assembly, where the sample will be measured for volume, photographed, hermetically sealed, and stored. The next time the sample tube contents are seen, they will be in a clean room facility on Earth, for analysis using scientific instruments much too large to send to Mars.

“Not every sample Perseverance is collecting will be done in the quest for ancient life, and we don’t expect this first sample to provide definitive proof one way or the other,” said Perseverance project scientist Ken Farley, of Caltech. “While the rocks located in this geologic unit are not great time capsules for organics, we believe they have been around since the formation of Jezero Crater and incredibly valuable to fill gaps in our geologic understanding of this region – things we’ll desperately need to know if we find life once existed on Mars.”

More About the Mission

A key objective for Perseverance’s mission on Mars is astrobiology, including the search for signs of ancient microbial life. The rover will characterize the planet’s geology and past climate, pave the way for human exploration of the Red Planet, and be the first mission to collect and cache Martian rock and regolith.

The Mars 2020 Perseverance mission is the first step in NASA’s Mars Sample Return Campaign. Subsequent NASA missions, now in development in cooperation with the European Space Agency, would send spacecraft to Mars to collect these sealed samples from the surface and return them to Earth for in-depth analysis.

The Mars 2020 Perseverance mission is part of NASA’s Moon to Mars exploration approach, which includes Artemis missions to the Moon that will help prepare for human exploration of the Red Planet.

JPL is managed for NASA by Caltech in Pasadena, California.

To learn more about Perseverance, visit:

https://nasa.gov/perseverance

and

https://mars.nasa.gov/mars2020/

 

Tuesday, July 20, 2021

Day in Review

 

DAY IN REVIEW
Journey to the Center of Mars With the InSight Lander Team
Scientists will talk about new findings in a question-and-answer session with the news media and public.
› Read the full story
NASA Study Finds Tropical Forests’ Ability to Absorb Carbon Dioxide Is Waning
The finding comes out of an effort to map where vegetation is emitting and soaking up carbon dioxide from the atmosphere.
› Read the full story
Signs of Life on Mars? NASA’s Perseverance Rover Begins the Hunt
After testing a bristling array of instruments on its robotic arm, NASA’s latest Mars rover gets down to business: probing rocks and dust for evidence of past life.
› Read the full story

 

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Monday, July 19, 2021

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Friday, July 16, 2021

Day in Review

 

DAY IN REVIEW
This illustration depicts NASA’s Mars 2020 rover studying rocks with its robotic arm.
NASA to Brief Early Science From Perseverance Mars Rover

Panelists will discuss the rover’s recently started science campaign and groundwork for its next major milestone.

NASA will hold a virtual media briefing at 1 p.m. EDT (10 a.m. PDT) Wednesday, July 21, to discuss early science results from the agency’s Perseverance Mars rover and its preparations to collect the first-ever Martian samples for planned return to Earth.

The briefing will originate from NASA’s Jet Propulsion Laboratory in Southern California, where the Mars 2020 Perseverance rover mission is managed. It will air live on NASA Television, the NASA app, and the agency’s website and livestream on multiple agency social media platforms, including JPL’s YouTube and Facebook channels.

Briefing participants include:

  • Thomas Zurbuchen, associate administrator for science, NASA Headquarters
  • Jennifer Trosper, Perseverance project manager, JPL
  • Olivier Toupet, Perseverance enhanced navigation team lead, JPL
  • Ken Farley, Perseverance project scientist, Caltech
  • Vivian Sun, Perseverance science campaign co-lead, JPL

Members of the public also may ask questions on social media during the briefing using #AskNASA.

Perseverance landed in Jezero Crater Feb. 18. The rover team recently wrapped up an initial checkout period, which lasted 90 sols, or Martian days, and which included the Ingenuity Mars Helicopter test flight campaign. Perseverance kicked off the science phase of its mission on June 1.

A key objective for Perseverance’s mission on Mars is astrobiology, including the search for signs of ancient microbial life. The rover will characterize the planet’s geology and past climate, pave the way for human exploration of the Red Planet, and be the first mission to collect and cache Martian rock and regolith.

Subsequent NASA missions, in cooperation with ESA (European Space Agency), would send spacecraft to Mars to collect these sealed samples from the surface and return them to Earth for in-depth analysis.

The Mars 2020 Perseverance mission is part of NASA’s Moon to Mars exploration approach, which includes Artemis missions to the Moon that will help prepare for human exploration of the Red Planet.

JPL is managed for NASA by Caltech in Pasadena, California.

To learn more about Perseverance, visit:

https://nasa.gov/perseverance

and

https://mars.nasa.gov/mars2020/