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Image: The Copernicus Sentinel-2 mission takes us over a section of Italy’s heel in the southern part of the boot-shaped peninsula.

Blown by fast winds from a hot, massive star,

Eight former SpaceX employees are suing the company and its founder and CEO, Elon Musk, alleging sexual harassment and wrongful termination.

In 2021, NASA’s Perseverance rover landed in the Jezero Crater on Mars. For the next three years, this astrobiology mission collected soil and rock samples from the crater floor for eventual return to Earth. The analysis of these samples is expected to reveal much about Mars’ past and how it transitioned from being a warmer, wetter place to the frigid and desiccated place we know today. Unfortunately, budget cuts have placed the future of the proposed NASA-ESA Mars Sample Return (MSR) mission in doubt.

As a result, NASA recently announced that it was seeking proposals for more cost-effective and rapid methods of bringing the samples home. This will consist of three studies by NASA and the Johns Hopkins University Applied Physics Laboratory (JHUAPL). In addition, NASA has selected seven commercial partners for firm-fixed-price contracts for up to $1.5 million to conduct their own 90-day studies. Once complete, NASA will consider which proposals to integrate into the MSR mission architecture.

As Administrator Bill Nelson stated in a NASA press release

“Mars Sample Return will be one of the most complex missions NASA has undertaken, and it is critical that we carry it out more quickly, with less risk, and at a lower cost. I’m excited to see the vision that these companies, centers and partners present as we look for fresh, exciting, and innovative ideas to uncover great cosmic secrets from the Red Planet.”

The MSR mission represents the culmination of decades of efforts to learn more about the early history of Mars. NASA had originally hoped that the first crewed mission (planned for 2033) would retrieve the samples and transport them back to Earth. However, delays and budget concerns have led to growing concerns that a crewed mission will not reach Mars until 2040 (at the earliest). As a result, NASA and the European Space Agency adopted a joint mission architecture consisting of multiple robotic elements that would return the samples by 2031.

This included the Sample Retrieval Lander (SRL), two Sample Recovery Helicopters (SRH), the Mars Ascent Vehicle (MAV), the Earth Return Orbiter (ERO), and the Earth Entry System (EES). However, the current budget environment forced NASA to announce that the 15-year MSR mission architecture (which would cost $11 billion) was too expensive and that waiting until 2040 was impractical. As a result, NASA has adopted a revised plan that leverages current technology and will return the Mars samples by the 2030s. As NASA Administrator Bill Nelson said at the time:

“Mars Sample Return will be one of the most complex missions NASA has ever undertaken. The bottom line is, an $11 billion budget is too expensive, and a 2040 return date is too far away. Safely landing and collecting the samples, launching a rocket with the samples off another planet – which has never been done before – and safely transporting the samples more than 33 million miles back to Earth is no small task. We need to look outside the box to find a way ahead that is both affordable and returns samples in a reasonable timeframe.”

In addition to the NASA-led studies, seven aerospace companies have been selected to develop sample-return concepts. They include NASA’s regular commercial partners, such as Lockheed Martin, SpaceX, Aerojet Rocketdyne, Blue Origin, and Northrop Grumman, as well as relative newcomers Quantum Space and Whittinghill Aerospace. A total of $10 million has been awarded to these companies to develop their concepts, the full list of which can be found here.

Once again, NASA is facing a budget crunch and has reached out to its commercial partners to develop cost-effective alternatives. This is in keeping with NASA’s long history of collaborating with the commercial sector to develop key mission concepts. However, the need to outsource major elements of its Moon to Mars program highlights the agency’s ongoing budget problems. As independent experts have concluded, a budget increase is necessary if NASA is to realize its ambitious goals for the future.

Further Reading: NASA

The post NASA is Considering Other Ways of Getting its Mars Samples Home appeared first on Universe Today.

17 Min Read The Next Full Moon is the Strawberry Moon

A perigee full moon, or supermoon, is seen next to the Empire State Building, Sunday, Sept. 27, 2015 in New York City.

Credits:
NASA/Joel Kowsky

The Next Full Moon is the Strawberry Moon; the Flower, Hot, Hoe, or Planting Moon; the Mead or Honey Moon; the Rose Moon; Vat Purnima; Poson Poya; and the LRO Moon.

The next full Moon will be Friday evening, June 21, 2024, appearing opposite the Sun (in Earth-based longitude) at 9:08 PM EDT. This will be Saturday from Greenland and Cape Verde time eastward across Eurasia, Africa, and Australia to the International Date Line in the mid-Pacific. Most commercial calendars will show this full Moon on Saturday, June 22, the date in Coordinated Universal Time (UTC). The Moon will appear full for about three days around this time, from Thursday evening through Sunday morning.

In the 1930s the Maine Farmer’s Almanac began publishing “Indian” names for full Moons and these names are now widely known and used. According to this Almanac, as the full Moon in June this is the Strawberry Moon, a name that comes from the relatively short season for harvesting strawberries in the north-eastern United States. Other seasonal names that I have found in various sources (sometimes with conflicting information about whether they are of European or Native American origin) are the Flower Moon, Hot Moon, Hoe Moon, and Planting Moon.

An old European name for this full Moon is the Mead or Honey Moon. Mead is a drink created by fermenting honey mixed with water and sometimes fruits, spices, grains, or hops. In some countries Mead is also called Honey Wine (though in others Honey Wine is made differently). Some writings suggest the time around the end of June was when honey was ready for harvesting, which made this the “sweetest” Moon. The word “honeymoon” traces back to at least the 1500s in Europe. The tradition of calling the first month of marriage the “honeymoon” may be tied to this full Moon because of the custom of marrying in June or because the “Honey Moon” is the “sweetest” Moon of the year. There doesn’t appear to be enough evidence to support a 19th century theory that the word entered English from the custom of gifting newlyweds mead for their first month of marriage.

Another European name for this full Moon is the Rose Moon. Some sources indicate “Rose Moon” comes from the roses that bloom this time of year. Others indicate that the name comes from the color of the full Moon. The orbit of the Moon around the Earth is in almost the same plane as the orbit of the Earth around the Sun (only about 5 degrees off). On the summer solstice the Sun appears highest in the sky for the year. Full Moons are opposite the Sun, so a full Moon near the summer solstice will be low in the sky. Particularly for Europe’s higher latitudes, when the full Moon is low it shines through more atmosphere, making it more likely to have a reddish color (for the same reasons that sunrises and sunsets are red). For the Washington, DC area, the full Moon on the night from the evening of June 21 to the morning of June 22 will have the lowest full Moon of the year, reaching only 21.9 degrees above the southern horizon at 1:20 AM EDT.

For Hindus this is Vat Purnima. During the 3 days of this full Moon married women will show their love for their husbands by tying a ceremonial thread around a banyan tree. The celebration is based on the legend of Savitri and Satyavan.

For Buddhists this full Moon is Poson Poya. The Poson holiday in Sri Lanka celebrates the introduction of Buddhism in 236 BCE.

Another tribe has also given a name to this full Moon. This tribe is now scattered but mostly lived in the mid-Atlantic region of the United States. This tribe’s language is primarily English, but with a liberal smattering of acronyms, arcane scientific and engineering terms, and Hawaiian phrases (cheerfully contributed by the former Deputy Project Manager). Comprised of people from all backgrounds, many of whom have gone on to join other tribes, this tribe was devoted to the study of the Moon. This tribe calls June’s full Moon the LRO Moon, in honor of the spacecraft they launched towards the Moon 15 years ago, on June 18, 2009. NASA’s Lunar Reconnaissance Orbiter is still orbiting the Moon providing insights about our nearest celestial neighbor, some of which help us understand our own planet. See https://www.nasa.gov/mission_pages/LRO/main/index.html for more information.

Many lunar and lunisolar calendars start the months on or just after the new Moon and the full Moon is near the middle of the month. This full Moon is near the middle of the fifth month of the Chinese year of the Dragon, Sivan in the Hebrew calendar, and Dhu al-Hijjah, the final month of the Islamic year and one of the four sacred months during which fighting is forbidden.

As usual, the wearing of suitably celebratory celestial attire is encouraged in honor of the full Moon. If you’re not allergic, enjoy the strawberries, flowers, and honey during this “sweetest” month of the year, and take note of how low in the sky this full Moon will be.

As for other celestial events between now and the full Moon after next (with specific times and angles based on the location of NASA Headquarters in Washington, DC):

As summer begins the daily periods of sunlight start to gradually shorten, having been at their longest on the summer solstice on the day before this full Moon. On Friday, June 21, 2024 (the day of the full Moon), morning twilight will begin at 4:30 AM, sunrise will be at 5:43 AM, solar noon at 1:10 PM when the Sun will reach its maximum altitude of 74.6 degrees, sunset will be at 8:37 PM, and evening twilight will end at 9:49 PM. The period of daylight will be 1.2 seconds shorter than on the summer solstice the previous day.

The solar days (as measured, for example, from solar noon to solar noon on a sundial) are longer than 24 hours near the solstices, so the earliest sunrises of the year occur before the summer solstice and the latest sunsets occur after the solstice. For the Washington, DC area and similar latitudes at least (I’ve not checked for other latitudes), Thursday, June 27, will have the latest sunset of the year, with sunset at 8:37:30 PM EDT.

By Sunday, July 21, (the day of the full Moon after next), morning twilight will begin at 4:52 AM, sunrise will be at 6:00 AM, solar noon at 1:15 PM when the Sun will reach its maximum altitude of 71.4 degrees, sunset will be at 8:28 PM, and evening twilight will end at 9:37 PM.

The comet 13P/Olbers is expected to peak at magnitude 7.5 in early July, too dim to see with the naked eye. The two meteor showers expected to peak this lunar cycle will be difficult to see. The full Moon will interfere with the peak of the June Bootids (170 JBO) on June 27. The July Pegasids (175 JPE), peaking on July 10, is only expected to show 3 meteors per hour (under ideal conditions).

Evening Sky Highlights:

On the evening of Friday, June 21, 2024 (the evening of the day of the full Moon), as twilight ends (at 9:49 PM EDT), the rising Moon will be 7 degrees above the southeastern horizon. The bright planets Venus and Mercury will be below the horizon, with Venus setting 21 minutes and Mercury setting 43 minutes after sunset. Mercury may be visible from about 30 minutes after sunset until it sets 13 minutes later. The bright object appearing closest to overhead will be the star Arcturus at 69 degrees above the south-southwestern horizon. Arcturus is the brightest star in the constellation Boötes the herdsman or plowman. It is the 4th brightest star in our night sky and is 36.7 light years from us. While it has about the same mass as our Sun, it is about 2.6 billion years older and has used up its core hydrogen, becoming a red giant 25 times the size and 170 times the brightness of our Sun.

As this lunar cycle progresses the background of stars will appear to shift westward each evening (as the Earth moves around the Sun). June 30 will be the first evening that the bright planet Mercury will be above the west-northwestern horizon as evening twilight ends and the first evening that the bright planet Venus will be above the horizon 30 minutes after sunset (an approximation of when Venus will start emerging from the glow of dusk. Mercury will shift to the left low along the horizon, reaching its highest above the horizon (just 2 degrees as twilight ends) on July 13. The waxing Moon will pass by Regulus on July 8 and 9, Spica on July 13, and Antares on July 17.

By the evening of Sunday, July 21 (the evening of the day of the full Moon after next), as twilight ends (at 9:37 PM EDT), the rising Moon will be 3 degrees above the east-southeastern horizon. The bright planet Mercury will be 1 degree above the west-northwestern horizon and 6 minutes away from setting. The planet Venus will set 22 minutes before twilight ends, but will be bright enough to see in the glow of dusk low on the west-northwestern horizon before it sets. The bright object appearing closest to overhead will be Vega, the brightest star in the constellation Lyra the lyre, at 65 degrees above the eastern horizon. Vega is one of the three bright stars in the Summer Triangle along with Deneb, and Altair. Vega is the 5th brightest star in our night sky, about 25 light-years from Earth, has twice the mass of our Sun, and shines 40 times brighter than our Sun.

Morning Sky Highlights:

On the morning of Friday, June 21, 2024 (the morning of the day of the full Moon), as twilight begins (at 4:31 AM EDT), the setting full Moon will be 2 degrees above the southwestern horizon. The brightest planet in the sky will be Jupiter at just 3 degrees above the east-northeastern horizon. The planet Mars will be 19 degrees above the eastern horizon and the planet Saturn (almost as bright as Mars) will be 37 degrees above the southeastern horizon. The bright object appearing closest to overhead will be the star Deneb at 80 degrees above the northwestern horizon. Deneb is the 19th brightest star in our night sky and is the brightest star in the constellation Cygnus the swan. Deneb is one of the three bright stars of the “Summer Triangle” (along with Vega and Altair). Deneb is about 20 times more massive than our Sun but has used up its hydrogen, becoming a blue-white supergiant about 200 times the diameter of the Sun. If Deneb were where our Sun is, it would extend to about the orbit of the Earth. Deneb is about 2,600 light years from us.

As this lunar cycle progresses, Jupiter, Saturn, and the background of stars will appear to shift westward each evening, with Mars shifting more slowly and to the left. The waning Moon will pass by Saturn on June 27, on Mars on July 1, the Pleiades star cluster on July 2, and Jupiter on July 3.

By the morning of Sunday, July 21 (the morning of the day of the full Moon after next), as twilight begins (at 4:52 AM EDT), the setting full Moon will be 7 degrees above the southwestern horizon. The brightest planet in the sky will be Jupiter at 25 degrees above the eastern horizon. Mars will be 33 degrees above the eastern horizon and Saturn 45 degrees above the southern horizon. The bright object appearing closest to overhead still will be the star Deneb at 56 degrees above the west-northwestern horizon.

Detailed Daily Guide:

Here for your reference is a day-by-day listing of celestial events between now and the full Moon after next. The times and angles are based on the location of NASA Headquarters in Washington, DC, and some of these details may differ for where you are (I use parentheses to indicate times specific to the DC area).

Sunday morning, June 16, 2024, will be the first morning that the bright planet Jupiter will be above the east-northeastern horizon as morning twilight begins (at 4:30 AM EDT).

Sunday evening into early Monday morning, June 16 to 17, 2024, the bright star Spica will appear near the waxing gibbous Moon. As evening twilight ends (at 9:48 PM EDT) Spica will be 3.5 degrees to the right of the Moon. By the time Spica sets on the west-southwestern horizon 4.5 hours later (at 2:16 AM) it will be 5 degrees to the lower right of the Moon. Around the northern part of the boundary between Europe and Asia the Moon will actually block Spica from view.

Wednesday evening, June 19, 2024, will be the first evening the bright planet Mercury will be above the west-northwestern horizon 30 minutes after sunset, an approximation of when it will begin emerging from the glow of dusk. Each evening after this Mercury should become easier to spot and by the end of June will be above the horizon as evening twilight ends.

Wednesday evening into Thursday morning, June 19 to 20, 2024, the bright star Antares will appear near the waxing gibbous Moon. As evening twilight ends (at 9:49 PM EDT) Antares will be 5 degrees to the lower left of the Moon. The Moon will reach its highest in the sky 1.5 hours later (at 11:25 PM EDT) with Antares 4 degrees to the left of the Moon. The Moon will set first on the southwestern horizon (at 4:03 AM) with Antares 2 degrees to the upper left.

Thursday afternoon, June 20, 2024, at 4:51 PM EDT will be the summer solstice, the astronomical end of spring and start of summer. This will be the day with the longest period of sunlight (14 hours, 53 minutes, 42.5 seconds) but will not be the day with the earliest sunrise or the latest sunset.

As mentioned above, the full Moon will be Friday evening, June 21, 2024, at 9:08 PM EDT. This will be on Saturday from Greenland and Cape Verde time eastward across Eurasia, Africa, and Australia to the International Date Line in the mid-Pacific. Most commercial calendars will show this full Moon on Saturday, June 22. This will be the lowest full Moon of the year (reaching only 21.9 degrees above the southern horizon Saturday morning at 1:20 AM). The Moon will appear full for about three days around this time, from Thursday evening through Sunday morning.

Thursday morning, June 27, 2024, the planet Saturn will appear near the waning gibbous Moon. As Saturn rises on the eastern horizon (at 12:26 AM EDT) it will be 6 degrees to the lower left of the Moon. By the time morning twilight begins (at 4:33 AM) Saturn will be 4 degrees to the upper left of the Moon.

Thursday morning June 27, 2024, the Moon will be at perigee, its closest to the Earth for this orbit.

For the Washington, DC area and similar latitudes, at least, Thursday, June 27, 2024, will have the latest sunset of the year (with sunset at 8:37:30 PM EDT).

Friday afternoon, June 28, 2024, the waning Moon will appear half-full as it reaches its last quarter at 5:53 PM EDT (when the Moon will be below the horizon).

Sunday evening, June 30, 2024, will be the first evening that the bright planet Mercury will be above the west-northwestern horizon as evening twilight ends (at 9:49 PM EDT). It will also be the first evening that the bright planet Venus will be above the west-northwestern horizon (at 9:07 PM) 30 minutes after sunset, an approximation of when Venus will start emerging from the glow of dusk.

Monday morning, July 1, 2024, the planet Mars will appear 5 degrees to the lower left of the waning crescent Moon. Mars will rise last on the east-northeastern horizon (at 2:29 AM EDT) and morning twilight will begin a little more than 2 hours later (at 4:35 AM).

Tuesday morning, July 2, 2024, the Pleiades star cluster will appear 5 degrees to the lower left of the waning crescent Moon. The Pleiades will rise last on the east-northeastern horizon (around 2:46 AM EDT) and morning twilight will begin a little less than 2 hours later (at 4:35 AM).

Friday afternoon, July 5, 2024, the Earth will be at aphelion, its farthest away from the Sun in its orbit, 3.4% farther away than it was at perihelion in early January. Since the intensity of light drops off as the square of the distance, the sunlight reaching the Earth at aphelion is about 6.5% less bright than sunlight reaching the Earth at perihelion.

Friday evening, July 5, 2024, at 6:57 PM EDT, will be the new Moon, when the Moon passes between the Earth and the Sun and will not be visible from the Earth. The day of or the day after the New Moon marks the start of the new month for most lunisolar calendars. Saturday, July 6 will be the start of the sixth month of the Chinese year of the Dragon. Sundown on July 6 will mark the start of Tammuz in the Hebrew calendar. In the Islamic calendar the months traditionally start with the first sighting of the waxing crescent Moon. Many Muslim communities now follow the Umm al-Qura Calendar of Saudi Arabia, which uses astronomical calculations to start months in a more predictable way. Using this calendar, sundown on Saturday, July 6, will probably mark Al-Hijra, the Islamic New Year and the beginning of the month of Muharram, although Muharram is one of four months for which the calendar dates may be adjusted by the religious authorities of Saudi Arabia after actual sightings of the lunar crescent. Al-Hijra is a public holiday in many Muslim countries. Customs vary, but most include observing the day quietly and practicing gratitude. Muharram is one of the four sacred months during which warfare is forbidden.

Sunday evening, July 7, 2024, the planet Mercury will appear 3 degrees below the thin, waxing crescent Moon, with the Beehive cluster (visible with binoculars) 1.5 degrees to the lower right of Mercury. As evening twilight ends (at 9:47 PM EDT) the Moon will be 4 degrees above the west-northwestern horizon, with Mercury a little more than 1 degree and the Beehive cluster a little less than 1 degree above the horizon. The Beehive cluster will set first 7 minutes later (at 9:54 PM), followed by Mercury 4 minutes after that (at 9:58 PM) and the Moon 19 minutes after Mercury set (at 10:17 PM).

Friday morning, July 12, 2024, at 4:12 AM EDT (when we can’t see it), the Moon will be at apogee, its farthest from the Earth for this orbit.

Saturday evening, July 13, 2024, the Moon will appear half-full as it reaches its first quarter at 6:49 PM EDT.

Saturday evening, July 13, 2024, will be when the planet Mercury will reach its highest (2 degrees) above the west-northwestern horizon as evening twilight ends (at 9:43 PM EDT).

Saturday night, July 13, 2024, the bright star Spica will appear near the half-full Moon, so near that for part of the night the Moon will block Spica from view for much of North America (see http://lunar-occultations.com/iota/bstar/0714zc1925.htm for a map and information on the locations that will see this occultation). For the location of NASA Headquarters in Washington, DC (angles and times will be different for other locations), as evening twilight ends (at 9:43 PM EDT), Spica will be 1 degree to the left of the Moon. If you are in a location that will see this occultation, you should be able to see Spica vanish behind the dark half of the Moon (at 11:26 PM for the DC area). For the Washington, DC area the Moon will set (at 12:32 AM) before Spica reemerges. For locations farther west, the brightness of the lit half of the Moon will make it hard to see when Spica emerges.

Wednesday night into early Thursday morning, July 17 to 18, 2024, the bright star Antares will appear near the waxing gibbous Moon. As evening twilight ends (at 9:40 PM EDT) Antares will be 3 degrees to the upper right of the Moon. The Moon will reach its highest in the sky 27 minutes later (at 10:07 PM). As Antares sets (at 2:21 AM) it will be 5 degrees to the lower right of the Moon. For much of the southern part of Africa the Moon will pass in front of Antares earlier on Wednesday. See http://lunar-occultations.com/iota/bstar/0717zc2366.htm for a map and information on the locations that will see this occultation. The full Moon after next will be Sunday morning, July 21, 2024, at 6:17 AM EDT. This will be late Saturday night for the International Date Line West and the American Samoa and Midway time zones and early Monday morning for Line Islands Time. The Moon will appear full for about three days around this time, from Friday evening through Monday morning, making this a full Moon weekend.

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NASA's NuSTAR telescope found evidence of cosmic fireworks and X-ray echoes coming from the Milky Way's supermassive black hole Sagittarius A*.

In early May, widespread flooding and landslides occurred in the Brazilian state of Rio Grande do Sul, leaving thousands of people without food, water, or electricity. In the following days, NASA teams provided data and imagery to help on-the-ground responders understand the disaster’s impacts and deploy aid.

Building on this response and similar successes, on June 13, NASA announced a new system to support disaster response organizations in the U.S. and around the world.

Members of the Los Angeles County Fire Department’s Urban Search and Rescue team in Adiyaman, Turkey (Türkiye), conducting rescue efforts in the wake of powerful earthquakes that struck the region in February 2023. NASA provided maps and data to support USAID and other regional partners during these earthquakes. USAID

“When disasters strike, NASA is here to help — at home and around the world,” said NASA Administrator Bill Nelson. “As challenges from extreme weather grow, so too does the value of NASA’s efforts to provide critical Earth observing data to disaster-response teams on the frontlines. We’ve done so for years. Now, through this system, we expand our capability to help power our U.S. government partners, international partners, and relief organizations across the globe as they take on disasters — and save lives.”

The team behind NASA’s Disaster Response Coordination System gathers science, technology, data, and expertise from across the agency and provides it to emergency managers. The new system will be able to provide up-to-date information on fires, earthquakes, landslides, floods, tornadoes, hurricanes, and other extreme events.

NASA Administrator Bill Nelson delivers remarks during an event launching a new Disaster Response Coordination System that will provide communities and organizations around the world with access to science and data to aid disaster response, Thursday, June 13, 2024, at the NASA Headquarters Mary W. Jackson Building in Washington. NASA/Bill Ingalls

“The risk from climate-related hazards is increasing, making more people vulnerable to extreme events,” said Karen St. Germain, director of NASA’s Earth Science Division. “This is particularly true for the 10% of the global population living in low-lying coastal regions who are vulnerable to storm surges, waves and tsunamis, and rapid erosion. NASA’s disaster system is designed to deliver trusted, actionable Earth science in ways and means that can be used immediately, to enable effective response to disasters and ultimately help save lives.”

Agencies working with NASA include the Federal Emergency Management Agency, the National Oceanic and Atmospheric Administration (NOAA), the U.S. Geological Survey, and the U.S. Agency for International Development — as well as international organizations such as World Central Kitchen.

“With this deliberate and structured approach, we can be even more effective in putting Earth science into action,” said Josh Barnes, at NASA’s Langley Research Center in Hampton, Virginia. Barnes manages the Disaster Response Coordination System.

NASA Disasters Team Aiding Brazil

When the floods and landslides ravaged parts of Brazil in May, officials from the U.S. Southern Command — working with the U.S. Space Force and Air Force, and regional partners — reached out to NASA for Earth-observing data.

Image Before/After

NASA’s response included maps of potential power outages from the Black Marble project at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. Disaster response coordinators at NASA Goddard also reviewed high-resolution optical data — from the Commercial Smallsat Data Acquisition Program — to map more than 4,000 landslides.

Response coordinators from NASA’s Jet Propulsion Laboratory and the California Institute of Technology, both in Southern California, produced flood extent maps using data from the NASA and U.S. Geological Survey Landsat mission and from ESA’s (the European Space Agency) Copernicus Sentinel-2 satellite. Response coordinators at NASA’s Johnson Space Center in Houston also provided photographs of the flooding taken by astronauts aboard the International Space Station.

Building on Previous Work

The Brazil event is just one of hundreds of responses NASA has supported over the past decade. The team aids decision-making for a wide range of natural hazards and disasters, from hurricanes and earthquakes to tsunamis and oil spills. 

“NASA’s Disasters Program advances science for disaster resilience and develops accessible resources to help communities around the world make informed decisions for disaster planning,” said Shanna McClain, manager of NASA’s Disasters Program. “The new Disaster Response Coordination System significantly expands our efforts to bring the power of Earth science when responding to disasters.”

For more information visit:

https://disasters.nasa.gov/response

By Jacob Reed
NASA’s Goddard Space Flight Center, Greenbelt, Md.

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Last Updated

Jun 13, 2024

Editor Rob Garner

Related Terms

• Ames Research Center
• Earth
• Extreme Weather Events
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• Jet Propulsion Laboratory
• Johnson Space Center
• Langley Research Center
• Marshall Space Flight Center
• Natural Disasters

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Managed by NASA’s Jet Propulsion Laboratory through launch, Webb’s Mid-Infrared Instrument also revealed jets of gas flowing into space from the twin stars.

Scientists recently got a big surprise from NASA’s James Webb Space Telescope when they turned the observatory toward a group of young stars called WL 20. The region has been studied since the 1970s with at least five telescopes, but it took Webb’s unprecedented resolution and specialized instruments to reveal that what researchers long thought was one of the stars, WL 20S, is actually a pair that formed about 2 million to 4 million years ago.

The discovery was made using Webb’s Mid-Infrared Instrument (MIRI) and was presented at the 244th meeting of the American Astronomical Society on June 12. MIRI also found that the twins have matching jets of gas streaming into space from their north and south poles.

“Our jaws dropped,” said astronomer Mary Barsony, lead author of a new paper describing the results. “After studying this source for decades, we thought we knew it pretty well. But without MIRI we would not have known this was two stars or that these jets existed. That’s really astonishing. It’s like having brand new eyes.”

This artist’s concept shows two young stars nearing the end of their formation. Encircling the stars are disks of leftover gas and dust from which planets may form. Jets of gas shoot away from the stars’ north and south poles.

The team got another surprise when additional observations by the Atacama Large Millimeter/submillimeter Array (ALMA), a group of more than 60 radio antennas in Chile, revealed that disks of dust and gas encircle both stars. Based on the stars’ age, it’s possible that planets are forming in those disks.

The combined results indicate that the twin stars are nearing the end of this early period of their lives, which means scientists will have the opportunity to learn more about how the stars transition from youth into adulthood.

“The power of these two telescopes together is really incredible,” said Mike Ressler, project scientist for MIRI at NASA’s Jet Propulsion Laboratory and co-author of the new study. “If we hadn’t seen that these were two stars, the ALMA results might have just looked like a single disk with a gap in the middle. Instead, we have new data about two stars that are clearly at a critical point in their lives, when the processes that formed them are petering out.”

This image of the WL 20 star group combines data from the Atacama Large Millimeter/submillimeter Array and the Mid-Infrared Instrument on NASA’s Webb telescope. Gas jets emanating from the poles of twin stars appear blue and green; disks of dust and gas surrounding the stars are pink.U.S. NSF; NSF NRAO; ALMA; NASA/JPL-Caltech; B. Saxton Stellar Jets

WL 20 resides in a much larger, well-studied star-forming region of the Milky Way galaxy called Rho Ophiuchi, a massive cloud of gas and dust about 400 light-years from Earth. In fact, WL 20 is hidden behind thick clouds of gas and dust that block most of the visible light (wavelengths that the human eye can detect) from the stars there. Webb detects slightly longer wavelengths, called infrared, that can pass through those layers. MIRI detects the longest infrared wavelengths of any instrument on Webb and is thus well equipped for peering into obscured star-forming regions like WL 20.

Radio waves can often penetrate dust as well, though they may not reveal the same features as infrared light. The disks of gas and dust surrounding the two stars in WL 20S emit light in a range that astronomers call submillimeter; these, too, penetrate the surrounding gas clouds and were observed by ALMA.

These four images show the WL 20 star system as seen by (from left) NASA’s Infrared Telescope Facility at the Mauna Kea Observatory, the Hale 5.0-meter telescope the Palomar Observatory, the Keck II telescope, and the NASA’s Webb telescope and the Atacama Large Millimeter/submillimeter Array.

But scientists could easily have interpreted those observations as evidence of a single disk with a gap in it had MIRI not also observed the two stellar jets. The jets of gas are composed of ions, or individual atoms with some electrons stripped away that radiate in mid-infrared wavelengths but not at submillimeter wavelengths. Only an infrared instrument with spatial and spectral resolution like MIRI’s could see them.

ALMA can also observe clouds of leftover formation material around young stars. Composed of whole molecules, like carbon monoxide, these clouds of gas and dust radiate light at these longer wavelengths. The absence of those clouds in the ALMA observations shows that the stars are beyond their initial formation phase.

“It’s amazing that this region still has so much to teach us about the life cycle of stars,” said Ressler. “I’m thrilled to see what else Webb will reveal.”

More About the Mission

The James Webb Space Telescope is the world’s premier space science observatory. Webb is solving mysteries in our solar system, looking beyond to distant worlds around other stars, and probing the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and CSA (Canadian Space Agency).

MIRI was developed through a 50-50 partnership between NASA and ESA. A division of Caltech in Pasadena, California, JPL led the U.S. efforts for MIRI, and a multinational consortium of European astronomical institutes contributes for ESA. George Rieke with the University of Arizona is the MIRI science team lead. Gillian Wright is the MIRI European principal investigator.

The MIRI cryocooler development was led and managed by JPL, in collaboration with Northrop Grumman in Redondo Beach, California, and NASA’s Goddard Space Flight Center in Greenbelt, Maryland.

News Media Contact

Calla Cofield
Jet Propulsion Laboratory, Pasadena, Calif.
626-808-2469
calla.e.cofield@jpl.nasa.gov

2024-085

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Details Last Updated Jun 13, 2024 Related Terms

• James Webb Space Telescope (JWST)
• Astrophysics
• Exoplanets
• Jet Propulsion Laboratory
• Stars

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