Jumat, 30 September 2022

Behold! Our closest view of Jupiter's ocean moon Europa in 22 years - Space.com

NASA's Jupiter-gazing spacecraft just got a rare closeup of an icy world.

The Juno probe made the closest pass in 22 years of Jupiter's icy moon Europa on Thursday (Sept. 29), providing the best view of the ocean world since the NASA's Galileo spacecraft flew by it 2000.

Skimming just 219 miles (352 kilometers) above Europe's surface, the two-hour flyby was among the three closest-ever glimpses of the icy world. The last similar view that we received was on Jan. 3, 2000 with Galileo, officials with NASA's Jet Propulsion Laboratory (JPL) in Southern California said in a statement.

"Rugged terrain features are easily seen, including tall shadow-casting blocks, while bright and dark ridges and troughs curve across the surface. The oblong pit near the terminator might be a degraded impact crater," JPL officials wrote of Juno's flyby imagery (opens in new tab) on Thursday (Sept. 29).

Video: NASA unveils most amazing view of Jupiter's moon Europa ever 

While geology data from the flyby is just starting to come in, officials termed Juno's rare look as key to establishing observations for NASA's coming Europa Clipper mission, which will launch in just two years to study the icy moon.

"Europa Clipper will study the moon's atmosphere, surface, and interior, with its main science goal being to determine whether there are places below Europa's surface that could support life," JPL stated of the mission, which is scheduled to reach the Jupiter system in 2030.

As the sixth-largest moon in the solar system, Europa is similar in size to Earth's moon but has a much different formation and evolutionary history. Europa has a massive icy crust overlying an ocean that researchers think may be capable of supporting Earth-like life.

During its flyby, Juno collected some of the highest-ever resolution pictures of the moon at 0.6 miles or 1 km per pixel, JPL stated, along with information about the moon's environment, atmosphere, surface and interior structure.

In pictures: Chaos reigns in detailed views of Jupiter's icy moon Europa

"The science team will be ... looking to see if Europa's surface features have changed over the past two decades," said Candy Hansen, a Juno co-investigator who leads planning for JunoCam (which obtained the images) at the Planetary Science Institute in Tucson, Arizona.

Data from Juno's microwave radiometer instrument could be especially important for future missions such as Clipper, as it may help identify some potentially habitable  "pockets" of liquid water just underneath the massive ice cap.

Scientists used the flyby to change Juno's trajectory slightly, as it now is slated to make a single orbit of Jupiter in 38 Earth days (compared with the previous 43.) Flybys of the volcanic Jovian moon Io are expected in 2023 and 2024, if the mission can continue surviving the intense radiation radiation belts near Jupiter.

Follow Elizabeth Howell on Twitter @howellspace (opens in new tab). Follow us on Twitter @Spacedotcom (opens in new tab) or Facebook (opens in new tab)

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2022-09-30 13:39:25Z
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NASA's James Webb And Hubble Telescopes Capture Detailed Views Of Asteroid Strike - NDTV

NASA's James Webb And Hubble Telescopes Capture Detailed Views Of Asteroid Strike

DART mission was the world's first-ever in-space test for planetary defence.

Two of NASA's space telescopes - James Webb Space Telescope and Hubble Space Telescope - have captured views of the DART spacecraft intentionally smashing into an asteroid earlier this week. 

On Tuesday, NASA's Double Asteroid Redirection Test (DART) deliberately crashed into asteroid Dimorphos some 9.6 million kilometres away from Earth, ploughing into the rock at 22,500 kilometres per hour. The experiment was the world's first-ever in-space test for planetary defence. It was also the first time that the Hubble Space Telescope and the James Webb Space Telescope simultaneously observed the same celestial target, as per the US space agency. 

Taking to Instagram, NASA stated that the images and videos taken from James Webb's near-infrared camera show a tight, compact core with "plumes of material appearing as wisps streaming away" from where the impact took place. 

Take a look below: 

The space agency also added that observing the Dart Mission impact with Webb was a "unique challenge". "Asteroid Dimorphos moved over at a speed over 3 times faster than the original speed limit Webb was designed to track! In the weeks leading up to the impact, teams carefully tested how they would accomplish the task," it added in the caption. 

Also Read | NASA Shares Terrifying Footage Of Hurricane Ian Captured From Space

Hubble telescope, on the other hand, captured images taken 22 minutes, five hours and 8.2 hours after the impact, NASA said. Photos taken from Hubble's wide field camera 3 show the impact of the mission in visible light. 

"Hubble's images show the movement of ejecta from Dimorphos after impact. The ejecta appear as rays stretching out from the asteroid," the caption of the Instagram post read.

"Webb and Hubble show what we've always known to be true at NASA: We learn more when we work together," said NASA Administrator Bill Nelson, as per a press note

"For the first time, Webb and Hubble have simultaneously captured imagery from the same target in the cosmos: an asteroid that was impacted by a spacecraft after a seven-million-mile journey. All of humanity eagerly awaits the discoveries to come from Webb, Hubble, and our ground-based telescopes - about the DART mission and beyond," Mr Nelson added. 

Also Read | NASA's Artemis Mission Rolled Back To Storage As Hurricane Nears

Now, according to NASA, observations from Webb and Hubble together will allow scientists to gain knowledge about the nature of the surface of Dimorphos, how much material was ejected by the collision, and how fast it was ejected. Combining this information, along with ground-based telescope observations, will help scientists to understand how effectively a kinetic impact can modify an asteroid's orbit, the space agency said in its press release. 

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2022-09-30 11:10:48Z
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Kamis, 29 September 2022

Webb, Hubble Capture Detailed Views of DART Impact - NASA

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  1. Webb, Hubble Capture Detailed Views of DART Impact  NASA
  2. Moment Nasa's Dart spacecraft hits target asteroid in test to avoid future catastrophes on Earth  The Straits Times
  3. The Most Intriguing Images of DART’s Fatal Encounter With an Asteroid  Gizmodo
  4. First images of asteroid strike from Webb, Hubble telescopes  Phys.org
  5. Skywatch 16: DART planetary defense  WNEP
  6. View Full coverage on Google News

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2022-09-29 13:43:15Z
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Watch live early Thursday: Cosmonauts departing space station - Space.com

Three Russian cosmonauts will return to Earth Thursday (Sept. 29), and you can watch the whole thing live.

Expedition 67 cosmonauts Oleg Artemyev, Denis Matveev and Sergey Korsakov will fly back to Earth on a Russian Soyuz spacecraft from the International Space Station (ISS). 

Their Soyuz MS-21 spacecraft is scheduled to undock from the Prichal module of the ISS at 3:34 a.m. EDT (0734 GMT) and arrive in Kazakhstan, outside of the remote town of Dzhezkazgan, at 6:57 a.m. EDT (1057 GMT or 4:57 a.m. local time), NASA officials (opens in new tab) said.

Live streaming of the undocking and re-entry will be available here at Space.com, via NASA Television (opens in new tab), as well as on the agency's website, app, and social media. Undocking coverage will start at 3:15 a.m. EDT (0715 GMT) and landing coverage at 5:45 a.m. EDT (0945 GMT).

International Space Station: Facts about the orbital laboratory

The trio's launch to the ISS on March 18 took place less than a month after the Russian invasion of Ukraine began, and their Soyuz held the first all-Russian cosmonaut crew in 22 years. 

Expedition 67 featured numerous spacewalks to prepare and integrate the European Robotic Arm on the Russian side of the space station, adding on to robotic capabilities used by Canada's Canadarm2 and Japan's Kibo module arm. (One Aug. 17 spacewalk was cut short due to problems with Artemyev's suit, which were resolved before the next excursion.)

During a change of command ceremony on Wednesday (Sept. 28), outgoing Expedition 67 commander Artemyev seemed to allude to the ongoing war. "In the end, our war will end everywhere," he said.

Expedition 68 commander Samantha Cristoforetti is the first European woman to helm the ISS and the fifth European to do so overall. After Artemyev, Matveev and Korsakov depart, she'll share the ISS with NASA astronauts Robert Hines, Jessica Watkins and Kjell Lindgren and Frank Rubio, along with cosmonauts Sergey Prokopyev and Dmitri Petelin.

In photos: Astronaut Samantha Cristoforetti takes Europe's historic 1st female spacewalk

The next crewed launch to the ISS is expected to happen no sooner than Oct. 5. Crew-5, a mission that will take place aboard a SpaceX Crew Dragon spacecraft, is slated to launch from NASA's Kennedy Space Center in Florida. 

The multinational Crew-5 will include a seat for Anna Kikina, the first Russian cosmonaut to fly to the ISS on a commercial American spacecraft, along with NASA's Nicole Mann (who will become the first Native American woman in space), NASA's Josh Cassada and Japan's Koichi Wakata. 

Crew-5's launch has been delayed at least two days due to the potential "catastrophic" arrival of Hurricane Ian in Florida, as some officials have termed the storm. NASA has emphasized that the new launch date is tentative and depends on the center's recovery after the hurricane, which has brought Category 4 winds to the state. 

Follow Elizabeth Howell on Twitter @howellspace (opens in new tab). Follow us on Twitter @Spacedotcom (opens in new tab) or Facebook (opens in new tab)

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2022-09-29 10:40:33Z
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Rabu, 28 September 2022

Asteroid Diversion? Earth Still "Careening Headlong into Climate Catastrophe," Says NASA Scientist - Democracy Now!

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2022-09-28 14:14:59Z
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'Incredible': Astronomers hail first images of asteroid impact - RFI English

Issued on: Modified:

Paris (AFP) – The asteroid is flying through space in the grainy black and white video, when suddenly a massive cloud of debris sprays out in front of it, meaning only one thing: impact.

Astronomers have hailed this early footage of the first time humanity deliberately smashed a spacecraft into an asteroid, saying it looks like it did a "lot of damage".

That would be good news, because NASA's Double Asteroid Redirection Test (DART) impactor struck the asteroid Dimorphos at 23,500 kilometres (14,500 miles) per hour on Monday night with the goal of deflecting its trajectory.

While Dimorphos is 11 million kilometres (6.8 million miles) away and poses no threat to Earth, it is being used as a historic test run so the world can be ready to defend itself if a future astroid heads Earth's way.

After the impact, ground-based telescopes and the toaster-sized satellite LICIACube, which separated from DART a few weeks ago, revealed the first images of the collision.

"On the LICIACube images, the plume of what came off the surface was quite impressive," Antonella Barucci of the Paris Observatory's LESIA laboratory told AFP.

By examining the plume, "we can begin to estimate the density of the material on the surface," she said.

'Very, very big' plume

The Asteroid Terrestrial-impact Last Alert System (ATLAS) project on Tuesday tweeted a nine-second video of the impact taken by its telescope in South Africa.

Larry Denneau, the ATLAS co-principal investigator, said the telescope took one image every 40 seconds.

#photo1

"So the whole sequence that you've seen on Twitter lasts about two hours in real time," he told AFP.

He said the "very, very big" plume was made by dust shooting off the asteroid.

"A lot of the dust is released at a speed that's greater than the gravity of the asteroid, and so it escapes," Denneau said.

The plume expanded to around "several thousand miles in diameter," he added.

In the coming days and weeks astronomers around the world will work to confirm whether the asteroid's trajectory was definitively altered by the impact.

Then the European Space Agency's Hera mission will arrive at Dimorphos in 2026 to survey the surface and discover the extent of DART's impact.

Hera mission principal investigator Patrick Michel said "we are all impressed by the magnitude of the event".

"We have done a lot of damage to Dimorphos," Michel said.

"We have a quantity of ejected matter that is quite incredible."

The amount of matter ripped from the asteroid will help scientists work out exactly how much its trajectory has been affected -- if at all.

"So it's a pretty good sign," he added.

juc-la-pcl-dl/yad

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2022-09-28 09:50:19Z
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NASA explains decision to roll back Artemis I rocket - WAAY-TV 31 News

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2022-09-28 00:51:45Z
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NASA's Dart crashes into asteroid - KTVB

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2022-09-27 22:27:14Z
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Ready for its close-up: Vancouver Islanders snap spectacular photos of Jupiter - CHEK News

On a night when the solar system’s largest planet was the closest it’s been to Earth in nearly six decades, Vancouver Island’s astrophotographers were ready.

While you can glimpse it in the night sky for much of the year, Jupiter was glowing bright Monday as it not only was the closest it’s been since October 1963, but also was in opposition — a term to describe when a celestial object rises in the east as the sun sets in the west.

Greater Victoria photographer Conan Chee, who has snapped some impressive celestial phenomena like the Northern Lights and a meteor striking a “super blood wolf moon“, decided to try to capture his first-ever shot of the gas giant.

“My buddy was mentioning after his birthday, ‘you should go do it,’ because we saw some pictures on the internet,” said Chee. “I was like alright, I’ll give it a shot.”

After setting up his supertelephoto lens and dialing in his equipment over the course of two hours, and thanks to crystal clear, low-humiditiy conditions, Chee was left with an image clearly showing Jupiter’s orange body and dark red bands.

He also captured the planet’s four brightest moons: Callisto, Io, Ganymede and Europa.

Chee wasn’t the only person trying to score a once-in-a-lifetime shot of Jupiter.

Members of the Royal Astronomical Society of Canada — Victoria Chapter got their setups out as the planet came the closest it will to Earth until 2129.

Brock Johnston managed to snap not just Jupiter, but Saturn, over the past few nights as they glowed brighter in the night sky.

Johnston said he took the images from Brentwood bay  using a Celestron Schmidt-Cassegrain telescope.

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2022-09-28 00:33:45Z
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Selasa, 27 September 2022

NASA's DART hits target asteroid in Earth defense test - The Star

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2022-09-27 09:00:00Z
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Senin, 26 September 2022

Jupiter at Opposition III | StarDate Online - Stardate.org

Earth and Jupiter wouldn’t appear to have a lot in common. Earth is a ball of rock surrounded by a thin atmosphere. Jupiter is a ball of gas 11 times wider than Earth, with a thick, dense atmosphere.

One thing they do have in common is thunderstorms. On both planets, rising columns of water vapor condense to form clouds when they reach higher, colder altitudes. If there’s enough water vapor and enough energy, the clouds can reach towering proportions — the kind that produce thunderstorms. On Earth, they can be 10 miles high. But on Jupiter, they can be dozens of miles tall.

Several missions to Jupiter have recorded lightning in its clouds. Some have recorded radio waves produced by the lightning. Others have actually seen lightning. Some of the lightning bolts are thousands of times stronger than anything on Earth.

The Juno mission has also seen smaller flashes above the clouds. And so far, scientists don’t have a great explanation for them. But they continue to work on the problem as Juno takes more readings of Jupiter’s big thunderstorms.

Jupiter’s great size and its clouds make it especially bright. And right now, it’s shining at its brightest. It looks like an especially brilliant star, outshined only by the Moon and Venus. Jupiter is low in the east at nightfall, climbs across the south during the night, and is ready to vanish in the west at dawn.
 

Script by Damond Benningfield

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2022-09-26 05:09:57Z
CBMiLWh0dHBzOi8vc3RhcmRhdGUub3JnL3JhZGlvL3Byb2dyYW0vMjAyMi0wOS0yNtIBAA

Planetary defence test: Why NASA's aiming for an asteroid - CTV News

Ten months after launch, NASA's asteroid-deflecting DART spacecraft neared a planned impact with its target on Monday in a test of the world's first planetary defence system, designed to prevent a doomsday collision with Earth.

The cube-shaped "impactor" vehicle, roughly the size of a vending machine with two rectangular solar arrays, was on course to fly into the asteroid Dimorphos, about as large as a football stadium, and self-destruct around 7 p.m. EDT (2300 GMT) some 6.8 million miles (11 million km) from Earth.

The mission's finale will test the ability of a spacecraft to alter an asteroid's trajectory with sheer kinetic force, plowing into the object at high speed to nudge it astray just enough to keep our planet out of harm's way.

It marks the world's first attempt to change the motion of an asteroid, or any celestial body.

DART, launched by a SpaceX rocket in November 2021, has made most of its voyage under the guidance of NASA's flight directors, with control to be handed over to an autonomous on-board navigation system in the final hours of the journey.

Monday evening's planned impact is to be monitored in real time from the mission operations center at the Johns Hopkins University Applied Physics Laboratory (APL) in Laurel, Maryland.

DART's celestial target is an asteroid "moonlet" about 560 feet (170 metres) in diameter that orbits a parent asteroid five times larger called Didymos as part of a binary pair with the same name, the Greek word for twin.

Neither object presents any actual threat to Earth, and NASA scientists said their DART test cannot create a new existential hazard by mistake.

Dimorphos and Didymos are both tiny compared with the cataclysmic Chicxulub asteroid that struck Earth some 66 million years ago, wiping out about three-quarters of the world's plant and animal species including the dinosaurs.

Smaller asteroids are far more common and pose a greater theoretical concern in the near term, making the Didymos pair suitable test subjects for their size, according to NASA scientists and planetary defence experts.

Also, their relative proximity to Earth and dual-asteroid configuration make them ideal for the first proof-of-concept mission of DART, short for Double Asteroid Redirection Test.

ROBOTIC SUICIDE MISSION

The mission represents a rare instance in which a NASA spacecraft must ultimately crash to succeed.

The plan is for DART to fly directly into Dimorphos at 15,000 miles per hour (24,000 kph), bumping it hard enough to shift its orbital track closer to its larger companion asteroid.

Cameras on the impactor and on a briefcase-sized mini-spacecraft released from DART days in advance are designed to record the collision and send images back to Earth.

DART's own camera is expected to return pictures at the rate of one image per second during its final approach, with those images streaming live on NASA TV starting an hour before impact, according to APL.

The DART team said it expects to shorten the orbital track of Dimorphos by 10 minutes but would consider at least 73 seconds a success, proving the exercise as a viable technique to deflect an asteroid on a collision course with Earth - if one were ever discovered. A small nudge to an asteroid millions of miles away could be sufficient to safely reroute it away from the planet.

The test's outcome will not be known until a new round of ground-based telescope observations of the two asteroids in October. Earlier calculations of the starting location and orbital period of Dimorphos were confirmed during a six-day observation period in July.

DART is the latest of several NASA missions in recent years to explore and interact with asteroids, primordial rocky remnants from the solar system's formation more than 4.5 billion years ago.

Last year, NASA launched a probe on a voyage to the Trojan asteroid clusters orbiting near Jupiter, while the grab-and-go spacecraft OSIRIS-REx is on its way back to Earth with a sample collected in October 2020 from the asteroid Bennu.

The Dimorphos moonlet is one of the smallest astronomical objects to receive a permanent name and is one of 27,500 known near-Earth asteroids of all sizes tracked by NASA. Although none are known to pose a foreseeable hazard to humankind, NASA estimates that many more asteroids remain undetected in the near-Earth vicinity.

NASA has put the entire cost of the DART project at US$330 million, well below that of many of the space agency's most ambitious science missions.

Reporting by Steve Gorman in Los Angeles; Editing by Will Dunham

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2022-09-26 14:13:55Z
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Minggu, 25 September 2022

The Weekly: NASA monitoring Ian's track ahead of planned Artemis I launch in October - WKMG News 6 ClickOrlando

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2022-09-25 13:32:59Z
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Why is a NASA Spacecraft Crashing Into an Asteroid? - Voice of America - VOA News

In the first-of-its kind, save-the-world experiment, NASA is about to clobber a small, harmless asteroid millions of miles away.

A spacecraft named Dart will zero in on the asteroid Monday, intent on slamming it head-on at 14,000 mph (22,500 kph). The impact should be just enough to nudge the asteroid into a slightly tighter orbit around its companion space rock — demonstrating that if a killer asteroid ever heads our way, we'd stand a fighting chance of diverting it.

"This is stuff of science-fiction books and really corny episodes of "StarTrek" from when I was a kid, and now it's real," NASA program scientist Tom Statler said Thursday.

Cameras and telescopes will watch the crash, but it will take days or even weeks to find out if it actually changed the orbit.

The $325 million planetary defense test began with Dart's launch last fall.

Asteroid target

The asteroid with the bull's-eye on it is Dimorphos, about 7 million miles (9.6 million kilometers) from Earth. It is actually the puny sidekick of a 2,500-foot (780-meter) asteroid named Didymos, Greek for twin. Discovered in 1996, Didymos is spinning so fast that scientists believe it flung off material that eventually formed a moonlet. Dimorphos — roughly 525 feet (160 meters) across — orbits its parent body at a distance of less than a mile (1.2 kilometers).

"This really is about asteroid deflection, not disruption," said Nancy Chabot, a planetary scientist and mission team leader at Johns Hopkins University's Applied Physics Laboratory, which is managing the effort. "This isn't going to blow up the asteroid. It isn't going to put it into lots of pieces." Rather, the impact will dig out a crater tens of yards (meters) in size and hurl some 2 million pounds (1 million kilograms) of rocks and dirt into space.

NASA insists there's a zero chance either asteroid will threaten Earth — now or in the future. That's why the pair was picked.

Dart, the impactor

The Johns Hopkins lab took a minimalist approach in developing Dart — short for Double Asteroid Redirection Test — given that it's essentially a battering ram and faces sure destruction. It has a single instrument: a camera used for navigating, targeting and chronicling the final action. Believed to be essentially a rubble pile, Dimorphos will emerge as a point of light an hour before impact, looming larger and larger in the camera images beamed back to Earth. Managers are confident Dart won't smash into the larger Didymos by mistake. The spacecraft's navigation is designed to distinguish between the two asteroids and, in the final 50 minutes, target the smaller one.

The size of a small vending machine at 1,260 pounds (570 kilograms), the spacecraft will slam into roughly 11 billion pounds (5 billion kilograms) of asteroid. "Sometimes we describe it as running a golf cart into a Great Pyramid," said Chabot.

Unless Dart misses — NASA puts the odds of that happening at less than 10% — it will be the end of the road for Dart. If it goes screaming past both space rocks, it will encounter them again in a couple years for Take 2.

Saving earth

Little Dimorphos completes a lap around big Didymos every 11 hours and 55 minutes. The impact by Dart should shave about 10 minutes off that. Although the strike itself should be immediately apparent, it could take a few weeks or more to verify the moonlet's tweaked orbit. Cameras on Dart and a mini tagalong satellite will capture the collision up close. Telescopes on all seven continents, along with the Hubble and Webb space telescopes and NASA's asteroid-hunting Lucy spacecraft, may see a bright flash as Dart smacks Dimorphos and sends streams of rock and dirt cascading into space. The observatories will track the pair of asteroids as they circle the sun, to see if Dart altered Dimorphos' orbit. In 2024, a European spacecraft named Hera will retrace Dart's journey to measure the impact results.

Although the intended nudge should change the moonlet's position only slightly, that will add up to a major shift over time, according to Chabot. "So if you were going to do this for planetary defense, you would do it five, 10, 15, 20 years in advance in order for this technique to work," she said. Even if Dart misses, the experiment still will provide valuable insight, said NASA program executive Andrea Riley. "This is why we test. We want to do it now rather than when there's an actual need," she said.

Asteroid missions galore

Planet Earth is on an asteroid-chasing roll. NASA has close to a pound (450 grams) of rubble collected from asteroid Bennu headed to Earth. The stash should arrive next September. Japan was the first to retrieve asteroid samples, accomplishing the feat twice. China hopes to follow suit with a mission launching in 2025. NASA's Lucy spacecraft, meanwhile, is headed to asteroids near Jupiter, after launching last year. Another spacecraft, Near-Earth Asteroid Scout, is loaded into NASA's new moon rocket awaiting liftoff; it will use a solar sail to fly past a space rock that's less than 60 feet (18 meters) next year. In the next few years, NASA also plans to launch a census-taking telescope to identify hard-to-find asteroids that could pose risks. One asteroid mission is grounded while an independent review board weighs its future. NASA's Psyche spacecraft should have launched this year to a metal-rich asteroid between Mars and Jupiter, but the team couldn't test the flight software in time.

Hollywood's take

Hollywood has churned out dozens of killer-space-rock movies over the decades, including 1998′s "Armageddon" which brought Bruce Willis to Cape Canaveral for filming, and last year's "Don't Look Up" with Leonardo DiCaprio leading an all-star cast. NASA's planetary defense officer, Lindley Johnson, figures he's seen them all since 1979′s "Meteor," his personal favorite "since Sean Connery played me." While some of the sci-fi films are more accurate than others, he noted, entertainment always wins out. The good news is that the coast seems clear for the next century, with no known threats. Otherwise, "it would be like the movies, right?" said NASA's science mission chief Thomas Zurbuchen. What's worrisome, though, are the unknown threats. Fewer than half of the 460-foot (140-meter) objects have been confirmed, with millions of smaller but still-dangerous objects zooming around. "These threats are real, and what makes this time special, is we can do something about it," Zurbuchen said. Not by blowing up an asteroid as Willis' character did — that would be a last, last-minute resort — or by begging government leaders to take action as DiCaprio's character did in vain. If time allows, the best tactic could be to nudge the menacing asteroid out of our way, like Dart.

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2022-09-25 07:01:36Z
1576687942

Sabtu, 24 September 2022

NWT man among finalists in international astronomy photographer contest - KamloopsBCNow

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NWT man among finalists in international astronomy photographer contest  KamloopsBCNowView Full coverage on Google News
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2022-09-24 18:13:36Z
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NASA delays moon rocket launch again - CTV News

CAPE CANAVERAL, Fla. -

NASA is skipping next week's launch attempt of its new moon rocket because of a tropical storm that's expected to become a major hurricane.

It's the third delay in the past month for the lunar-orbiting test flight featuring mannequins but no astronauts, a follow-up to NASA's Apollo moon-landing program of a half-century ago. Hydrogen fuel leaks and other technical issues caused the previous scrubs.

Currently churning in the Caribbean, Tropical Storm Ian is expected to become a hurricane by Monday and slam into Florida's Gulf coast by Thursday. The entire state, however, is in the cone showing the probable path of the storm's center -- including NASA's Kennedy Space Center.

Given the forecast uncertainties, NASA decided Saturday to forgo Tuesday's planned launch attempt and instead prepare the 322-foot (98-metre) rocket for a possible return to its hangar. Managers will decide Sunday whether to haul it off the launch pad.

If the rocket remains at the pad, NASA could try for an Oct. 2 launch attempt, the last opportunity before a two-week blackout period. But a rollback late Sunday or early Monday likely would mean a lengthy delay for the test flight, possibly pushing it into November.

The Space Launch System rocket is the most powerful ever built by NASA. Assuming its first test flight goes well, astronauts would climb aboard for the next mission in 2024, leading to a two-person moon landing in 2025.

------

The Associated Press Health and Science Department receives support from the Howard Hughes Medical Institute's Department of Science Education. The AP is solely responsible for all content.

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2022-09-24 14:56:33Z
1576143795

NASA is slamming a spacecraft into an asteroid on Monday to test planetary defence - CBC.ca

On Monday, in what seems like a scene out of a science fiction movie, NASA will slam a spacecraft into a distant asteroid to see whether it can nudge its orbit — all in an effort to test a way to protect Earth from any potential future threats.

The good news is that there's no need to panic: The asteroid, which is part of a binary — or two-bodied — system, is not a threat to our planet, and there are no known ones that are headed our way for at least the next 100 years. However, space agencies like the U.S. National Aeronautics and Space Administration want to be prepared should there ever be a threat.

NASA's Double Asteroid Redirection Test (DART) is testing a way in which a spacecraft may be able to nudge an asteroid on a collision course with Earth out of its orbit.

At 7:14 p.m. ET on Monday, the refrigerator-sized spacecraft will plunge itself into Dimorphos — a moonlet that orbits its larger companion, Didymos — at roughly 6.6 km/s.

The goal isn't to knock Dimorphos out of orbit but rather to change its 12-hour orbit around Didymos by 10 minutes. This means that scientists will know within roughly 12 hours whether they were successful.

So why target a binary asteroid system rather than a single asteroid to see whether you can change its orbit around the sun?

This image of the light from asteroid Didymos and its orbiting moonlet, Dimorphos, is a composite of 243 images taken by the Didymos Reconnaissance and Asteroid Camera for Optical navigation (DRACO) on July 27. (NASA JPL DART Navigation Team)

"A binary system was perfect for this test," said Mallory DeCoster, a senior scientist at Johns Hopkins University's Applied Physics Laboratory in Maryland and part of the DART Impact Modeling Working Group.

For one, the size of Dimorphos — about 164 metres across — is perfect to illustrate whether this would be an effective way of deflecting asteroids that pose a threat to Earth. Didymos is 780 metres across.

"But then the other piece is, if we were to impact a single asteroid, in order to characterize if we changed its orbit, we would have to wait until it completed its orbit around the sun, which could take many, many years."

The other advantage is that the binary system is relatively close to us, astronomically speaking, at just 11 million kilometres away.

Shooting gallery

NASA's Center for Near-Earth Object Studies says that more than 90 per cent of near-Earth objects (NEOs) bigger than one kilometre have already been discovered. But that doesn't mean we're out of the woods when it comes to Potentially Hazardous Asteroids (PHAs).

In 2013, the Chelyabinsk asteroid — which was roughly 20 metres in diameter— exploded over parts of Russia, injuring about 1,000 people and serving as a reminder of how even a small asteroid can be dangerous.

In February 2013, a meteorite contrail was seen over Chelyabinsk, Russia, a city close to the Ural Mountains located about 1,500 kilometres east of Moscow. The Chelyabinsk asteroid, which was roughly 20 metres in diameter, exploded over parts of Russia, injuring about 1,000 people. (Chelyabinsk.ru, Yekaterina Pustynnikova/The Associated Press)

Basically, Earth flies through a shooting gallery in space. There are small chunks of debris that burn up in our atmosphere as meteors; bigger ones, like Chelyabinsk; and then even bigger ones that can be catastrophic — all left over from the formation of our solar system.

That's why space agencies like NASA and the European Space Agency have been trying to develop ways to deflect or nudge a PHA so that its orbit changes and poses no threat to Earth.

Mike Daly, a professor at York University's Lassonde School of Engineering in Toronto and a co-investigator on DART, said one of the most popular concepts is deflecting asteroids before they become a real threat. But that means we need to have advance warning that one is headed our way.

"So the simplest method is the one that DART is doing, which is essentially to take a spacecraft at high speed and crash it into the asteroid and use that transfer of the energy from the spacecraft to the asteroid to move it along," he said.

This infographic shows the potential effect of DART's impact on the orbit of Dimorphos. (NASA/Johns Hopkins APL)

However, the science behind asteroid deflection in this manner is about more than just the combination of the spacecraft's size and incredibly high speed, called a hypervelocity impact.

"In a hypervelocity impact, you induce this pressure wave into the target that causes a lot of new physics to happen," Johns Hopkins University's DeCoster said.

"So what will happen, or what we think will happen, is that the size of the spacecraft might actually not matter that much. It might actually be: How does the asteroid respond to this pressure wave that is induced due to the hypervelocity impact? And we think that it will likely spew out a lot of material in the form of ejecta. And this ejecta might actually have a major component for changing the orbit. So much ejecta might get spewed out that that piece might matter more than the incoming energy from the spacecraft in changing its orbit."

The DART team hopes that an onboard camera, called DRACO, will show the close approach and then suddenly go black, which would be indicative of an impact.

This map shows the 38 telescopic facilities in space and around the globe that are expected to observe the Didymos asteroid system in support of DART’s global observation campaign after impact. Numerical figures in parentheses next to the telescope names indicate the telescope size. (NASA/Johns Hopkins APL/Nancy Chabot/Mike Halstad)

But there's a straggler tagging along behind DART, by about three minutes: the Italian Space Agency's Light Italian Cubesat for Imaging of Asteroids, or LICIACube. Its job is to photograph the impact, study the plume of ejecta and help determine the morphology of the asteroid, as they can be made of iron, rock or just rocky clumps held together by gravity.

As this is the first test of a form of planetary defence, scientists are eagerly anticipating not only the impact of the event itself but what they will learn from it and, most importantly, what this may mean for the future of protecting Earth in the future. Telescopes from around the world will be observing the event and collecting followup data.

"We're really the first generation that can protect ourselves from these potentially catastrophic impacts," York University's Daly said. "And, you know, fortunately the really catastrophic ones don't happen very often, but they could happen, and never before have we been able to change our fate. So I think it's really up to us, given the potentially large consequences of not paying attention and our ability to do it."

The event will be broadcast on NASA TV, which is available online and through its app.

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2022-09-24 08:00:00Z
1576687942

Jumat, 23 September 2022

Approaching storm may delay launch try for NASA moon rocket - Winnipeg Free Press

CAPE CANAVERAL, Fla. (AP) — An approaching storm threatens to delay NASA’s next launch attempt for its new moon rocket, already grounded for weeks by fuel leaks.

A tropical depression in the southern Caribbean is moving toward Florida and could become a major hurricane.

Managers said Friday that the rocket is ready to blast off Tuesday on its first test flight without astronauts, after overcoming more hydrogen leaks during a fueling test earlier this week.

FILE - The NASA moon rocket stands on Pad 39B before a launch attempt for the Artemis 1 mission to orbit the moon at the Kennedy Space Center, Friday, Sept. 2, 2022, in Cape Canaveral, Fla. On Friday, Sept. 23, 2022, a storm in the Caribbean is threatening to delay NASA's third attempt to launch the rocket. (AP Photo/Brynn Anderson, File)

NASA said it will keep monitoring the forecast and decide no later than Saturday whether to not only delay the launch, but haul the rocket off the pad and back to the hangar. Officials said it’s unclear when the next launch attempt would be — whether October or even November — if the rocket must seek shelter indoors.

It takes three days of preparations to get the rocket back into Kennedy Space Center’s mammoth Vehicle Assembly Building, four miles away.

“I don’t think we’re cutting it close,” said NASA’s Tom Whitmeyer, deputy associate administrator for exploration systems. “We’re just taking it a step at a time.”

This would be the third launch attempt for the Space Launch System rocket, the most powerful ever built by NASA. Fuel leaks and other technical problems scrapped the first two tries.

The 322-foot (98-meter) rocket can withstand gusts of 85 mph (137 kph) at the pad, but only 46 mph (74 kph) once it’s on the move.

___

The Associated Press Health and Science Department receives support from the Howard Hughes Medical Institute’s Department of Science Education. The AP is solely responsible for all content.

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2022-09-23 18:09:55Z
1576143795

Undersea volcano eruption in Tonga was a "once-in-a-lifetime event" that could warm Earth's surface, scientists say - CBS News

When an undersea volcano erupted in Tonga in January, its watery blast was huge and unusual — and scientists are still trying to understand its impacts.

The volcano, known as Hunga Tonga-Hunga Ha'apai, shot millions of tons of water vapor high up into the atmosphere, according to a study published Thursday in the journal Science.

The researchers estimate the eruption, which dwarfed the power of the Hiroshima atomic bomb, raised the amount of water in the stratosphere - the second layer of the atmosphere, above the range where humans live and breathe - by around 5%.

Now, scientists are trying to figure out how all that water could affect the atmosphere, and whether it might warm Earth's surface over the next few years.

"This was a once-in-a-lifetime event," said lead author Holger Voemel, a scientist at the National Center for Atmospheric Research in Colorado.

FILE PHOTO: Satellite view of the eruption of an underwater volcano off Tonga
The eruption of an underwater volcano off Tonga is seen in an image from a NOAA GOES-West satellite taken on January 15, 2022. CIRA / NOAA / Handout via REUTERS

Big eruptions usually cool the planet. Most volcanoes send up large amounts of sulfur, which blocks the sun's rays, explained Matthew Toohey, a climate researcher at the University of Saskatchewan who was not involved in the study.

The Tongan blast was much soggier: The eruption started under the ocean, so it shot up a plume with much more water than usual. And since water vapor acts as a heat-trapping greenhouse gas, the eruption will probably raise temperatures instead of lowering them, Toohey said.

It's unclear just how much warming could be in store.

Karen Rosenlof, a climate scientist at the National Oceanic and Atmospheric Administration who was not involved with the study, said she expects the effects to be minimal and temporary.

"This amount of increase might warm the surface a small amount for a short amount of time," Rosenlof said in an email.

In August, scientists said it broke "all records" for the injection of water vapor since satellites began recording such data -- enough water vapor to fill 58,000 Olympic-sized swimming pools.

The water vapor will stick around the upper atmosphere for a few years before making its way into the lower atmosphere, Toohey said. In the meantime, the extra water might also speed up ozone loss in the atmosphere, Rosenlof added.

But it's hard for scientists to say for sure, because they've never seen an eruption like this one.

The stratosphere stretches from around 7.5 miles to 31 miles above Earth and is usually very dry, Voemel explained.

Voemel's team estimated the volcano's plume using a network of instruments suspended from weather balloons. Usually, these tools can't even measure water levels in the stratosphere because the amounts are so low, Voemel said.

Another research group monitored the blast using an instrument on a NASA satellite. In their study, published earlier this summer, they estimated the eruption to be even bigger, adding around 150 million metric tons of water vapor to the stratosphere - three times as much as Voemel's study found.

In that study, scientists also concluded that the unprecedented plume could temporarily affect Earth's global average temperature. 

Voemel acknowledged that the satellite imaging might have observed parts of the plume that the balloon instruments couldn't catch, making its estimate higher.

Either way, he said, the Tongan blast was unlike anything seen in recent history, and studying its aftermath may hold new insights into our atmosphere.

e2-tonga-ash-plume-width-1320.jpg
An image from the ISS from Jan. 16, 2022, shows the ash plume from the Hunga Tonga-Hunga Ha'apai volcanic eruption that occurred the day before.  NASA

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2022-09-23 11:02:00Z
1571707069

Kamis, 22 September 2022

Tonga volcano blast was unusual, could even warm the Earth - mySA

NEW YORK (AP) — When an undersea volcano erupted in Tonga in January, its watery blast was huge and unusual — and scientists are still trying to understand its impacts.

The volcano, known as Hunga Tonga-Hunga Ha’apai, shot millions of tons of water vapor high up into the atmosphere, according to a study published Thursday in the journal Science.

The researchers estimate the eruption raised the amount of water in the stratosphere — the second layer of the atmosphere, above the range where humans live and breathe — by around 5%.

Now, scientists are trying to figure out how all that water could affect the atmosphere, and whether it might warm Earth’s surface over the next few years.

“This was a once-in-a-lifetime event,” said lead author Holger Voemel, a scientist at the National Center for Atmospheric Research in Colorado.

Big eruptions usually cool the planet. Most volcanoes send up large amounts of sulfur, which blocks the sun’s rays, explained Matthew Toohey, a climate researcher at the University of Saskatchewan who was not involved in the study.

The Tongan blast was much soggier: The eruption started under the ocean, so it shot up a plume with much more water than usual. And since water vapor acts as a heat-trapping greenhouse gas, the eruption will probably raise temperatures instead of lowering them, Toohey said.

It’s unclear just how much warming could be in store.

Karen Rosenlof, a climate scientist at the National Oceanic and Atmospheric Administration who was not involved with the study, said she expects the effects to be minimal and temporary.

“This amount of increase might warm the surface a small amount for a short amount of time,” Rosenlof said in an email.

The water vapor will stick around the upper atmosphere for a few years before making its way into the lower atmosphere, Toohey said. In the meantime, the extra water might also speed up ozone loss in the atmosphere, Rosenlof added.

But it’s hard for scientists to say for sure, because they’ve never seen an eruption like this one.

The stratosphere stretches from around 7.5 miles to 31 miles (12 km to 50 km) above Earth and is usually very dry, Voemel explained.

Voemel's team estimated the volcano’s plume using a network of instruments suspended from weather balloons. Usually, these tools can’t even measure water levels in the stratosphere because the amounts are so low, Voemel said.

Another research group monitored the blast using an instrument on a NASA satellite. In their study, published earlier this summer, they estimated the eruption to be even bigger, adding around 150 million metric tons of water vapor to the stratosphere — three times as much as Voemel's study found.

Voemel acknowledged that the satellite imaging might have observed parts of the plume that the balloon instruments couldn’t catch, making its estimate higher.

Either way, he said, the Tongan blast was unlike anything seen in recent history, and studying its aftermath may hold new insights into our atmosphere.

___

The Associated Press Health and Science Department receives support from the Howard Hughes Medical Institute’s Department of Science Education. The AP is solely responsible for all content.

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2022-09-22 18:10:55Z
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James Webb space telescope captures Neptune rings and moons - Sky News

NASA has released new images capturing Neptune and its rings, taken by the James Webb space telescope in July.

Neptune is the solar system's outermost planet which has thin rings with faint dust bands around it.

These have been observed in infrared for the first time, allowing for seven of Neptune's 14 moons to be captured.

The seven that can be viewed from the newly-released shots are Galatea, Naiad, Thalassa, Despina, Proteus, Larissa, and Triton.

Triton is Neptune's largest and most unusual moon, which dominates the James Webb image of Neptune as a beaming point of light, creating signature diffraction spikes that are seen in many images.

Webb recently showed Jupiter at its clearest in photos publicised last month.

The new telescope was launched last Christmas and experts are hope to be able to look back to the beginning of time when stars and galaxies were formed.

James Webb Space Telescope  captures  view of  Neptune's  rings 
Credit: NASA, ESA, CSA, STScI

NASA's Voyager 2 was the first spacecraft to view the icy, blue planet of Neptune in a 1989 flyby.

Heidi Hammel, of the Space Science Institute, said it had been three decades since astronomers last saw the rings from Neptune in detail.

And Ms Hammel wrote on Twitter: "More than 20 years in the making, and the James Webb Space Telescope delivered.

"...And that bright blue "star"? That's no star! That's Neptune's fantastic moon Triton! It looks brighter than Neptune because at these near-IR wavelengths, Neptune's atmospheric methane absorbs sunlight, making the planet darker - this is also why the rings pop out."

James Webb is the world's biggest and most powerful telescope and is floating about 930,000 miles above us.

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2022-09-22 11:37:17Z
1574189963

Trending on WION | James Webb telescope captures stunning image of Neptune and its rings - WION

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2022-09-22 09:24:15Z
1574189963

Rabu, 21 September 2022

Blinding light of Mars spotted by Webb telescope - CTV News

The James Webb Space Telescope's main goal is to detect faint light from distant galaxies, but it recently observed one of the brightest objects in the night sky: Mars.

The space observatory captured its first images and data of the red planet on September 5.

Multiple orbiters above Mars, and the land-bound rovers Curiosity and Perseverance, roam the surface, regularly send back insights. Webb's infrared capabilities contribute another perspective that could reveal details about the Martian surface and atmosphere.

Webb, located a million miles (1.6 million kilometres) from Earth, can spot the sunlit side of Mars that faces the space telescope, which puts the observatory in the perfect position to spy the planet's seasonal changes, dust storms and weather all at once.

The telescope is so sensitive that astronomers had to make adjustments to prevent the blinding infrared light of Mars from saturating Webb's detectors. Instead, Webb observed Mars using very short exposures.

The new images depict Mars' eastern hemisphere in different wavelengths of infrared light. To the left is a reference map of the hemisphere captured by the Mars Global Surveyor mission, which ended in 2006.

The top-right image from Webb shows reflected sunlight on the Martian surface, showcasing Martian features like the Huygens Crater, dark volcanic rock and the Hellas Planitia, a massive impact crater on the red planet that stretches for more than 1,200 miles (2,000 kilometres).

The lower-right image shows the thermal emission of Mars, or the light emitted by the planet as it loses heat. The brightest areas indicate the warmest spots. Additionally, astronomers spotted something else in the thermal emission image.

When this thermal light passes through the Martian atmosphere, some of it is absorbed by carbon dioxide molecules. This phenomenon has caused the Hellas Planitia to appear darker.

"This is actually not a thermal effect at Hellas," said Geronimo Villanueva, a planetary scientist at NASA's Goddard Space Flight Center, in Greenbelt, Maryland, in a statement.

"The Hellas Basin is a lower altitude, and thus experiences higher air pressure," said Villanueva, who is also the principal investigator of Mars and Ocean Worlds studies for Webb. "That higher pressure leads to a suppression of the thermal emission at this particular wavelength range due to an effect called pressure broadening. It will be very interesting to tease apart these competing effects in these data."

With Webb's powerful capabilities, Villanueva and his team also captured the first near-infrared spectrum of Mars.

The spectrum indicates more subtle differences in brightness across the planet, which could highlight aspects of the Martian surface and atmosphere. An initial analysis has revealed information about icy clouds, dust, rock types on the surface and the composition of the atmosphere contained in the spectrum. There are also signatures of water, carbon dioxide and carbon monoxide.

The NASA research team will share more about Webb's observations of Mars in a study that will be submitted for peer review and publication in the future. And the Mars team is looking forward to using Webb's capabilities to pick out the differences between regions on the red planet and search for gases like methane and hydrogen chloride in the atmosphere.

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2022-09-21 15:11:51Z
CAIiEI7-f7lDqxRJCIuKOdIhSioqGQgEKhAIACoHCAow6f-ICzDjj4gDMJTFnwY

Exoplanets study reveals uniqueness of Earth's climate - Innovation News Network

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  1. Exoplanets study reveals uniqueness of Earth's climate  Innovation News Network
  2. Earth-like exoplanets unlikely to be another 'pale blue dot'  Phys.org
  3. View Full coverage on Google News

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2022-09-21 09:32:06Z
1573138892

Selasa, 20 September 2022

Philadephia’s Diatom Archive Is a Way, Way, Wayback Machine - Hakai Magazine

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Nestled in the heart of Philadelphia, Pennsylvania, the Academy of Natural Sciences of Drexel University emanates the aura of a sprawling cabinet of curiosities. Its neoclassical facade is covered in natural motifs—doorways flanked by ammonites, handrails that curl into ferns, bronze door handles shaped like ibis skulls. As the oldest natural science institution in the western hemisphere, the academy has accumulated a trove of remarkable specimens. Among the 19 million or so specimens housed here are plants procured on the Lewis and Clark Expedition, blue marlin reeled in by Ernest Hemingway, and America’s first mounted dinosaur skeleton.

Many of the academy’s most unassuming yet impactful treasures are filed away on its second floor, in an office space crowded with hulking cabinets and microscopes. Next to one of these microscopes, curator Marina Potapova pops open a notebook-sized plastic container brimming with glass slides. To the untrained eye, these unremarkable slides seem filthy—each looks like it’s been smudged by dirty fingers.

But as soon as Potapova slips one under a microscope lens, the slide’s contents dazzle. Dozens of diatoms—microscopic, single-celled algae encased in sturdy silica walls and found wherever there is water—are fixed to the slides in a myriad of shapes.

container of microscope slides

With over four million specimens, the Academy of Natural Sciences of Drexel University’s diatom collection in Philadelphia, Pennsylvania, is the second largest in the world. Photo by Jack Tamisiea

Some are elongated like baguettes or flattened into saucers while others hook together to resemble translucent centipedes. Others are barbed like harpoons or shaped like pudgy sea stars. Some even resemble ornate stained-glass windows. Under a microscope, a few drops of murky pond water become a kaleidoscope of diatom diversity.

The beauty of diatoms is impressive. But their ecological significance is staggering. Diatoms anchor marine food webs by feeding everything from minuscule zooplankton to mammoth filter feeders. (Case in point: scientists have deduced that the rise of whales some 30 million years ago mirrors a spike in diatom diversity.) Diatoms also have an outsized atmospheric impact. As one of the planet’s most prolific organisms, diatoms siphon harmful gases like carbon dioxide out of the air and produce massive stores of oxygen as they photosynthesize. It is estimated that roughly one-quarter of the air we breathe is created by diatoms.

More than four million specimens of these essential algae are plastered onto hundreds of thousands of slides and housed in the academy’s diatom herbarium. Only London’s Natural History Museum stores more slides of diatoms.

Although the academy’s diatoms no longer feed the planktonic masses or pump oxygen into the atmosphere, they do hold clues about how the aquatic world is changing. As their tough shells sink to the bottom of a body of water, they are stored in the sediment for millennia. When researchers use a sediment core to drill down into the muddy bottom of an estuary, they are collecting diatoms deposited over the eons.

In addition to being plentiful and hardy, diatoms are also a crucial barometer for a variety of environmental conditions. The existence of certain diatom species can help scientists pinpoint everything from industrial pollution to oxygen depletion. Potapova and her colleagues have recently used these water condition time capsules to gauge how accelerating sea level rise is endangering New Jersey’s coastal wetlands.

diatoms

Diatoms, a type of phytoplankton made of silica and coming in myriad shapes and forms, underpin marine food webs and have an outsized impact on the health of Earth’s atmosphere. Photo by Scenics & Science/Alamy Stock Photo

Thanks to a relative dearth of environmental monitoring, the historical decline of these crucial marshes—which hoard carbon, provide nursery grounds for fish, and buffer the coast from storms—has largely been obscured, making restoration efforts little more than guesswork.

However, the millions of diatoms stored at the academy are helping the researchers track the fall of the coastal wetlands as the ocean rises, which may help anticipate the coast’s future. “Diatoms are absolutely invaluable environmental archives,” Potapova says. “You can infer the future from what they tell you about the past.”


Considering the academy’s history, it is no wonder that the storied institution has become a hub for diatoms. With the advent of accessible microscopy in the 1850s, many of Philadelphia’s gentleman naturalists were captivated by the realm of minute microbes, eventually establishing the Microscopical Society of Philadelphia at the academy.

Because of their striking beauty, diatoms took the microscopical society by storm. To satiate their interest, many of these diatomists headed east to the New Jersey coastline to collect samples, which they mounted onto glass slides using a steady hand and a brush brimming with pig eyelashes. The hobbyists would then gather at the academy to show off their slides at gourmet luncheons.

The academy’s early members were clearly enthusiastic about diatoms, but most were amateurs and published little research on the myriad of specimens they collected. Organizing the mountains of slides compiled by each collector into a cohesive collection proved to be quite the task for Ruth Patrick when she arrived at the academy in 1933. The daughter of an amateur diatomist who received her first microscope at the age of seven, Patrick gravitated toward diatoms early in her childhood and eventually completed her PhD studying the microscopic organisms. Despite her scientific credentials, she was relegated to setting up microscopes and slides for the untrained hobbyists. It took her years to even gain membership in the male-dominated academy. But her persistence paid off, and in 1937 she became curator of the nascent diatom herbarium.

Patrick’s first goal was organizing the amalgamation of different collections into a unified and comprehensive source for taxonomic research. When she was not mounting and organizing slides, she was wading into nearby ponds and streams to collect new specimens in the field, where she gradually gained an appreciation for the ecological importance of diatoms.

Ruth Patrick

Ruth Patrick, the first curator of the academy’s diatoms, works on the collection in the 1940s. Photo courtesy of Academy of Natural Sciences Archives coll. 457

This crystalized during a 1948 expedition to Pennsylvania’s Conestoga River—a body of water heavily polluted by sewage and industrial runoff. As her team collected samples from throughout the creek, she recognized patterns in the diatom composition. Some species’ densities exploded in areas contaminated with sewage, while others thrived in spots tainted with chemicals. Soon, Patrick became adept at using the existence of certain diatoms as a key for diagnosing pollution in lakes and rivers. This supported the idea that greater diatom diversity correlated with healthier freshwater ecosystems—an insight ecologists coined the Patrick Principle.

Patrick revolutionized the use of diatoms to monitor freshwater systems, but using them in coastal wetlands lagged behind. The brackish fusion of fresh and salt water in coastal zones such as estuaries creates habitats that are dynamic and complex with a mixture of inland and oceanic diatoms, according to Mihaela Enache, a research scientist at the New Jersey Department of Environmental Protection (NJDEP).

However, in recent decades, the sea has dominated the once-dynamic coastal margin, propelling farther inland as sea levels rise. Over the last century, the sea level along New Jersey has risen by 0.45 meters, more than double the global average of 0.18 meters. By 2100, the sea could rise by over a meter.

This dramatic rise in sea level has proven disastrous for the patchwork of marshes along New Jersey’s coastline, several of which have already succumbed to the sea. However, the full extent of the loss of these wetlands is difficult to parse because environmental monitoring only dates back a few decades.

Without a sense of a wetland’s natural conditions, ecological restoration is daunting. Having that information is crucial, says Enache. “Without [it], you are in the dark.” Thankfully, some of this missing data is recorded in the academy’s cache of diatoms.


Like most coastal margins, New Jersey is familiar with sea level rise. During the Pleistocene, when New Jersey was blanketed by ice and home to mastodons, sea ice slurped up stores of seawater. Around 18,000 years ago, sea levels sank more than 130 meters below their current levels—extending the New Jersey coastline 110 kilometers farther into the Atlantic Ocean.

The end of the last ice age sparked a steady climb in sea levels. Retreating ice sheets caused parts of New Jersey to sink. This subsidence, combined with glacial melt, proved a potent mix for rapid sea level rise according to Jennifer Walker, a sea level researcher at Rutgers University.

In a study published last year, Walker turned to the past to put New Jersey’s current bout of sea level rise in context. “If we can understand how temperatures, atmosphere, and sea level changes are all interconnected in the past, that’s what we can use to project changes in the future.”

To gauge fluctuating sea levels over the past 2,000 years, her team examined the shells of single-celled protists called foraminifera that are finely calibrated to specific environmental conditions. This makes them a valuable proxy for reconstructing shifts in sea levels. By identifying the presence of certain foraminifera species throughout sediment cores collected from different spots along the Jersey shore, her team concluded that New Jersey’s coast is experiencing the fastest rise of sea level in 2,000 years.

The NJDEP hoped diatoms could serve as a similar tool for understanding how coastal marshes responded to the rising sea. Like foraminifera, each diatom species is extremely sensitive to environmental conditions. For example, species like the rolling pin–shaped Nitzschia microcephala thrive in nitrogen-rich environments, making their shells a common sign of nutrient pollution. Other species, like Diploneis smithii, whose segmented shell resembles a slender trilobite, prefer saline waters. Their existence inland is a good indication of past sea level intrusion and helps researchers deduce which marshes have been prone to flooding in the past.

To pinpoint where these microscopic indicators once existed, the NJDEP deployed a team of researchers into several marshes along the coastline, ranging from heavily polluted wetlands in the north to near-pristine tidal marshes in the south. At each site, they cored into the marsh muck, sampling as deep as two meters in certain spots. Enache compares this method to slicing into a stack of pancakes—as you cut deeper, you are essentially going back in time from the steaming pancake just off the griddle to the soggy pancake deposited at the bottom of the stack. As they dug deeper, the researchers were traveling back decades. In total, they collected nine cores from five wetlands.

The NJDEP then sent the sediment cores to Philadelphia, where Potapova and her master’s student Nina Desianti gauged the diatom diversity of New Jersey’s coastal wetlands through time. Desianti began processing the diatom specimens by soaking the sediment samples in strong acid to dissolve everything but the silica shell before adhering them to slides. The result was an environmental history of each of the five marshes mounted onto thousands of glass slides. Then, by using the specimens already cataloged at the academy, they played a microscopic game of who’s who. But even the sprawling diatom herbarium lacked all the answers—Desianti estimates that over one-third of the 900-odd species they collected from the wetlands are new to science.

Marina Potapova

Marina Potapova, curator at the Academy of Natural Sciences of Drexel University, samples for diatoms. Photo courtesy of Academy of Natural Sciences of Drexel University

The monumental effort yielded the tome Diatom Flora of the New Jersey Coastal Wetlands in 2019. To the uninitiated, it is an overwhelming mix of intimidating Latinized names and dramatic electron microscope photographs that portray the diatoms in all their infinitesimal glory. To Enache, it’s the key to decoding the decline of New Jersey’s wetlands. By punching the composition of diatom species and modern wetland conditions into modeling programs, Enache is able to illustrate what a wetland once looked like. “Diatom species are a very precious environmental archive because we can go back in time—when nobody could take measurements of nutrients, nobody could take measurements of pH—and actually use the diatom species to get complete numbers,” she says. These figures help her record the increase of everything from agricultural nutrients to industrial chemicals in New Jersey’s water all the way back to the mid-1600s, when Europeans arrived and began to dramatically alter the state.

But while diatoms offer a window into the decline of New Jersey’s marshes, they also offer a glimpse of environmental resiliency to Desianti. Just as the team used the salt tolerance of different diatoms to map past episodes of sea level rise, they could also use the microscopic algae to deduce how these marshes responded to saltwater intrusion.

When it comes to habitats, marshes are particularly dynamic. As the boggy barriers between land and sea, coastal marshes hoard sediment, building vertically to stay above the rising ocean. When sea level rise outpaces their accumulation of sediment, the marshes retreat inland by spilling into coastal forests. As the marsh’s briny water percolates into the groundwater, it kills the trees, creating what ecologists call “ghost forests” of desiccated tree husks.

Marina Potapova at a microscope

Potapova examines diatoms sampled from the coast in an Academy of Natural Sciences of Drexel University lab. Photo by Jack Tamisiea

While coastal marshes are naturally pliable, anthropogenic impacts have rendered them brittle. In New Jersey, dams strain out sediment, robbing the marsh of construction material, and retreating marshes butt up against paved roads and vacation homes. “Salt marshes have to compete with us in establishing habitat,” says Desianti, who now uses diatoms to track nutrient pollution for the Wisconsin State Laboratory of Hygiene. “As a result, these salt marshes are squeezed between sea level rise and human pressures.”


The diatoms Potapova and Desianti collected and identified will help the NJDEP not only understand how New Jersey’s coastal wetlands have responded to past bouts of sea level rise but also inform what can be done to restore these vibrant ecosystems.

The deeper you core into the pond muck, the more diverse the diatoms tend to be, which, as Ruth Patrick deduced decades ago, is the trademark of a healthy ecosystem. As you examine a core’s more recent chapters, this diatomic diversity often decreases as certain specialists, like salt-loving marine diatoms, dominate. Understanding where these saline-specializing species persist reveals which ecosystems have succumbed to sea level rise and where restoration efforts, like an influx of sediment, are needed the most.

Diatoms are not a cure for threats like sea level rise and pollution. Instead, they are a key to help combat them. They reveal what pristine habitats were once like long before anyone paid attention and illustrate what has gone awry over the centuries. To enact successful wetland restoration measures, it would be wise to consult these microscopic algae.

Which is why the diatom specimens Potapova and Desianti collected in New Jersey’s coastal marshes are being filed away alongside Patrick’s specimens in the diatom herbarium’s steel cabinets. Similarly to how they persist in sediment for millennia, the diatom specimens stored at the academy will offer invaluable data points for future researchers to make sense of pollution and shifting sea levels.

“The diatom herbarium is an invaluable resource for diatom research,” says Desianti. “I’m sure that in the future, even when I’m gone, people will still access this collection and continue to investigate environmental issues.” She is confident that within the tens of thousands of slides deposited in the recesses of the academy are environmental breakthroughs waiting to be decoded.

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2022-09-20 07:08:43Z
CBMiXWh0dHBzOi8vaGFrYWltYWdhemluZS5jb20vZmVhdHVyZXMvcGhpbGFkZXBoaWFzLWRpYXRvbS1hcmNoaXZlLWlzLWEtd2F5LXdheS13YXktYmFjay1tYWNoaW5lL9IBAA