Orbiter.ch Space News

lundi 12 mars 2018

Investigations this week set the stage for longer missions in space

ISS - Expedition 55 Mission patch.

March 12, 2018

Image above: Flying over China seen by EarthCam on ISS, speed: 27'621 Km/h, altitude: 404,51 Km, image captured by Roland Berga (on Earth in Switzerland) from International Space Station (ISS) using ISS-HD Live application with EarthCam's from ISS on March 13, 2018 at 00:44 UTC.

Kicking off the new week, the Expedition 55 crew aboard the International Space Station continued studies evaluating crew health, performance and sustainability for long-duration space missions.

For one such investigation, a crewmate set up Neuromapping hardware to perform tests for Flight Day 90, conducting strapped in and free-floating body configurations. This experiment studies whether long missions can cause changes to brain structure and function, motor control and multitasking abilities, as well as how long it would take the brain and body to recover from the possible effects. Previous anecdotal evidence supplied by astronauts suggests that movement control and cognition can be affected in microgravity.

Image above: The crew continued work with Veggie-03, watering the lettuce plants, documenting growth and selecting some for consumption. Image Credit: NASA.

The crew also continued work with Veggie-03, watering the lettuce plants, documenting growth and selecting some for consumption. Veggie-03 supports the concept that for future long-duration space missions, a fresh food supply can be grown in space to supplement the crew while far from home.

On the ground, Expedition 55-56, consisting of Soyuz Commander Oleg Artemyev and NASA Flight Engineers Ricky Arnold and Drew Feustel, checked off more reviews of launch day and rendezvous procedures in anticipation of a March 21 liftoff from the Baikonur Cosmodrome in a Soyuz MS-08 spacecraft. They will join the crew already in orbit following a March 23 docking.

Related links:

Neuromapping: https://www.nasa.gov/mission_pages/station/research/experiments/1007.html

Veggie-03: https://www.nasa.gov/mission_pages/station/research/experiments/explorer/Investigation.html?#id=1159

Expedition 55: https://www.nasa.gov/mission_pages/station/expeditions/expedition55/index.html

Space Station Research and Technology: https://www.nasa.gov/mission_pages/station/research/index.html

International Space Station (ISS): https://www.nasa.gov/mission_pages/station/main/index.html

Images (mentioned), Text, Credits: NASA/Mark Garcia/Orbiter.ch Aerospace/Roland Berga.

Best regards, Orbiter.ch

Space Station Science Highlights: Week of Mar 5, 2018

ISS - Expedition 55 Mission patch.

March 12, 2018

The crew members aboard the International Space Station were busy with scientific operations this week as their on-ground counterparts completed final preparations for their upcoming launch at the Baikonur Cosmodrome.

NASA astronauts Ricky Arnold and Drew Feustel, and cosmonaut Oleg Artemyev of Roscosmos, will join Anton Shkaplerov of Roscomos, Scott Tingle of NASA and Norishige Kanai of the Japan Aerospace Exploration Agency aboard the orbiting laboratory following their March 21 launch.

Take a look at some of the science that happened this week aboard the station:

Bubble Detectors released into station for radiation detection

The RaDI-N2 Neutron Field Study (Radi-N2) measures neutron radiation levels aboard the orbiting laboratory using Space Bubble Detectors. Results from this investigation may provide a better understanding of the connections between neutron radiation and DNA damage and mutation rates, symptoms that affect some astronauts, and other radiation health issues.

Animation above: Another batch of plants is growing aboard the space station. Arabidopsis and Dwarf Wheat are currently growing inside the new Advanced Plant Habitat. APH provides a laboratory for the comprehensive study of plant metabolism, transcription, protein production and much more. Animation Credit: NASA.

This week, crew members deployed eight Space Bubble Detectors, designed to detect neutrons and ignore all other forms of radiation.

Crew enjoys space-grown veggies

Future long-duration missions into the solar system will require a fresh food supply to supplement crew diets, which means growing crops in space. The Veg-03 investigation expands on previous validation tests of the new Veggie hardware, which crew members will soon use to grow cabbage, lettuce and other fresh vegetables in space.

Our space gardeners were busy this week as they watered, pruned, and photographed the plants, which are growing in special plant pillows. Finally, the crew enjoyed the first harvest of Mizuna and red romaine lettuce from the VEG-03 investigation.

Image above: NASA astronaut Scott Tingle waters the crops as a part of the Veg-03 investigation. Image Credit: NASA.

This marks the first time that two grow-outs have been initiated using two Veggie facilities in parallel aboard the space station. These plants will provide the crew the opportunity to consume fresh vegetables every few days, while some of the products from this run will be returned to Earth for testing.

Image above: NASA astronaut Scott Tingle harvested mizuna and red romaine lettuce as a part of the Veg-03 investigation. Portions of the harvest were consumed by crew members. Image Credit: NASA.

Crew’s airway tested for Nitric Oxide

With dust particles present in the space station atmosphere, Airway Monitoring studies the occurrence and indicators of airway inflammation in crewmembers, using ultra-sensitive gas analyzers to analyze exhaled air. This helps to highlight any health impacts and to maintain crewmember well-being on future human spaceflight missions, especially longer-duration missions to the Moon and Mars for example, where crewmembers will have to be more self-sufficient in highlighting and avoiding such conditions. This kind of research may also benefit similar conditions, such as asthma, on Earth.

This week, crewmembers performed two different measurement protocols; the low Nitric Oxide (NO) protocol which determines how much NO is exhaled with the respiration, and the high NO protocol, which determines how much NO is diffused into the blood.

International Space Station (ISS). Image Credit: NASA

Crew prepares for next week’s ACME operations

The Advanced Combustion Microgravity Experiment (ACME) investigation is a set of studies of gaseous flames to be conducted in the Combustion Integration Rack (CIR), one of which being Electric-Field Effects on Laminar Diffusion Flames (E-FIELD Flames).

In E-FIELD Flames, an electric field with voltages as high as 10,000 volts is established between the burner and a mesh electrode. The motion of the charged ions, which are naturally produced within the flame, are strongly affected by a high-voltage electric field. The resulting ion-driven wind can dramatically influence the stability and sooting behavior of the flame. Measurements are made of electric-field strength, the ion current passing through the flame, and flame characteristics such as the size, structure, temperature, soot, and stability. Conducting the tests in microgravity enables new understanding and the development of less polluting and more efficient combustion technology for use on Earth.

Space to Ground: A Unique Experience: 03/09/2018

Arrested Development: Hubble Finds Relic Galaxy Close to Home

NASA - Hubble Space Telescope patch.

March 12, 2018

Astronomers have put NASA's Hubble Space Telescope on an Indiana Jones-type quest to uncover an ancient "relic galaxy" in our own cosmic backyard.

The very rare and odd assemblage of stars has remained essentially unchanged for the past 10 billion years. This wayward stellar island provides valuable new insights into the origin and evolution of galaxies billions of years ago.

Zoom to NGC 1277

Video above: This video zooms into the relic galaxy NGC 1277 near the center of the Perseus cluster of over 1,000 galaxies, located 240 million light-years from Earth.
Video Credits: NASA, ESA, and J. DePasquale (STScI).

The galaxy, NGC 1277, started its life with a bang long ago, ferociously churning out stars 1,000 times faster than seen in our own Milky Way today. But it abruptly went quiescent as the baby boomer stars aged and grew ever redder.

The findings are being published online in the March 12 issue of the science journal Nature.

Image above: This is a Hubble Space Telescope image of galaxy NGC 1277. The galaxy is unique in that it is considered a relic of what galaxies were like in the early universe. The galaxy is composed exclusively of aging stars that were born 10 billion years ago. But unlike other galaxies in the local universe, it has not undergone any further star formation. Astronomers nickname such galaxies as "red and dead," because the stars are aging and there aren't any successive generations of younger stars. The telltale sign of the galaxy's "arrested development" lies in the ancient globular clusters that swarm around it. The reddish clusters are the strongest evidence that the galaxy went out of the star-making business long ago. Otherwise, there would be a lot of blue globular star clusters, which are largely absent. The lack of blue clusters suggests that NGC 1277 never grew further by gobbling up surrounding galaxies. The galaxy lives near the center of the Perseus cluster of over 1,000 galaxies, located 240 million light-years away from Earth. NGC 1277 is moving so fast through the cluster, at 2 million miles per hour, that it cannot merge with other galaxies to collect stars or pull in gas to fuel star formation. In addition, near the galaxy cluster center, intergalactic gas is so hot it cannot cool to condense and form stars. Image Credits: NASA, ESA, and M. Beasley (Instituto de Astrofísica de Canarias).

Though Hubble has seen such "red and dead" galaxies in the early universe, one has never been conclusively found nearby. Where the early galaxies are so distant, they are just red dots in Hubble deep-sky images. NGC 1277 offers a unique opportunity to see one up close and personal. "We can explore such original galaxies in full detail and probe the conditions of the early universe," said Ignacio Trujillo, of the Instituto de Astrofisica de Canarias at the University of La Laguna, Spain.

The researchers learned that the relic galaxy has twice as many stars as our Milky Way, but physically it is as small as one quarter the size of our galaxy. Essentially, NGC 1277 is in a state of "arrested development." Perhaps like all galaxies it started out as a compact object but failed to accrete more material to grow in size to form a magnificent pinwheel-shaped galaxy.

Approximately one in 1,000 massive galaxies is expected to be a relic (or oddball) galaxy, like NGC 1277, researchers say. They were not surprised to find it, but simply consider that it was in the right place at the right time to evolve - or rather not evolve - the way it did.

Animation above: This is a blink comparison that plots the location of the red stars and blue stars that dominate the globular clusters in galaxies NGC 1277 and NGC 1278. It shows that NGC 1277 is dominated by ancient red globular clusters. This is evidence that galaxy NGC 1277 stopped making new stars many billions of years ago, compared to NGC 1278, which has more young blue star clusters. Image Credits: NASA, ESA, and Z. Levay (STScI).

The telltale sign of the galaxy's state lies in the ancient globular clusters of stars that swarm around it. Massive galaxies tend to have both metal-poor (appearing blue) and metal-rich (appearing red) globular clusters. The red clusters are believed to form as the galaxy forms, while the blue clusters are later brought in as smaller satellites are swallowed by the central galaxy. However, NGC 1277 is almost entirely lacking in blue globular clusters. "I've been studying globular clusters in galaxies for a long time, and this is the first time I've ever seen this," said Michael Beasley, also of the Instituto de Astrofisica de Canarias.

The red clusters are the strongest evidence that the galaxy went out of the star-making business long ago. However, the lack of blue clusters suggests that NGC 1277 never grew further by gobbling up surrounding galaxies.

By contrast, our Milky Way contains approximately 180 blue and red globular clusters. This is due partly to the fact that our Milky Way continues cannibalizing galaxies that swing too close by in our Local Group of a few dozen small galaxies.

Image above: [Inset] —This is a Hubble Space Telescope image of galaxy NGC 1277. The galaxy is unique in that it is considered a relic of what galaxies were like in the early universe. The galaxy is composed exclusively of aging stars that were born 10 billion years ago. But unlike other galaxies in the local universe, it has not undergone any further star formation. Astronomers nickname such galaxies as "red and dead," because the stars are aging and there aren't any successive generations of younger stars. The telltale sign of the galaxy's "arrested development" lies in the ancient globular clusters that swarm around it. The reddish clusters are the strongest evidence that the galaxy went out of the star-making business long ago. Otherwise, there would be a lot of blue globular star clusters, which are largely absent. The lack of blue clusters suggests that NGC 1277 never grew further by gobbling up surrounding galaxies. [Background image] — The galaxy lives near the center of the Perseus cluster of over 1,000 galaxies, located 240 million light-years away from Earth. NGC 1277 is moving so fast through the cluster, at 2 million miles per hour, that it cannot merge with other galaxies to collect stars or pull in gas to fuel star formation. In addition, near the galaxy cluster center, intergalactic gas is so hot it cannot cool to condense and form stars. Image Credits: NASA, ESA, M. Beasley (Instituto de Astrofísica de Canarias), and P. Kehusmaa.

It's a markedly different environment for NGC 1277. The galaxy lives near the center of the Perseus cluster of over 1,000 galaxies, located 240 million light-years away. But NGC 1277 is moving so fast through the cluster, at 2 million miles per hour, that it cannot merge with other galaxies to collect stars or pull in gas to fuel star formation. In addition, near the galaxy cluster center, intergalactic gas is so hot it cannot cool to condense and form stars.

The team started looking for "arrested development" galaxies in the Sloan Digital Sky Survey and found 50 candidate massive compact galaxies. Using a similar technique, but out of a different sample, NGC 1277 was identified as unique in that it has a central black hole that is much more massive than it should be for a galaxy of that size. This reinforces the scenario that the supermassive black hole and dense hub of the galaxy grew simultaneously, but the galaxy's stellar population stopped growing and expanding because it was starved of outside material.

Hubble Space Telescope (HST). Animation Credits: ESA/NASA

"I didn't believe the ancient galaxy hypothesis initially, but finally I was surprised because it's not that common to find what you predict in astronomy," Beasley added. "Typically, the universe always comes up with more surprises that you can think about."

The team has 10 other candidate galaxies to look at with varying degrees of "arrested development."

The upcoming NASA James Webb Space Telescope (scheduled for launch in 2019) will allow astronomers to measure the motions of the globular clusters in NGC 1277. This will provide the first opportunity to measure how much dark matter the primordial galaxy contains.

The Hubble Space Telescope is a project of international cooperation between NASA and ESA (European Space Agency). NASA's Goddard Space Flight Center in Greenbelt, Maryland, manages the telescope. The Space Telescope Science Institute (STScI) in Baltimore, Maryland, conducts Hubble science operations. STScI is operated for NASA by the Association of Universities for Research in Astronomy, in Washington, D.C.

For images and more information about this study and Hubble, visit:

http://www.nasa.gov/hubble

http://hubblesite.org/news_release/news/2018-17

Images (mentioned), Animations (mentioned), Video (mentioned), Text, Credits: NASA/Karl Hille/Space Telescope Science Institute/Ray Villard/Instituto de Astrofisica de Canarias/Michael Beasley.

Best regards, Orbiter.ch

dimanche 11 mars 2018

Making antimatter transportable

CERN - European Organization for Nuclear Research logo.

March 11, 2018

Antimatter vanishes instantly when it meets matter. But researchers have developed ways to trap it and increase its lifespan in order to use it to study matter. A new project called PUMA (antiProton Unstable Matter Annihilation) aims to trap a record one billion antiprotons at CERN’s GBAR experiment at the ELENA facility and keep them for several weeks.

Image above: Panoramic view of the low energy beam lines in the ISOLDE hall (Image: Samuel Morier-Genoud/CERN).

Such a long storage time would allow the trapped antiprotons to be loaded into a van and transported to the neighbouring ISOLDE ion-beam facility located a few hundred metres away. At ISOLDE, the antiprotons would then be collided with radioactive ions so that exotic nuclear phenomena could be studied.

To trap the antiprotons for long enough for them to be transported and used at ISOLDE, PUMA plans to use a 70-cm-long “double-zone” trap inside a one-tonne superconducting solenoid magnet and keep it under an extremely high vacuum (10^-17 mbar) and at cryogenic temperature (4 K). The so-called storage zone of the trap will confine the antiprotons, while the second zone will host collisions between the antiprotons and radioactive nuclei that are produced at ISOLDE but decay too rapidly to be transported and studied elsewhere.

Image above: The ELENA ring prior to the start of first beam in 2016 (Image: CERN).

The project hopes to study the properties of radioactive nuclei by measuring the pion particles emitted in the collisions between the nuclei and the antiprotons. Such measurements would help determine how often the antiprotons annihilate with the nuclei’s protons or neutrons, and, therefore, their relative densities at the surface of the nucleus. The relative densities would then indicate whether the nuclei have exotic properties, such as thick neutron skins, which correspond to a significantly higher density of neutrons than protons at the nuclear surface, and extended halos of protons or neutrons around the nuclear core.

Today, CERN is the only place in the world where low-energy antiprotons are produced, but “this project might lead to the democratisation of the use of antimatter”, says Alexandre Obertelli, a physicist from the Darmstadt technical university TU Darmstadt who is leading the project. He plans to build and develop the solenoid, trap and detector in the coming two years, with the aim of producing the first collisions at CERN in 2022.

Image above: Antimatter’s journey between the ELENA and ISOLDE facilities (Image: CERN).

Obertelli was awarded an ERC Consolidator Grant from the European Research Council and the five-year PUMA project was launched in January this year. Along with researchers from RIKEN in Japan and CEA Saclay and IPN Orsay in France, he has submitted a letter of intent to CERN’s experiment committee to pave the way towards PUMA becoming a CERN-recognised experiment.

Find out more: http://cern.ch/go/M8lp

Note:

CERN, the European Organization for Nuclear Research, is one of the world’s largest and most respected centres for scientific research. Its business is fundamental physics, finding out what the Universe is made of and how it works. At CERN, the world’s largest and most complex scientific instruments are used to study the basic constituents of matter — the fundamental particles. By studying what happens when these particles collide, physicists learn about the laws of Nature.

The instruments used at CERN are particle accelerators and detectors. Accelerators boost beams of particles to high energies before they are made to collide with each other or with stationary targets. Detectors observe and record the results of these collisions.

Founded in 1954, the CERN Laboratory sits astride the Franco–Swiss border near Geneva. It was one of Europe’s first joint ventures and now has 22 Member States.

Related links:

Darmstadt technical university: https://www.tu-darmstadt.de/vorbeischauen/aktuell/news_details_198528.en.jsp

ELENA: https://home.cern/about/accelerators/antiproton-decelerator

ISOLDE: https://home.cern/about/experiments/isolde

For more information about European Organization for Nuclear Research (CERN), Visit: https://home.cern/

Images (mentioned), Text, Credits: CERN/Cristina Agrigoroae.

Best regards, Orbiter.ch

Accelerator hibernation ends

CERN - European Organization for Nuclear Research logo.

March 11, 2018

Large Hadron Collider (LHC). Image Credit: CERN

On 9 March 2018, marks the end of CERN’s annual winter shut down. The Laboratory’s massive accelerator complex will soon begin to lumber out of its winter hibernation and resume accelerating and colliding particles.

But while the Large Hadron Collider (LHC) has not been filled with protons since the Year-End Technical Stop (YETS) began on 4 December 2017, its tunnels and experimental caverns have been packed with people performing maintenance and repairs as well as testing components for future accelerators.

What's up at CERN during the "winter shutdown"?

Video above: Watch this short overview of activities from around the LHC ring during the YETS (Video: CERN).

CERN’s Engineering department hands the accelerator complex back to the Beams department, who will commence hardware commissioning for 2018. This commissioning will culminate in the restart of the LHC, planned for early April.

Find out more about what has been happening during the winter shutdown for the LHC, the injectors and the experiments.

Note:

CERN, the European Organization for Nuclear Research, is one of the world’s largest and most respected centres for scientific research. Its business is fundamental physics, finding out what the Universe is made of and how it works. At CERN, the world’s largest and most complex scientific instruments are used to study the basic constituents of matter — the fundamental particles. By studying what happens when these particles collide, physicists learn about the laws of Nature.

The instruments used at CERN are particle accelerators and detectors. Accelerators boost beams of particles to high energies before they are made to collide with each other or with stationary targets. Detectors observe and record the results of these collisions.

Founded in 1954, the CERN Laboratory sits astride the Franco–Swiss border near Geneva. It was one of Europe’s first joint ventures and now has 22 Member States.

Related links:

Large Hadron Collider (LHC): https://home.cern/topics/large-hadron-collider

For more information about European Organization for Nuclear Research (CERN), Visit: https://home.cern/

Image (mentioned), Video (mentioned), Text, Credits: CERN/Achintya Rao.

Greetings, Orbiter.ch

vendredi 9 mars 2018

Webb Telescope to Make a Splash in Search for Interstellar Water

NASA - James Webb Space Telescope patch.

March 9, 2018

Water is crucial for life, but how do you make water? Cooking up some H₂O takes more than mixing hydrogen and oxygen. It requires the special conditions found deep within frigid molecular clouds, where dust shields against destructive ultraviolet light and aids chemical reactions. NASA’s James Webb Space Telescope will peer into these cosmic reservoirs to gain new insights into the origin and evolution of water and other key building blocks for habitable planets.

A molecular cloud is an interstellar cloud of dust, gas, and a variety of molecules ranging from molecular hydrogen (H₂) to complex, carbon-containing organics. Molecular clouds hold most of the water in the universe, and serve as nurseries for newborn stars and their planets.

Animation above: In this animation we fly into a protoplanetary disk surrounding a young star. Within the disk, tiny dust grains accumulate layers of ice over thousands of years. These cosmic snowflakes are swept up by forming planets, delivering key ingredients for life. Animation Credits: NASA/JPL-Caltech/R. Hurt.

Within these clouds, on the surfaces of tiny dust grains, hydrogen atoms link with oxygen to form water. Carbon joins with hydrogen to make methane. Nitrogen bonds with hydrogen to create ammonia. All of these molecules stick to the surface of dust specks, accumulating icy layers over millions of years. The result is a vast collection of “snowflakes” that are swept up by infant planets, delivering materials needed for life as we know it. "If we can understand the chemical complexity of these ices in the molecular cloud, and how they evolve during the formation of a star and its planets, then we can assess whether the building blocks of life should exist in every star system," said Melissa McClure of the Universiteit van Amsterdam, the principal investigator on a research project to investigate cosmic ices.

In order to understand these processes, one of Webb’s Director’s Discretionary Early Release Science projects will examine a nearby star-forming region to determine which ices are present where. “We plan to use a variety of Webb’s instrument modes and capabilities, not only to investigate this one region, but also to learn how best to study cosmic ices with Webb,” said Klaus Pontoppidan of the Space Telescope Science Institute (STScI), an investigator on McClure’s project. This project will take advantage of Webb’s high-resolution spectrographs to get the most sensitive and precise observations at wavelengths that specifically measure ices. Webb’s spectrographs, NIRSpec and MIRI, will provide up to five times better precision that any previous space telescope at near- and mid-infrared wavelengths.

Infant stars and comet cradles

The team, led by McClure and co-principal investigators Adwin Boogert (University of Hawaii) and Harold Linnartz (Universiteit Leiden), plans to target the Chamaeleon Complex, a star-forming region visible in the southern sky. It’s located about 500 light-years from Earth and contains several hundred protostars, the oldest of which are about 1 million years old. “This region has a bit of everything we’re looking for,” said Pontoppidan.

The team will use Webb’s sensitive infrared detectors to observe stars behind the molecular cloud. As light from those faint, background stars passes through the cloud, ices in the cloud will absorb some of the light. By observing many background stars spread across the sky, astronomers can map ices within the cloud’s entire expanse and locate where different ices form. They will also target individual protostars within the cloud itself to learn how ultraviolet light from these nascent stars promotes the creation of more complex molecules.

Image above: Blue light from a newborn star lights up the reflection nebula IC 2631. This nebula is part of the Chamaeleon star-forming region, which Webb will study to learn more about the formation of water and other cosmic ices. Image Credit: European Southern Observatory (ESO).

Astronomers also will examine the birthplaces of planets, rotating disks of gas and dust known as protoplanetary disks that surround newly formed stars. They will be able to measure the amounts and relative abundances of ices as close as 5 billion miles from the infant star, which is about the orbital distance of Pluto in our solar system.

“Comets have been described as dusty snowballs. At least some of the water in Earth’s oceans likely was delivered by the impacts of comets early in our solar system’s history. We’ll be looking at the places where comets form around other stars,” explained Pontoppidan.

Laboratory experiments

In order to understand Webb’s observations, scientists will need to conduct experiments on Earth. Webb’s spectrographs will spread incoming infrared light into a rainbow spectrum. Different molecules absorb light at certain wavelengths, or colors, resulting in dark spectral lines. Laboratories can measure a variety of substances to create a database of molecular “fingerprints.” When astronomers see those fingerprints in a spectrum from Webb, they can then identify the molecule or family of molecules that created the absorption lines.

“Laboratory studies will help address two key questions. The first is what molecules are present. But just as important, we’ll look at how the ices got there. How did they form? What we find with Webb will help inform our models and allow us to understand the mechanisms for ice formation at very low temperatures,” explained Karin Öberg of the Harvard-Smithsonian Center for Astrophysics, an investigator on the project.

Image above: This simulated spectrum from the Webb telescope illustrates the kinds of molecules that may be detected in star-forming regions like the Eagle Nebula (background). Image Credits: NASA, ESA, the Hubble Heritage Team, and M. McClure (Universiteit van Amsterdam) and A. Boogert (University of Hawaii).

“It will take years to fully mine the data that comes out of Webb,” Öberg added.

The James Webb Space Telescope will be the world’s premier infrared space observatory of the next decade. Webb will help humanity solve the mysteries of our solar system, look beyond to distant worlds around other stars, and probe the mysterious structures and origins of our universe and our place in it. Webb is an international project led by NASA with its partners, ESA (European Space Agency) and CSA (Canadian Space Agency).

For more information about Webb, visit http://www.nasa.gov/webb or http://www.webbtelescope.org/

Related link:

Webb’s Director’s Discretionary Early Release Science projects: https://jwst.stsci.edu/news-events/news/News%2520items/selections-made-for-the-jwst-directors-discretionary-early-release-science-program

Images (mentioned), Animation (mentioned), Text, Credits: NASA/Lynn Jenner/Space Telescope Science Institute, by Christine Pulliam.

Greetings, Orbiter.ch

3 NASA & ESA Satellites Recreate Solar Eruption in 3-D

NASA & ESA - SOHO Mission patch / NASA - STEREO Mission logo.

March 9, 2018

Image above: Using data from three different satellites, scientists have developed new models that recreate, in 3-D, CMEs and shocks, separately. Image Credits: NASA’s Goddard Space Flight Center/GMU/APL/Joy Ng.

The more solar observatories, the merrier: Scientists have developed new models to see how shocks associated with coronal mass ejections, or CMEs, propagate from the Sun — an effort made possible only by combining data from three NASA satellites to produce a much more robust mapping of a CME than any one could do alone.

Much the way ships form bow waves as they move through water, CMEs set off interplanetary shocks when they erupt from the Sun at extreme speeds, propelling a wave of high-energy particles. These particles can spark space weather events around Earth, endangering spacecraft and astronauts.

Understanding a shock’s structure — particularly how it develops and accelerates — is key to predicting how it might disrupt near-Earth space. But without a vast array of sensors scattered through space, these things are impossible to measure directly. Instead, scientists rely upon models that use satellite observations of the CME to simulate the ensuing shock’s behavior.

3 NASA Satellites Recreate Solar Eruption in 3-D

Video above: Using data from three different satellites, scientists have developed new models that recreate, in 3-D, CMEs and shocks, separately. This movie illustrates the recreation of a CME and shock that erupted from the Sun on March 7, 2011. The pink lines show the CME structure and the yellow lines show the structure of the shock - a side effect of the CME that can spark space weather events around Earth. Video Credits: NASA’s Goddard Space Flight Center/GMU/APL/Joy Ng.

The scientists — Ryun-Young Kwon, a solar physicist at George Mason University in Fairfax, Virginia, and Johns Hopkins University Applied Physics Laboratory, or APL, in Laurel, Maryland, and APL astrophysicist Angelos Vourlidas — pulled observations of two different eruptions from three spacecraft: ESA/NASA’s Solar and Heliospheric Observatory, or SOHO, and NASA’s twin Solar Terrestrial Relations Observatory, or STEREO, satellites. One CME erupted in March 2011 and the second, in February 2014.

NASA’s twin Solar Terrestrial Relations Observatory, or STEREO. Image Ctedit: NASA

The scientists fit the CME data to their models — one called the “croissant” model for the shape of nascent shocks, and the other the “ellipsoid” model for the shape of expanding shocks — to uncover the 3-D structure and trajectory of each CME and shock.

Each spacecraft’s observations alone weren’t sufficient to model the shocks. But with three sets of eyes on the eruption, each of them spaced nearly evenly around the Sun, the scientists could use their models to recreate a 3-D view. Their work confirmed long-held theoretical predictions of a strong shock near the CME nose and a weaker shock at the sides.

ESA/NASA’s Solar and Heliospheric Observatory, or SOHO. Image Credits: ESA/NASA

In time, shocks travel away from the Sun, and thanks to the 3-D information, the scientists could reconstruct their journey through space. The modeling helps scientists deduce important pieces of information for space weather forecasting — in this case, for the first time, the density of the plasma around the shock, in addition to the speed and strength of the energized particles. All of these factors are key to assessing the danger CMEs present to astronauts and spacecraft. Their results are summarized in a paper published in the Journal of Space Weather and Space Climate published on Feb. 13, 2018.

Related:

Space Weather Model Helps Simulate Magnetic Structure of Solar Storms: https://www.nasa.gov/feature/goddard/2017/new-space-weather-model-helps-simulate-magnetic-structure-of-solar-storms

NASA's STEREO Spacecraft Reveals the Anatomy of Solar Storm: https://www.nasa.gov/mission_pages/stereo/news/solarstorm3D.html

Journal of Space Weather and Space Climate: https://www.swsc-journal.org/articles/swsc/abs/2018/01/swsc170031/swsc170031.html

NASA’s twin Solar Terrestrial Relations Observatory, or STEREO: http://nasa.gov/stereo

ESA/NASA’s Solar and Heliospheric Observatory, or SOHO: http://nasa.gov/soho

Images (mentioned), Video (NASA), Text, Credits: NASA/Rob Garner/Goddard Space Flight Center, by Lina Tran.

Best regards, Orbiter.ch