Monday, August 31, 2020

Scientists reveal complete physical scenario of sympathetic eruption of two solar filaments

AUGUST 31, 2020, by Li Yuan, Chinese Academy of Sciences
https://phys.org/news/2020-08-scientists-reveal-physical-scenario-sympathetic.html

Fig. 1 Overview of the sympathetic eruptions of two filaments and subsequent flares and CMEs. 
Credit: HOU Yijun

Solar filaments are large magnetic structures confining cool and dense plasma suspended in the hot and tenuous corona.

The sun ubiquitously breeds sympathetic eruptions, which are defined as causally linked eruptions occurring with a relatively short time interval in different, but physically related source regions.

Recent observational and numerical works suggest that the physical linkages between the sympathetic eruptions should essentially be of a magnetic nature. However, the exact physical mechanism of the sympathetic eruptions of two filaments is still not well understood.

Recently, Dr. Hou Yijun from the National Astronomical Observatories of the Chinese Academy of Sciences (NAOC) and his collaborators studied a sympathetic event involving successive eruptions of two filaments (F1 and F2) and revealed a complete physical scenario of the sympathetic eruption.

Relevant results were published in Astronomy & Astrophysics and the Astrophysical Journal, respectively.

The researchers proposed an integrated evidence chain to demonstrate the critical roles of external magnetic reconnection and the resultant reconfiguration of overlying fields on the sympathetic eruptions of two filaments.

Fig. 2 Three-dimensional (3D) magnetic fields above F1 and F2 revealed by NLFFF extrapolation before the eruption. Credit: HOU Yijun

"Our observations show that after F1 first erupted due to the magnetic flux cancelation, an inward-spreading brightening and a dimming region were observed to the south of stable F2. The fields above pre-eruption F1 and F2 constituted a quadrupolar magnetic system with a possible null point, and the null point kept moving toward F2 and descending," said Dr. Hou Yijun.

These results indicated that the rising F1 pushed its overlying fields toward the fields above stable F2 and caused successive external reconnection between the overlying fields. From outside to inside (lower and lower in height), the fields above pre-eruption F2 were gradually involved in the reconnection, manifesting as the inward-spreading brightening and extending dimming on the south side of F2.

"Furthermore, the external reconnection could reconfigure the overlying fields of F2 by transporting magnetic flux from its west part to the east part, which is further verified by the subsequent partial eruption of F2," he said.

The coupling among multiple spatio-temporal solar activities is a basic problem in solar physics, which is closely related to the magnetic field of solar atmosphere and various solar eruptions.

The findings in these two papers further complement the study of sympathetic eruptions of two solar filaments, as well as the relation between filament eruptions and large-scale coronal fields, helping us forecast disastrous space weather.


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SPACE - S0 - 20200831 - Solar Eruption, Earth Discharges, Geoelectric Pathways

SPACE - S0 - 20200831 - Solar Eruption, Earth Discharges, Geoelectric Pathways

Good Morning, 0bservers!

   
    
Solar winds had calmed yesterday morning but they spiked up later to around 500 KPS, and stayed in the 440-500 KPS range before ramping up to about 540 KPS just after 0300, then spiking above 600 KPS for the first time in a while two hours later. Temps and particle density remained relatively steady. The jump may have been due to a combination of a coronal surge plus a shift in solar magnetic polarity, putting us into a solar storm situation. The KP-Index jumped to KP-4 (minor storm) after midnight, and then up a notch to KP-5. Watch for minor tech and health risks from this. A spike in the GOES Magnetometer seems to confirm this. Yesterday's Electron Flux, which had stayed under the SWPC Threshold, definitely jumped over it for most of the day, but it's back down below it (but only just). On the videos, we saw a strong kick-out from the Northern bright spots, which may also have contributed to the current storm. These were most visible at 193Å and 304Å. The lithosphere was a bit busier, with a Mag 5.0 off New Zealand, a 5.1 in the Philippines, a sharp Mag 6.5 along the Mid-Atlantic Ridge (about midway between the "hump" of South America and the "hump" of Africa), a Mag 5.0 off Vanuatu, and a Mag 5.0 in Iran.
  
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Sunday, August 30, 2020

UAE And Israel Plan To Create Intelligence Bases On Yemen’s Socotra Island

by Tyler Durden, Sat, 08/29/2020  By South Front,
https://www.zerohedge.com/markets/uae-and-israel-plan-create-intelligence-bases-yemens-socotra-island

screen cap of vid in article, CC

Israel and the United Arab Emirates are going to create a military intelligence-gathering infrastructure on Yemen’s Socotra Island, according to Arab and French sources.

The 3,650km^2 island, located south of the Yemeni mainland in the Indian Ocean, overlooks the Bab al-Mandab Strait. The straight is a sea route chokepoint between the Horn of Africa and the Middle East, connecting the Red Sea to the Gulf of Aden and Arabian Sea. Most exports of oil and natural gas from the Persian Gulf that transit the Suez Canal or the SUMED Pipeline pass through both the Bab el-Mandeb and the Strait of Hormuz.

Since the start of the Saudi-led intervention in Yemen, the UAE, formally a Saudi ally, and the UAE-backed Southern Transitional Council, a Yemeni separatist movement that is formally allied with the Saudi-backed government in Aden, have established control over most of Socotra Island. For years, the UAE has been seeking to annex the island due to its strategic location. The collapse of the Yemeni statehood due to the years-long instability and the foreign intervention paved a way for more direct actions. The creation of a military infrastructure there is a logical step in this strategy.

According to reports, a delegation of Israeli and UAE officers recently visited the island and examined several locations for establishing the planned intelligence facilities. Earlier in August, the UAE and Israel with assistance from the United States reached a historical peace agreement relaunching diplomatic, economic and even military cooperation between the states on the highest level. The security and military cooperation in the Bab al-Mandab Strait was among the expected goals.

Arab and Iranian media allege that in 2016 Israel started building an intelligence-gathering base at the top of Mount Ambassaira, south of the Eritrean capital of Asmara. The base, according to reports, is designed to monitor the conflict in Yemen, as well as the naval situation in the region, including movements of Iranian naval forces.

The UAE, thanks to its support to the Southern Transitional Council, has already changed the balance of power in southern Yemen to its favor. If, additionally to this, Abu Dhabi succeeds in turning the Socotra Island into its outpost, the UAE will have all chances to shift the balance of power to its own favor even further.

The Emirati leadership has been slowly but steadily taking an upper hand in the diplomatic, military and economic competition with the Saudi Kingdom, which has so far suffered most of negative consequences, including direct strikes on its territory, from the conflict with Yemen’s Houthis. The peace agreement and security, military cooperation with Israel will also contribute to this scenario.

The tactical UAE-Israeli-US alliance has all chances to compete with the expanding Iranian influence in the region. Saudi Arabia, which for years was the key US ally against Iran, has been left outside of this plan. And this is very bad news for the Kingdom, which is passing through a deep economic and political crisis complicated by the barely successful invasion of Yemen.


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SPACE - S0 - 20200830 - Spiral Aurora, Plasma Jets at Earth, Storm Watch

SPACE - S0 - 20200830 - Spiral Aurora, Plasma Jets at Earth, Storm Watch

Good Morning, 0bservers!

   
    
Solar wind speeds maxed out yesterday morning around 540 KPS, but started calming to 500 KPS by midnight and then did a sharper drop after that to around 440 KPS. Oddly enough, particle density went down a bit during Saturday, but then bumped up slightly when the wind speed started to drop more rapidly. Temperatures stayed steady to slightly elevated, again with the elevation after midnight around the same time as the particle density bump. That bump, however, was strong enough to put the KP-Index into the (minor) solar storm range, a KP-4. The rest of the day was mostly KP-3s and KP-2s. The Electron Flux, which had pretty low for the past several days, jumped around midday yesterday to just below the SWPC Alert Threshold. The Northern coronal hole is just now connecting to the polar hole as it passes the midpoint. Since we're nearing the Northernmost position in our orbit around the star, we're going to have more impact from those incoming streams than we normally would. The solar video at 304Å shows a lot of activity, including an ejection in the Northern hemisphere at the leading edge of one of the new bright spots. It caused some minor instability on the X-Ray Flux charts, but otherwise it seemed to be contained within the sun's atmosphere. Still don't see any underlying sunspots on the disc, though. Not too much in the way of earthquake activity, with only a handful of blot echos and a Mag. 5.1 in the South Shetland Islands.
  
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Still Report #3204 -- New Battery Only Needs Charging Every 1,000 Years

Still Report #3204 -- New Battery Only Needs Charging Every 1,000 Years

It is an interesting (if somewhat simplistic) video, but it explains a complex concept. And if it is real, or at least viable, it could be a game-changer in energy...


What do you think?
  
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Saturday, August 29, 2020

SPACE - S0 - 20200829 - First Solar Storm, Missions to Monitor the Sun

SPACE - S0 - 20200829 - First Solar Storm, Missions to Monitor the Sun

Good Morning, 0bservers!

   
    
The coronal hole streams from midweek have finally arrived at Earth, with a rise in plasma density preceding the jump in solar wind speeds. Midday saw the winds first increase to around 500 KPS, but after a brief lull it rose further to a high of 540 KPS. Current speeds are back in the 500-520 KPS range. Temps also rose about the same time as the particle density, but that has remained steady at that elevated level. That initial rise created a geomagnetic storm (the first of Cycle 25) all the way up to KP-5, but it immediately dropped back into the KP-2 to KP-3 range, with a KP-4 coming in just before this report. And we're seeing another coronal hole in the upper Norther latitudes passing the midpoint, and it will continue to present a hole toward us for the next 18 hours (unless the tail of the hole collapses). The X-Ray flux remained calm, and there were no visual eruptions from the various bright spot groups. The Solar Visual images, though, still show no actual underlying sunspots, but you can barely make out some lighter filaments on the surface that indicate some magnetic instability. In the shake 'n' quake zone, apparently New Zealand is suffering again from a crippling shortage of sheep's bladders as they suffer a Mag 5.5 about 70 miles North of Maketu. We also had a Mag 5.3 in one of new new favorite unknown places on the planet, the delightful archipelago of Alo, Wallis and Futana (sounds like a foreign law firm).
  
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Friday, August 28, 2020

SPACE - S0 - 20200828 - Plasma Universe, Are We in The Matrix?

SPACE - S0 - 20200828 - Plasma Universe, Are We in The Matrix?

Good Morning, 0bservers!

   
    
Solar winds remained relatively stable since yesterday's report, pretty much staying in the 400-430 KPS range until a jump to 450 KPS around 0600 Eastern. Particle density was on a slightly downward slope, but the temperature is a bit higher. We did have another KP-3 kick yesterday afternoon, but since then the KP-Index has dropped back to the KP-1 to KP-0 range. We had a sort of X-Ray "swelling" starting around noon UTC yesterday, sloping back to the bottom of the Class A range after rising to the middle of the chart. However, I couldn't see any surges, spikes or ejections from the solar surface videos. The coronal holes in the North are passed the midpoint now, and we're seeing a number of bright spots coming in from the lim. No underlying sunspots as yet, but the angle is still pretty steep for visuals close to the lim. The lithosphere didn't exactly wake up yesterday, more like rolled over under the covers and snorted. We had a Mag 5.4 in North Vanlaiphai India, a Mag 5.3 in the Easter Island "region" (found the quake, couldn't find the island), a Mag 5.0 in the D'Entrecasteaux Islands region (that Island I found), and a Mag 5.3 in the Bouvet Island region (again, found the quake, not the island).
  
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Hubble maps giant halo around Andromeda Galaxy

by Rob Garner, NASA's Goddard Space Flight Center
https://phys.org/news/2020-08-hubble-giant-halo-andromeda-galaxy.html

This illustration shows the location of the 43 quasars scientists used to probe Andromeda's gaseous halo. These quasars--the very distant, brilliant cores of active galaxies powered by black holes--are scattered far behind the halo, allowing scientists to probe multiple regions. Looking through the immense halo at the quasars' light, the team observed how this light is absorbed by the halo and how that absorption changes in different regions. By tracing the absorption of light coming from the background quasars, scientists are able to probe the halo's material. 
Credit: NASA, ESA, and E. Wheatley (STScI)

In a landmark study, scientists using NASA's Hubble Space Telescope have mapped the immense envelope of gas, called a halo, surrounding the Andromeda galaxy, our nearest large galactic neighbor. Scientists were surprised to find that this tenuous, nearly invisible halo of diffuse plasma extends 1.3 million light-years from the galaxy—about halfway to our Milky Way—and as far as 2 million light-years in some directions. This means that Andromeda's halo is already bumping into the halo of our own galaxy.

They also found that the halo has a layered structure, with two main nested and distinct shells of gas. This is the most comprehensive study of a halo surrounding a galaxy.

"Understanding the huge halos of gas surrounding galaxies is immensely important," explained co-investigator Samantha Berek of Yale University in New Haven, Connecticut. "This reservoir of gas contains fuel for future star formation within the galaxy, as well as outflows from events such as supernovae. It's full of clues regarding the past and future evolution of the galaxy, and we're finally able to study it in great detail in our closest galactic neighbor."

"We find the inner shell that extends to about a half million light-years is far more complex and dynamic," explained study leader Nicolas Lehner of the University of Notre Dame in Indiana. "The outer shell is smoother and hotter. This difference is a likely result from the impact of supernova activity in the galaxy's disk more directly affecting the inner halo."

A signature of this activity is the team's discovery of a large amount of heavy elements in the gaseous halo of Andromeda. Heavier elements are cooked up in the interiors of stars and then ejected into space—sometimes violently as a star dies. The halo is then contaminated with this material from stellar explosions.

The Andromeda galaxy, also known as M31, is a majestic spiral of perhaps as many as 1 trillion stars and comparable in size to our Milky Way. At a distance of 2.5 million light-years, it is so close to us that the galaxy appears as a cigar-shaped smudge of light high in the autumn sky. If its gaseous halo could be viewed with the naked eye, it would be about three times the width of the Big Dipper. This would easily be the biggest feature on the nighttime sky.

Through a program called Project AMIGA (Absorption Map of Ionized Gas in Andromeda), the study examined the light from 43 quasars—the very distant, brilliant cores of active galaxies powered by black holes—located far beyond Andromeda. The quasars are scattered behind the halo, allowing scientists to probe multiple regions. Looking through the halo at the quasars' light, the team observed how this light is absorbed by the Andromeda halo and how that absorption changes in different regions. The immense Andromeda halo is made of very rarified and ionized gas that doesn't emit radiation that is easily detectable. Therefore, tracing the absorption of light coming from a background source is a better way to probe this material.

This illustration depicts the gaseous halo of the Andromeda galaxy if it could be seen with the naked eye. At a distance of 2.5 million light-years, the majestic spiral Andromeda galaxy is so close to us that it appears as a cigar-shaped smudge of light high in the autumn sky. If its gaseous halo could be seen with the naked eye, it would be about three times the width of the Big Dipper—easily the biggest feature on the nighttime sky. 
Credit: NASA, ESA, J. DePasquale and E. Wheatley (STScI), and Z. Levay (background image)

The researchers used the unique capability of Hubble's Cosmic Origins Spectrograph (COS) to study the ultraviolet light from the quasars. Ultraviolet light is absorbed by Earth's atmosphere, which makes it impossible to observe with ground-based telescopes. The team used COS to detect ionized gas from carbon, silicon, and oxygen. An atom becomes ionized when radiation strips one or more electrons from it.

Andromeda's halo has been probed before by Lehner's team. In 2015, they discovered that the Andromeda halo is large and massive. But there was little hint of its complexity; now, it's mapped out in more detail, leading to its size and mass being far more accurately determined.

"Previously, there was very little information—only six quasars—within 1 million light-years of the galaxy. This new program provides much more information on this inner region of Andromeda's halo," explained co-investigator J. Christopher Howk, also of Notre Dame. "Probing gas within this radius is important, as it represents something of a gravitational sphere of influence for Andromeda."

Because we live inside the Milky Way, scientists cannot easily interpret the signature of our own galaxy's halo. However, they believe the halos of Andromeda and the Milky Way must be very similar since these two galaxies are quite similar. The two galaxies are on a collision course, and will merge to form a giant elliptical galaxy beginning about 4 billion years from now.

Scientists have studied gaseous halos of more distant galaxies, but those galaxies are much smaller on the sky, meaning the number of bright enough background quasars to probe their halo is usually only one per galaxy. Spatial information is therefore essentially lost. With its close proximity to Earth, the gaseous halo of Andromeda looms large on the sky, allowing for a far more extensive sampling.

"This is truly a unique experiment because only with Andromeda do we have information on its halo along not only one or two sightlines, but over 40," explained Lehner. "This is groundbreaking for capturing the complexity of a galaxy halo beyond our own Milky Way."

In fact, Andromeda is the only galaxy in the universe for which this experiment can be done now, and only with Hubble. Only with an ultraviolet-sensitive future space telescope will scientists be able to routinely undertake this type of experiment beyond the approximately 30 galaxies comprising the Local Group.

"So Project AMIGA has also given us a glimpse of the future," said Lehner.

The team's findings appear in the Aug. 27 edition of The Astrophysical Journal.


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Gas reaches young stars along magnetic field lines

AUGUST 27, 2020, by Max Planck Society
https://phys.org/news/2020-08-gas-young-stars-magnetic-field.html

Artistic impression of the hot gas streams that help young stars grow. Magnetic fields guide matter from the surrounding circumstellar disk, the birthplace of the planets, to the surface of the star, where they produce intense bursts of radiation.
 Credit: A. Mark Garlick

Astronomers have used the GRAVITY instrument to study the immediate vicinity of a young star in more detail than ever before. Their observations confirm a thirty-year-old theory about the growth of young stars: the magnetic field produced by the star itself directs material from a surrounding accretion disk of gas and dust onto its surface. The results, published today in the journal Nature, help astronomers to better understand how stars like our Sun are formed and how Earth-like planets are produced from the disks surrounding these stellar babies.

When stars form, they start out comparatively small and are located deep inside a cloud of gas. Over the course of the next hundreds of thousands of years, they draw more and more of the surrounding gas onto themselves, increasing their mass in the process. Using the GRAVITY instrument, a group of researchers that includes astronomers and engineers from the Max Planck Institute for Astronomy (MPIA), has now found the most direct evidence yet for how that gas is funnelled onto young stars: it is guided by the star's magnetic field onto the surface in a narrow column.

The relevant length scales are so small that even with the best telescopes currently available no detailed images of the process are possible. Still, using the latest observation technology, astronomers can at least glean some information. For the new study, the researchers made use of the superbly high resolving power of the instrument called GRAVITY. It combines four 8-meter VLT telescopes of the European Southern Observatory (ESO) at Paranal observatory in Chile into a virtual telescope that can distinguish small details as well as a telescope with a 100-meter-mirror could.

Using GRAVITY, the researchers were able to observe the inner part of the gas disk surrounding the star TW Hydrae. "This star is special because it is very close to Earth at only 196 light years away, and the disk of matter surrounding the star is directly facing us," says Rebeca García López (Max Planck Institute for Astronomy, Dublin Institute for Advanced Studies and University College Dublin), main author and leading scientist of this study. "This makes it an ideal candidate to probe how matter from a planet forming disk is channelled on to the stellar surface."

The observation allowed the astronomers to show that near-infrared radiation emitted by the entire system indeed originates in the innermost region, where hydrogen gas is falling onto the star's surface. The results point clearly towards a process known as magnetospheric accretion, that is, infalling matter guided by the star's magnetic field.

Stellar birth and stellar growth

A star is born when a dense region within a cloud of molecular gas collapses under its own gravity, becomes considerably denser, heats up in the process, until eventually density and temperature in the resulting protostar are so high that nuclear fusion of hydrogen to helium starts. For protostars up to about two times the mass of the Sun, the ten or so million years directly before the ignition of proton-proton nuclear fusion constitute the so-called T Tauri phase (named after the first observed star of this kind, T Tauri in the constellation Taurus).

Stars that we see in that phase of their development, known as T Tauri stars, shine quite brightly, in particular in infrared light. These so-called "young stellar objects" (YSOs) have not yet reached their final mass: they are surrounded by the remnants of the cloud from which they were born, in particular by gas that has contracted into a circumstellar disk surrounding the star. In the outer regions of that disk, dust and gas clump together and form ever-larger bodies, which will eventually become planets. Large amounts of gas and dust from the inner disk region, on the other hand, are drawn onto the star, increasing its mass. Last but not least, the star's intense radiation drives out a considerable portion of the gas as a stellar wind.

Guidelines to the surface: the star's magnetic field

Naively, one might think that transporting gas or dust onto a massive, gravitating body is easy. Instead, it turns out to be not that simple at all. Due to what physicists call the conservation of angular momentum, it is much more natural for any object—whether planet or gas cloud—to orbit a mass than to drop straight onto its surface. One reason why some matter nonetheless manages to reach the surface is a so-called accretion disk, in which gas orbits the central mass. There is plenty of internal friction inside that continually allows some of the gas to transfer its angular momentum to other portions of gas and move further inward. Yet, at a distance from the star of less than 10 times the stellar radius, the accretion process gets more complex. Traversing that last distance is tricky.

Thirty years ago, Max Camenzind, at the Landessternwarte Königstuhl (which has since become a part of the University of Heidelberg), proposed a solution to this problem. Stars typically have magnetic fields—those of our Sun, for instance, regularly accelerate electrically charged particles in our direction, leading to the phenomenon of Northern or Southern lights. In what has become known as magnetospheric accretion, the magnetic fields of the young stellar object guide gas from the inner rim of the circumstellar disk to the surface in distinct column-like flows, helping them to shed angular momentum in a way that allows the gas to flow onto the star.

In the simplest scenario, the magnetic field looks similar to that of the Earth. Gas from the inner rim of the disk would be funneled to the magnetic North and to the magnetic South pole of the star.

Checking up on magnetospheric accretion

Having a model that explains certain physical processes is one thing. However, it is important to be able to test that model using observations. But the length scales in question are of the order of stellar radii, very small on astronomical scales. Until recently, such length scales were too small, even around the nearest young stars, for astronomers to be able to take a picture showing all relevant details.

Schematic representation of the process of magnetospheric accretion of material onto a young star. Magnetic fields produced by the young star carry gas through flow channels from the disk to the polar regions of the star. The ionized hydrogen gas emits intense infrared radiation. When the gas hits the star's surface, shocks occur that give rise to the star's high brightness.
 Credit: MPIA graphics department

First indication that magnetospheric accretion is indeed present came from examining the spectra of some T Tauri stars. Spectra of gas clouds contain information about the motion of the gas. For some T Tauri stars, spectra revealed disk material falling onto the stellar surface with velocities as high as several hundred kilometers per second, providing indirect evidence for the presence of accretion flows along magnetic field lines. In a few cases, the strength of the magnetic field close to a T Tauri star could be directly measured by a combining high-resolution spectra and polarimetry, which records the orientation of the electromagnetic waves we receive from an object.

More recently, instruments have become sufficiently advanced—more specifically: have reached sufficiently high resolution, a sufficiently good capability to discern small details—so as to allow direct observations that provide insights into magnetospheric accretion.

The instrument GRAVITY plays a key role here. It was developed by a consortium that includes the Max Planck Institute for Astronomy, led by the Max Planck Institute for Extraterrestrial Physics. In operation since 2016, GRAVITY links the four 8-meter-telescopes of the VLT, located at the Paranal observatory of the European Southern Observatory (ESO). The instrument uses a special technique known as interferometry. The result is that GRAVITY can distinguish details so small as if the observations were made by a single telescope with a 100-m mirror.

Catching magnetic funnels in the act
In the Summer of 2019, a team of astronomers led by Jerome Bouvier of the University of Grenobles Alpes used GRAVITY to probe the inner regions of the T Tauri Star with the designation DoAr 44. It denotes the 44th T Tauri star in a nearby star forming region in the constellation Ophiuchus, catalogued in the late 1950s by the Georgian astronomer Madona Dolidze and the Armenian astronomer Marat Arakelyan. The system in question emits considerable light at a wavelength that is characteristic for highly excited hydrogen. Energetic ultraviolet radiation from the star ionizes individual hydrogen atoms in the accretion disk orbiting the star.

The magnetic field then influences the electrically charged hydrogen nuclei (each a single proton). The details of the physical processes that heat the hydrogen gas as it moves along the accretion current towards the star are not yet understood. The observed greatly broadened spectral lines show that heating occurs.

For the GRAVITY observations, the angular resolution was sufficiently high to show that the light was not produced in the circumstellar disk, but closer to the star's surface. Moreover, the source of that particular light was shifted slightly relative to the centre of the star itself. Both properties are consistent with the light being emitted near one end of a magnetic funnel, where the infalling hydrogen gas collides with the surface of the star. Those results have been published in an article in the journal Astronomy & Astrophysics.

The new results, which have now been published in the journal Nature, go one step further. In this case, the GRAVITY observations targeted the T Tauri star TW Hydrae, a young star in the constellation Hydra. They are based on GRAVITY observations of the T Tauri star TW Hydrae, a young star in the constellation Hydra. It is probably the best-studied system of its kind.

Too small to be part of the disk

With those observations, Rebeca García López and her colleagues have pushed the boundaries even further inwards. GRAVITY could see the emissions corresponding to the line associated with highly excited hydrogen (Brackett-γ, Brγ) and demonstrate that they stem from a region no more than 3.5 times the radius of the star across (about 3 million km, or 8 times the distance the distance between the Earth and the Moon).

This is a significant difference. According to all physics-based models, the inner rim of a circumstellar disk cannot possibly be that close to the star. If the light originates from that region, it cannot be emitted from any section of the disk. At that distance, the light also cannot be due to a stellar wind blown away by the young stellar object—the only other realistic possibility. Taken together, what is left as a plausible explanation is the magnetospheric accretion model.
What's next?

In future observations, again using GRAVITY, the researchers will try to get data that allows them a more detailed reconstruction of physical processes close to the star. "By observing the location of the funnel's lower endpoint over time, we hope to pick up clues as to how distant the magnetic North and South poles are from the star's axis of rotation," explains Wolfgang Brandner, co-author and scientist at MPIA. If North and South Pole directly aligned with the rotation axis, their position over time would not change at all.

They also hope to pick up clues as to whether the star's magnetic field is really as simple as a North Pole–South Pole configuration. "Magnetic fields can be much more complicated and have additional poles," explains Thomas Henning, Director at MPIA. "The fields can also change over time, which is part of a presumed explanation for the brightness variations of T Tauri stars."

All in all, this is an example of how observational techniques can drive progress in astronomy. In this case, the new observational techniques embody in GRAVITY were able to confirm ideas about the growth of young stellar objects that were proposed as long as 30 years ago. And future observations are set to help us understand even better how baby stars are being fed.


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Thursday, August 27, 2020

SPACE - S0 - 20200827 - Cosmic Rays, Ice Age, Extinction Coming

SPACE - S0 - 20200827 - Cosmic Rays, Ice Age, Extinction Coming

Good Morning, 0bservers!

   
    
Looks like the solar winds are calming down from yesterdays peak of 480 KPS to this morning's low of 405 KPS. It's back up a bit now to 430 KPS, all in the "high-normal" range.  Particle density and temperature also moved downward. The KP-Index was up in the KP-2 range most of yesterday, but we did see a brief KP-3 just after midnight. X-Ray flux readings have stayed calm now for the last three days. Don't be lulled into thinking the sun's "quiet", though - check out the solar videos at 304Å and you'll see some beautiful prominences on both lims of the disc, but they don't seem to be nudging the detectors, so enjoy the show. The largest of the Northern coronal holes should be passing the midpoint later today, and we WILL feel the effects of these holes come the weekend. Those new bright spots have crossed the terminator, and while I don't see any sunspots underneath yet, there are hints of magnetic disturbance that could become sunspots. Eyes Open, folks. The lithosphere was surprisingly quiescent in the past 24 hours, though - no shallow quakes, and no blot echos above Mag 5.0. 
  
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Wednesday, August 26, 2020

Small quake clusters can't hide from AI

AUGUST 25, 2020, by Mike Williams, Rice University
https://phys.org/news/2020-08-small-quake-clusters-ai.html

A graph extracted by a novel Rice University algorithm shows waveforms from the cluster associated with precursors and aligned with respect to a reference waveform within the cluster. The data was from three seismograms collected over the course of the day before the Nuugaatsiaq landslide. 
Credit: Nature Communications

Researchers at Rice University's Brown School of Engineering are using data gathered before a deadly 2017 landslide in Greenland to show how deep learning may someday help predict seismic events like earthquakes and volcanic eruptions.

Seismic data collected before the massive landslide at a Greenland fjord shows the subtle signals of the impending event were there, but no human analyst could possibly have put the clues together in time to make a prediction. The resulting tsunami that devastated the village of Nuugaatsiaq killed four people and injured nine and washed 11 buildings into the sea.

A study lead by former Rice visiting scholar Léonard Seydoux, now an assistant professor at the University of Grenoble-Alpes, employs techniques developed by Rice engineers and co-authors Maarten de Hoop and Richard Baraniuk. Their open-access report in Nature Communications shows how deep learning methods can process the overwhelming amount of data provided by seismic tools fast enough to predict events.

De Hoop, who specializes in mathematical analysis of inverse problems and deep learning in connection with Rice's Department of Earth, Environmental and Planetary Sciences, said advances in artificial intelligence (AI) are well-suited to independently monitor large and growing amounts of seismic data. AI has the ability to identify clusters of events and detect background noise to make connections that human experts might not recognize due to biases in their models, not to mention sheer volume, he said.

Hours before the Nuugaatsiaq event, those small signals began to appear in data collected by a nearby seismic station. The researchers analyzed data from midnight on June 17, 2017, until one minute before the slide at 11:39 p.m. that released up to 51 million cubic meters of material.

The Rice algorithm revealed weak but repetitive rumblings—undetectable in raw seismic records—that began about nine hours before the event and accelerated over time, leading to the landslide.

"There was a precursor paper to this one by our co-author, Piero Poli at Grenoble, that studied the event without AI," de Hoop said. "They discovered something in the data they thought we should look at, and because the area is isolated from a lot of other noise and tectonic activity, it was the purest data we could work with to try our ideas."

An overview by the U.S. Geological Survey shows the location of the Nuugaatsiaq landslide (yellow star) relative to five broadband seismic stations (pink triangles) within 500 km of the landslide. Nuugaatsiaq (NUUG) was impacted by the resulting tsunami the reached a height of 300 feet at sea, though it was much lower before it reached the village. The inset shows the geometry of the fjords relative to the landslide and Nuugaatsiaq. Credit: USGS

De Hoop is continuing to test the algorithm to analyze volcanic activity in Costa Rica and is also involved with NASA's InSight lander, which delivered a seismic detector to the surface of Mars nearly two years ago.

Constant monitoring that delivers such warnings in real time will save lives, de Hoop said.

"People ask me if this study is significant—and yes, it is a major step forward—and then if we can predict earthquakes. We're not quite ready to do that, but this direction is, I think, one of the most promising at the moment."

When de Hoop joined Rice five years ago, he brought expertise in solving inverse problems that involve working backwards from data to find a cause. Baraniuk is a leading expert in machine learning and compressive sensing, which help extract useful data from sparse samples. Together, they're a formidable team.

"The most exciting thing about this work is not the current result, but the fact that the approach represents a new research direction for machine learning as applied to geophysics," Baraniuk said.

"I come from the mathematics of deep learning and Rich comes from signal processing, which are at opposite ends of the discipline," de Hoop said. "But here we meet in the middle. And now we have a tremendous opportunity for Rice to build upon its expertise as a hub for seismologists to gather and put these pieces together. There's just so much data now that it's becoming impossible to handle any other way."

De Hoop is helping to grow Rice's reputation for seismic expertise with the Simons Foundation Math+X Symposia, which have already featured events on space exploration and mitigating natural hazards like volcanoes and earthquakes. A third event, dates to be announced, will study deep learning applications for solar giants and exoplanets.


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SPACE - S0 - 20200826 - Past Micronova, New Impact Zone, Radio Galaxy

SPACE - S0 - 20200826 - Past Micronova, New Impact Zone, Radio Galaxy

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We had a pretty sharp uptick in solar wind speeds after midnight, with a jump of around 100 KPS in the span of two hours to around 450 KPS. This was preceded by a brief rise, then drop, in particle density. Temperature also moved up along with the speed. This has increased the KP-Index readings to KP-2 levels after midnight after a full day of KP-1 readings. The Northern coronal holes are passing the midpoint right now, and a few developed and disappeared along or South of the equator. X-Ray flux readings remain at the bottom of the charts, and the various solar videos under different wavelengths showed no eruptions or spikes. There's a very strong glow at the Eastern lim in the North, so we've definitely got incoming bright spots. There was a Mag 5.5 off Papua New Guinea followed by a Mag 6.0 only five minutes later and a Mag 5.1 aftershock an hour after that, and a Mag 5.1 about 80 miles off Labuan Indonesia. Now, there was one notable blot echo yesterday as well, not because of the magnitude, but because of the location name. A Mag 4.6 blot echo about 250 miles deep, just under 100 miles from Alo, Wallis and Futuna. Yup, that's apparently a real place, folks...
  
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Tuesday, August 25, 2020

Earth Appears to Be Travelling Through The Debris of Ancient Supernovae

MICHELLE STARR,  24 AUGUST 2020
https://www.sciencealert.com/earth-might-be-moving-through-the-debris-of-ancient-supernovae

Added by CC

Radioactive dust deep beneath the ocean waves suggest that Earth is moving through a massive cloud left behind by an exploded star.

Continuously, for the last 33,000 years, space has been seeding Earth with a rare isotope of iron forged in supernovae.

It's not the first time that the isotope, known as iron-60, has dusted our planet. But it does contribute to a growing body of evidence that such dusting is ongoing - that we are still moving through an interstellar cloud of dust that could have originated from a supernova millions of years ago.

Iron-60 has been the focus of several studies over the years. It has a half-life of 2.6 million years, which means it completely decays after 15 million years - so any samples found here on Earth must have been deposited from elsewhere, since there's no way any iron-60 could have survived from the formation of the planet 4.6 billion years ago.

And deposits have been found. Nuclear physicist Anton Wallner of the Australian National University previously dated seabed deposits back to 2.6 million and 6 million years ago, suggesting that debris from supernovae had rained down on our planet at these times.

But there's more recent evidence of this stardust - much more recent.

It's been found in the Antarctic snow; according to the evidence, it had to have fallen in the last 20 years.

And, a few years ago, scientists announced that iron-60 had been detected in the space around Earth, measured over a 17-year period by NASA's space-based Advanced Composition Explorer.

Now Wallner has found more of the stuff, in five samples of deep-sea sediments from two locations dating back to 33,000 years ago. And the amounts of iron-60 in the samples are pretty consistent over the entire time period. But this finding actually poses more questions than it answers.

Earth, you see, is currently moving through a region called the Local Interstellar Cloud, made up of gas, dust and plasma.

If this cloud was created by exploding stars, then it's reasonable to expect that it's dusting Earth with a very faint rain of iron-60. This is what the Antarctic detection suggested; and this is what Wallner and his team were seeking to validate by examining the ocean sediments.

But if the Local Interstellar Cloud is the source of the iron-60, there should have been a sharp increase when the Solar System entered the cloud - which, according to the team's data, is likely to have occurred within the last 33,000 years. At the very least, the oldest sample should have had significantly lower levels of iron-60, yet it did not.

It's possible, the researchers note in their paper, that the Local Interstellar Cloud and the supernova debris are coincident, rather than one structure, with the debris remaining in the interstellar medium from supernovae that took place millions of years ago. That would suggest that the Local Interstellar Cloud is not a faint supernova remnant.

"There are recent papers that suggest iron-60 trapped in dust particles might bounce around in the interstellar medium," Wallner said.

"So the iron-60 could originate from even older supernovae explosions, and what we measure is some kind of echo."

The best way to find out, the researchers note, is to look for more iron-60, covering the gap between 40,000 years ago and around a million years ago.

If the iron-60 abundance grows greater farther back in time, that would suggest ancient supernovae.

However, a greater abundance more recently would suggest that the Local Interstellar Cloud is the source of the iron-60.

The research has been published in the Proceedings of the National Academy of Sciences.


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SPACE - S0 - 20200825 - Micronova Star, Earthquake Watch, Electric Bridge

SPACE - S0 - 20200825 - Micronova Star, Earthquake Watch, Electric Bridge

Good Morning, 0bservers!

   
    
Looks like the coronal hole streams from the past 36 hours are starting to fade. After a peak of nearly 420 KPS yesterday, we're now down in the 340-360 KPS range. There was a rise in particle density starting just after midnight, but that appears to be driven by a Phi-Angle shift. It certainly isn't reflected in the KP-Index, which has fallen from yesterday's KP-3 peaks down to KP-1s and KP-0s. X-Ray Flux remains low, and there were no major surges or eruptions from the bright spots. About the only coronal holes seem to remain at the North pole, and they ain't small. Another busy day in the world of plate tectonics, with a Mag 5.0 in Burundi, a Mag 5.6 off Tonga, a deep Mag 6.0 (15 miles down) in Costa Rica, an even deeper Mag 5.2 (25 miles down) off Tonga, a Mag 5.5 in Peru, and a Mag 5.2 at the Owen Fracture Zone (had to look that one up on the maps, it's off the coast of Oman).
  
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Monday, August 24, 2020

SPACE - S0 - 20200824 - Volcano, Major Storms, The Science of Everything

SPACE - S0 - 20200824 - Volcano, Major Storms, The Science of Everything

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We saw the solar wind speeds continue to increase all through yesterday and overnight, peaking at 420 KPS before starting to calm around 0100 to a current speed of 380 KPS. Particle density and temperature are also going down. The Phi Angle has been mostly at "North" on the dial with some wiggles and jiggles as you usually find. As to the KP-Index, it is slowly starting to calm back to KP-1 levels, but we did get a brief KP-3 right before midnight. X-Ray Flux is stable and low, with readings at the bottom of the Class A range. The solar videos are showing some new coronal hole development near the North pole, some of them preceding the new bright spot just appearing on the Eastern lim at around the 60° position. The larger extension of the Northern polar hole has passed the midpoint. The lithosphere seemed to be in a game of catch-up after yesterday's report, with a Mag 5.1 about 150 miles SSW of Indonesia followed by a Mag 5.0 16 hours later, a Mag 5.0 roughly 30 miles Northwest of Vanuatu, a Mag 5.4 in the Kermadec Islands region, a Mag 5.0 in Tanzania, and a moderately deep Mag 5.5 blot echo (about 30 miles) off Papua New Guinea.
  
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Sunday, August 23, 2020

Dieppe Raid

Article by                  Alex Herd
Published Online         August 25, 2013
Last Edited                August 15, 2017
https://www.thecanadianencyclopedia.ca/en/article/dieppe-raid



Bodies of Canadian soldiers of the Calgary Regiment lie dead on the beach at Dieppe, France, following the disastrous Allied raid there on 19 August, 1942.
(Library and Archives Canada)

Testing Fortress Europe

By the summer of 1942, Canada had been at war with Germany for nearly three years, but its army had yet to see any action, except during the failed defence of Hong Kong. Thousands of fresh Canadian soldiers waiting in Britain were eager to get involved in the fight against Germany.

The British and Americans were fighting in North Africa, but the Soviet Union was pressuring the Allies to invade Nazi-occupied western Europe, to ease the burden on the Red Army struggling against Germany's invasion of Russia.

The Allies weren't yet ready for a full-scale assault on mainland Europe. Instead, Winston Churchill, the British Prime Minister, wanted to mount commando-style raids against occupied France as a way of harassing the enemy. Churchill and Royal Air Force commanders also believed that such raids, supported by Allied aircraft, would draw the Luftwaffe, the German air force, into battle — thus wearing down the Luftwaffe and drawing its planes and pilots away from the Russian front.

Louis Mountbatten, a senior British naval officer and relative of the Royal Family, had been appointed to advise British commanders on the relatively new military tactic of using co-ordinated naval, air and land forces in "combined operations" attacks. Mountbatten proposed a raid on the town of Dieppe — to probe German defences on the coast of France, and to test the Allies' ability to mount an amphibious assault, using combined forces, against Adolf Hitler's "Fortress Europe." The plan was to take Dieppe, hold a perimeter around the town, destroy the harbour facilities, and then withdraw by sea.

2nd Canadian Division

Lieutenant-General Harry Crerar and other senior Canadian army commanders endorsed the plan, and offered up troops for the raid. Not only were Canadian soldiers stationed in Britain itching for a taste of combat, but domestic opinion at home was eager to see the Canadian Army finally involved in the European war.

Launched across the English Channel from southern England, Operation Jubilee (as the raid was called) involved more than 6,000 soldiers — 4,963 of them Canadian, plus 1,075 British troops, 15 French nationals and hundreds of airmen and sailors from Canada, Britain and the United States.

The 2nd Canadian Infantry Division, led by Major-General J.H. Roberts, formed the bulk of the infantry assault force. As Roberts told his troops before the raid — "Don't worry men, it'll be a piece of cake," — a comment that would haunt him for years afterwards.


Infantrymen of The Queen's Own Cameron Highlanders of Canada boarding landing craft before the raid on Dieppe on 19 August, 1942.\r\n

Tragedy on the Beaches
In the early morning hours of 19 August, the Allies arrived off the French coast on a naval task force of 237 ships and landing craft. Although the shoreline of Dieppe itself is relatively flat, the town is bookended on both sides by high, chalky-white cliffs rising directly from the beaches. From these cliffs, heavy German guns and machine guns situated inside concrete bunkers guarded the port and its surrounding beaches.



Map of the Dieppe Raid
(courtesy Veterans Affairs Canada website)

The Canadians assaulted Dieppe at four designated sections. At Blue Beach, below the village of Puys (1.6 km east of Dieppe), troops of The Royal Regiment of Canada and The Black Watch (Royal Highland Regiment) of Canada arrived late in their bid to take out enemy artillery and machine. From the start the enemy pinned down the Canadians and shot them up until the raid was over.

On the other side of the town at Green Beach, by the village of Pourville (4 km west of Dieppe), the South Saskatchewan Regiment arrived on time and in the dark. Unfortunately, the part of the unit tasked with reaching a radar station and anti-aircraft guns to the east of Pourville landed on the west side of the River Scie, which ran through the village. These troops had to cross the river on Pourville's only bridge, which the Germans ferociously defended. Ultimately, both the South Saskatchewans and Cameron Highlanders of Canada were pushed back.

At Red and White Beaches directly in front of the main port, the Essex Scottish and Royal Hamilton Light Infantry (RHLI) regiments landed without their armoured support, the 14th Canadian Army Tank Regiment (the Calgary Tanks), which was late. The enemy, from higher ground and in the town's beachfront casino, hit these units hard. Some infantry managed to get off the beach and enter Dieppe, but the Canadians also failed to achieve their objectives here.

A painting by Canadian war artist Charles Comfort, of the Allied raid on Dieppe in 1942.






On a ship offshore, Maj.-Gen. Roberts, believing that more troops had made their way into Dieppe than was true, sent his reserve unit, the Fusiliers Mont-Royal, to take advantage. This regiment was also destroyed.

Meanwhile, the Calgary Tanks that did arrive onshore were restricted in their movement, many becoming bogged down by the shingle beach (consisting of large pebbles, known as chert). Some tanks made it into the town, but their guns were unable to destroy the enemy's concrete barriers that lay in their path. Those tanks that survived the assault provided covering fire for the force’s evacuation.


Wrecked Allied tanks and landing craft lie strewn across a beach at Dieppe, France, following the failed raid there in 1942.

High Costs
The raid was over by mid-day. In nine hours, 907 Canadian soldiers were killed, 2,460 were wounded, and 1,946 were taken prisoner. That's more prisoners than the Canadian Army would lose in 11 months of fighting during the Northwest Europe campaign of 1944-1945. Fewer than half the Canadians who departed for Dieppe made it back to England.


Allied soldiers taken prisoner by the Germans at Dieppe, France in 1942.
Dieppe Raid

The British lost 300 men killed, wounded and taken prisoner, and there were 550 Allied naval casualties.

In the air battle overhead, the Royal Canadian Air Force lost 13 planes and 10 pilots, out of 106 Allied aircraft and 81 airmen lost overall.

Only British commandos, assigned to subdue coast artillery batteries to the east and west of Dieppe, enjoyed some success. And for the Canadians, the day was not without heroism. Honorary Captain J.W. Foote of the RHLI, and Lieutenant-Colonel C.C.I. Merritt of the South Saskatchewans both received the Victoria Cross, the British Empire's highest award for military valour. Foote, a chaplain, helped care for wounded troops under fire. Merritt bravely led his men over the Pourville bridge and later commanded a rearguard that allowed some troops to escape. Both were taken prisoner.

German casualties were light, other than the 48 aircraft lost after the Luftwaffe was drawn into battle.


Canadian survivors of the Dieppe Raid, upon their return to England on 19 August, 1942.

Critical Lessons

Allied commanders knew the raid was risky. But none imagined it would be such a terrible failure, with so much loss of life. The planners believed the element of surprise would allow landing troops to overcome German defenders and occupy the town, before withdrawing. Little thought was given to the importance of air superiority and the need for overwhelming firepower, including artillery support from naval warships. The assaulting infantry had only light destroyers firing at the Germans from offshore; no battleships or cruisers were made available for the raid, nor heavy bombers overhead.

Instead, strategists put their faith in the power of tanks. Tanks had spearheaded the German blitzkrieg across Europe in 1940. Two years later, tanks were seen as providing a crucial advantage in modern warfare. More than two dozen tanks would land on Dieppe's beaches beside the infantry, and this, planners said, would make all the difference. However, of the 29 tanks that attempted to land, only 15 made it off the beaches and reached the town's promenade. Their guns were not powerful enough to knock out German fortifications.

Said Second World War historian Terry Copp: "Army planners were still mesmerized by the vision of tanks as the decisive weapon of war, and surprise as a substitute for overwhelming firepower."

Despite its failure, the raid provided valuable lessons for the Allies. It erased the idea that surprise and tanks were enough to succeed in an amphibious assault against occupied France. Two years later, the D-Day landings would be backed up by massive naval artillery support, dominance over the skies, and heavy firepower — three essential factors missing at Dieppe.

Dieppe also made clear the difficulties of assaulting a well-defended port, as well as the need for better intelligence on beach conditions and German defences, better communication between infantry on the beach and commanders offshore, and the need for specialized landing craft and tanks able to overcome beach obstacles. These lessons would be implemented in later amphibious assaults in North Africa, Italy, and Normandy.

Memory
The sacrifices of Canadians at Dieppe are well remembered. Few Canadian military engagements have been as attentively researched and documented by historians.

Today, the town of Dieppe is filled with maple leaf flags and Canadian symbols, and its seafront promenade holds a park and several memorials to the regiments that came ashore in 1942. The Dieppe Canadian War Cemetery also holds the graves of 944 Allied servicemen and women, including 707 Canadians.

Perhaps the finest tribute to the men who fought and died at Dieppe is the official report on the battle in 1942 by the German army: "The enemy, almost entirely Canadian soldiers, fought — so far as he was able to fight at all —well and bravely.


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