Thursday, December 31, 2020

Defense News: Thai Army to procure additional M361 truck-mounted mortar systems

 

Thai Army to procure additional M361 truck-mounted mortar systems


So far, the army has purchased 22 of the mortars. The third order including 12 systems is expected to be delivered during 2021

By Eyal Boguslavsky, Israel Defense , 12/30/2020

A  previous test of the Thai military's M361 system. Photo: TAF


The Thai military says that it intends to purchase a third batch of M361 ATMM truck-mounted mortars, which are based on the Spear mortar system made by Israel's Elbit Systems. The military already purchased 10 of the mortars in 2019 and 12 more in 2020. The third order, including 12 systems, is expected to be delivered during 2021.


Here`s a clip of TATA 715 aka 2.5 ton with mounted @ElbitSystemsLtd 120mm mortar for Thai security forces also call Autonomous Truck Mounted Mortar. Kunwal Biwas, 20 Aug 2020

As reported by Israel Defense in late 2017, the Thai Ministry of Defense unveiled a new 120mm wheeled self-propelled mortar system called the Autonomous Truck Mounted Mortar (ATMM), developed in collaboration with Elbit Systems to provide fire support for infantry units. The ATMM, which is based on a 4x4 military truck chassis manufactured by India's TATA, is fitted with a new cargo platform with a thickness of 7mm that can carry Elbit's Spear 120mm mortar system. 


Thai Armed Forces ATMM  live firing. TAF photo 

The ATMM has a crew of four and can be ready to fire from road position in less than two minutes, with a maximum firing range of 6.5 km and a rate of fire of 10 rounds per minute.



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Novel public-private partnership facilitates development of fusion energy

DECEMBER 30, 2020, by Princeton Plasma Physics Laboratory
https://techxplore.com/news/2020-12-public-private-partnership-fusion-energy.html


PPPL physicist Gerrit Kramer with conceptual image of SPARC fusion reactor. 
Credit: Collage and Kramer photo by Elle Starkman/PPPL Office of Communications. SPARC image courtesy of Commonwealth Fusion Systems.




The U.S. Department of Energy's (DOE) Princeton Plasma Physics Laboratory (PPPL) is collaborating with private industry on cutting-edge fusion research aimed at achieving commercial fusion energy. This work, enabled through a public-private DOE grant program, supports efforts to develop high-performance fusion grade plasmas. In one such project PPPL is working in coordination with MIT's Plasma Science and Fusion Center (PSFC) and Commonwealth Fusion Systems, a start-up spun out of MIT that is developing a tokamak fusion device called "SPARC."

The goal of the project is to predict the leakage of fast "alpha" particles produced during the fusion reactions in SPARC, given the size and potential misalignments of the superconducting magnets that confine the plasma. These particles can create a largely self-heated or "burning plasma" that fuels fusion reactions. Development of burning plasma is a major scientific goal for fusion energy research. However, leakage of alpha particles could slow or halt the production of fusion energy and damage the interior of the SPARC facility.

New superconducting magnets

Key features of the SPARC machine include its compact size and powerful magnetic fields enabled by the ability of new superconducting magnets to operate at higher fields and stresses than existing superconducting magnets. These features will enable design and construction of smaller and less-expensive fusion facilities, as described in recent publications by the SPARC team—assuming that the fast alpha particles created in fusion reactions can be contained long enough to keep the plasma hot.

"Our research indicates that they can be," said PPPL physicist Gerrit Kramer, who participates in the project through the DOE Innovation Network for Fusion Energy (INFUSE) program. The two-year-old program, which PPPL physicist Ahmed Diallo serves as deputy director, aims to speed private-sector development of fusion energy through partnerships with national laboratories.

Well-confined

"We found that the alpha particles are indeed well confined in the SPARC design," said Kramer, coauthor of a paper in the Journal of Plasma Physics that reports the findings. He worked closely with the lead author Steven Scott, a consultant to Commonwealth Fusion Systems and former long-time physicist at PPPL.

Kramer used the SPIRAL computer code developed at PPPL to verify the particle confinement. "The code, which simulates the wavy pattern, or ripples, in a magnetic field that could allow the escape of fast particles, showed good confinement and lack of damage to the SPARC walls," Kramer said. Moreover, he added, "the SPIRAL code agreed well with the ASCOT code from Finland. While the two codes are completely different, the results were similar."

The findings gladdened Scott. "It's gratifying to see the computational validation of our understanding of ripple-induced losses," he said, "since I studied the issue experimentally back in the early 1980s for my doctoral dissertation."

Fusion reactions combine light elements in the form of plasma—the hot, charged state of matter composed of free electrons and atomic nuclei, or ions, that comprises 99 percent of the visible universe—to generate massive amounts of energy. Scientists around the world are seeking to create fusion as a virtually unlimited source of power for generating electricity.

Key guidance

Kramer and colleagues noted that misalignment of the SPARC magnets will increase the ripple-induced losses of fusion particles leading to increased power striking the walls. Their calculations should provide key guidance to the SPARC engineering team about how well the magnets must be aligned to avoid excessive power loss and wall damage. Properly aligned magnets will enable studies of plasma self-heating for the first time and development of improved techniques for plasma control in future fusion power plants.


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SPACE - S0 - 20201231 - Magnetic Flips - Quakes, Glass, Sediment

SPACE - S0 - 20201231 - Magnetic Flips - Quakes, Glass, Sediment

Don't Start Drinking Too Early, 0bservers!

   
    
Solar wind speeds went up in the mid to late morning topping out around 540 KPS, but it spent the rest of the day and night slowly calming back to the 410-430 KPS range. That should rise again by tomorrow with the arrival of a new coronal stream from the equatorial hole. Particle density lowered a bit yesterday evening, but rose back again around 0200 UTC before dropping again six hours later, with Temperature readings following suit. All nominal on the Proton/Electron/Magnetometer front. The X-Ray Flux background level has lowered further into the upper Class A flare range. We did see a couple of minor spikes in the afternoon and evening yesterday, but since then it's been pretty quiescent. The video loops showed the Northern coronal hole passing the midpoint, the Southern one is a couple days behind. The spikes on the chart appear to have come from the sunspot groups that already passed center disc, and they were little more than intra-atmospheric surges with a bit of sparking.

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Wednesday, December 30, 2020

Here's what we learned about aliens in 2020

By Brandon Specktor - Senior Writer Dec. 29, 2020
https://www.livescience.com/alien-clues-in-2020.html

An artist's illustration of the evolution of the interstellar object 'Oumuamua, whose weird, elongated shape may have come from tidal forces.
(Image: © YU Jingchuan from Beijing Planetarium)

In a year when mysterious monoliths literally appeared out of nowhere, you'd think the first real detection of alien life would be a stone's-throw away. Well, 2020 didn't bring any little green men, but it did bring astronomers closer to finding extraterrestrial life than ever before. From organic molecules turning up around the solar system to mysterious radio signals finally being traced back to their source, here are some of the biggest findings of the year about where aliens may be (and definitely aren't) hiding in the universe.

There could be alien life in the clouds of Venus


In September, Venus became the most popular planet on Earth when scientists discovered possible traces of the molecule phosphine in the planet's atmosphere. On Earth, phosphine (made from one phosphorous atom and three hydrogen atoms) is mostly associated with non-oxygen-breathing bacteria, as well as some human activities. The molecule is produced naturally by gas giants, but there's no good reason why it should be on the hot and hellish world of Venus, the researchers concluded — unless, perhaps, there is some sort of life breathing it into the planet's mysterious clouds?

… But it's not likely 


(Image credit: NASA)




Exciting as it was, the phosphine discovery was met with strong skepticism from the scientific community. For starters, it's not even clear that the researchers detected phosphine at all; their observations contained so much noise that something mimicking phosphine's chemical signature could have appeared by accident, John Carpenter, an observatory scientist at the Atacama telescope in Chile, previously told Live Science.

And even if the reading was accurate, phosphine could very easily be created totally randomly through a number of geological processes that don't involve life at all, said Lee Cronin, a chemist at the University of Glasgow in the United Kingdom. The processes that shape Venus' scorching surface and sky are largely a mystery, and one trace of an inexplicable molecule is, sadly, not enough to confirm alien life exists there. Significant study of the planet is required to solve this chemical conundrum.

There could be 36 alien civilizations sharing our galaxy

(Image credit: Angela Harburn/Shutterstock)

How many intelligent alien civilizations are lurking among the hundreds of billions of stars in the Milky Way? According to a study published June 15 in The Astrophysical Journal, the answer is 36.


How did the researchers arrive at that number? By taking a fresh stab at a decades-old alien-hunting riddle known as the Drake equation. Named for astronomer Frank Drake, who debuted the equation in 1961, the puzzle attempts to guess the likely number of alien civilizations in our galaxy based on variables like the average rate of star formation, the percentage of stars that form planets and the much-smaller percentage of planets that have the right stuff for life. Most of these variables are still unknown, but the authors of the new study tried to resolve them with the most up-to-date information on star formation and exoplanets available.

Their result? There are precisely 36 planets in the Milky Way that could host intelligence life similar to that on Earth. But even if the researchers nailed all those unknown variables, it'll still be a while before we meet one of our intelligence neighbors; assuming an even distribution of civilizations throughout the galaxy, the closest one is 17,000 light-years away from Earth.

And more than 1,000 alien stars could be watching us

(Image credit: NASA/NOAA)




Will they find us before we find them? We could find out in this lifetime. Two stars on the list host known exoplanets, one of which will have a direct line of sight to Earth in the year 2044.

But while we hunt for alien worlds, are aliens also hunting for us? That's the question that motivated an Oct. 20 study in the journal Monthly Notices of the Royal Astronomical Society, in which astronomers calculated the number of alien star systems that have a direct line of sight to Earth — and therefore could be watching us right now.

The team calculated that approximately 1,000 star systems within about 300 light-years of Earth could feasibly see our planet as it passes between their location and Earth's sun. Those sky-watching aliens would see our sun dim as Earth passes over it, just as humans have detected thousands of exoplanets by watching for suddenly-dimming stars in the night sky. What's more, if those alien astronomers have similar technology to ours, they could even detect traces of methane and oxygen in Earth's atmosphere, which would be potential signs of life, the researchers noted.

Aliens aren't responsible for FRBs (at least, not this one)

(Image credit: NASA/Goddard Space Flight Center Conceptual Image Lab)




Fast radio bursts (FRBs) are millisecond-long pulses of radio light that blast through space thousands of times a day. Until recently, nobody had any idea what they were. Could it be aliens, pulsing the jets on their hyper-speed spacecraft? The idea had crossed at least one astronomer's mind. But for better or worse, that idea may be dead after astronomers successfully traced an FRB to a known source in the Milky Way for the first time ever.

The source, it turns out, was a magnetar: the fast-spinning, highly magnetized corpse of a long-dead star. For thousands of years after their formation, these temperamental objects cycle through periods of violent activity, beaming powerful pulses of X-ray and gamma-ray radiation into the universe around them at seemingly random intervals. While astronomers were watching one such outburst, they also caught an FRB beaming out of the dead star. Perhaps not all FRBs in the universe come from magnetars (aliens, you're still on notice), but this discovery goes a long way toward solving a decade-old mystery of the cosmos.

White dwarfs may be alien strongholds

(Image credit: Shutterstock)





About 4 billion years from now, Earth's sun will swell into a red giant, then collapse into a small, smoldering white dwarf. This fate is inescapable, and the odds of humankind fleeing to another star system are near-impossible. Maybe, if we're still around at the time, we could find a way to harness the dim light of our dead star and keep on trucking as a civilization. And maybe, a paper published earlier this year to the preprint database arXiv suggests, other alien civilizations are already doing the same.

White dwarfs have been largely ignored in the search for extraterrestrial intelligence (SETI), the paper's authors claim, as a dead star is unlikely to host a thriving civilization. But white dwarfs do sometimes have planets in their orbit – and a highly advanced civilization might be able to make their tiny sun work for them, even after death. Astronomers therefore shouldn't cut white dwarfs out of their SETI equations, the authors write; in fact, maybe we should be looking to them first.

Aliens might not breathe oxygen


(Image credit: Shutterstock)




Another underrated target in the search for alien life: oxygen-free planets. While it has been long assumed that alien life needs air to breathe, a study published May 4 in the journal Nature Astronomy argues that maybe "air" and "oxygen" aren't always synonymous. Hydrogen and helium are far more common elements in our universe (Jupiter's atmosphere is 90% hydrogen, for example), so what if an alien species evolved to breathe that stuff instead?

It turns out, it may be possible. The study authors exposed a type of non-oxygen-breathing bacteria called E. coli to two different "atmospheres" fabricated inside some test tubes. One set of flasks was pure hydrogen, the other pure helium. They found that the bacteria were able to survive in both conditions, though their growth was stunted. This experiment "opens the possibility for a much broader spectrum of habitats for life on diverse habitable worlds," study author Sara Seager, a planetary scientist at MIT, wrote in the paper.

Aliens (probably) didn’t build 'Oumuamua

(Image credit: ZHANG Yun/background by ESO/M. Kornmesser)





The strange, cigar-shaped rock named 'Oumuamua has puzzled scientists since it was first spotted in our solar system in October 2017. The object was traveling too fast to have originated in our solar system, and seemed to be accelerating for no good reason. Some astronomers — particularly Harvard University astrophysicist Avi Loeb — said it could be an alien spacecraft, powered by a paper-thin sail. That theory met with ongoing skepticism this year, however, thanks to several studies that describe the object's potential natural origins.

One of the leading theories: 'Oumuamua is a "hydrogen iceberg" – essentially, a solid chunk of hydrogen gas that strayed away from its local star and into the icy heart of a giant molecular cloud. After leaving the core of the cloud, the berg was battered by radiation and molded into an elongated shape. Once it entered our solar system, hydrogen began boiling off of the icy rock, causing it to accelerate without leaving a visible trail of gas. It's a tantalizing theory that explains many of 'Oumuamua's quirks; still, Loeb believes aliens are the more likely explanation.

Four worlds hold the most promise

(Image credit: NASA/JPL-Caltech)





In our solar system, four worlds seem to have the right stuff for the possibility of life. The foremost is Mars — one of the most Earth-like worlds in our solar system. Earlier this year, a large lake was detected beneath the southern polar ice cap, giving new hope that tiny microbes could be present there (assuming they have something to eat).

The other three candidates are all moons: Jupiter's moon Europa, and Saturn's moons Enceladus and Titan. Like Mars, Europa hold the promise of water; its surface is a vast expanse of ice, which may conceal a gargantuan global ocean more than 60 miles (100 kilometers) deep. Enceladus, too, is an icy world that may holds liquid water deep beneath its surface. Recently, gargantuan geysers were spotted spraying water, grains of rocky particles and some organic molecules off of the moon and into space. Titan, meanwhile, is the only moon in our solar system with a substantial atmosphere, which is rich in nitrogen — an important building block of proteins in all known forms of life.

Alien hunting just got a little harder


(Image credit: University of Central Florida)




On Tuesday, Dec. 1, the Arecibo Observatory's iconic radio telescope in Puerto Rico finally collapsed, after hanging on by a literal thread for nearly five months (two mysterious cable-snapping incidents in August and November left the telescope in dire condition).

The tragic collapse ends Arecibo's 57-year legacy of searching the cosmos for signs of extraterrestrial life. In 1974, the telescope broadcast the now-famous "Arecibo Message," declaring the technical prowess of humanity to any intelligent extraterrestrials that might be listening. So far, there have been no answers – but that message to the stars inspired the 1997 film "Contact," in which the Arecibo telescope plays a starring role. The telescope's loss leaves a gap in SETI that won't easily be filled.


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SPACE - S0 - 20201230 - Magneto-Nuclear Sun, AGU Solar Climate Forcing

SPACE - S0 - 20201230 - Magneto-Nuclear Sun, AGU Solar Climate Forcing

Good Morning, 0bservers!

   


    
Solar winds are in the 470-530 KPS range right now, after a TEN HOUR OUTAGE on the satellite. The range now is pretty close to the range yesterday, but the calming shown around 2000 UTC was closer to the 450 KPS range, so there's been a slight increase. The KP-Index was mostly in the KP-1 region yesterday, but it popped up to KP-3 just before midnight UTC. Proton Flux, Electron Flux and Magnetometer readings are nominal. The X-Ray Flux had a pretty strong spike to nearly the top of the Class B flare range about 2100 UTC, and there have been a few lower level bumps since that point including two near the middle of Class B around 1000-1100 UTC. The Northern coronal hole is still reaching toward the pole as it approaches central heliographic longitude. We're also seeing a new coronal hole developing in the South ahead of a new bright spot system, much closer to the equator.

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Tuesday, December 29, 2020

Defense News: French Army orders new batch of 12,000 HK416F assault rifles

 

French Army orders new batch of 12,000 HK416F assault rifles


Over 45,000 of the rifles are in the process of being delivered, with 117,000 scheduled to be supplied by 2028

By  Eyal Boguslavsky, Defense News, 12/28/2020

HK416F - S (standard, 14.5” barrel/368 mm) 5.56mm   Photo: Armée de Terre

The French Army has ordered a new batch of 12,000 HK416F 5.56mm assault rifles to replace FAMAS 5.56 mm bullpup assault rifles that have been in use since 1972, according to a report by the Army Recognition website. 

HK416F - S (standard, 14.5” barrel/368 mm) 5.56mm Rifle 


In October 2016, the French Army confirmed the selection of the Heckler & Koch 416 5.56mm caliber to replace the old FAMAS. Currently, 45,340 HK416F assault rifles are in the process of delivery to the French Army by the DGA, the French Army procurement agency, with 117,000 scheduled to be supplied by 2028.
HK416 F-C (compact, 11” barrel/279 mm) 5.56mm Rifle .


The HK416F is based on the design of HK416A5 and can be used by left and right-handed shooters. The HK416F has a gas pressure loader system that is similar to the American-made AR-15 manufactured by Colt. 

HK416F - S (standard, 14.5” barrel/368 mm) 5.56mm Rifle fitted with the  HK269F (40 x 46 mm) grenade launcher


The weapon will be supplied to the French Army in two variants: the HK416 F-S (standard, 14.5” barrel/368 mm) and HK416 F-C (compact, 11” barrel/279 mm). It uses a magazine which has a capacity of 30 cartridges, the report said.

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Space News: Neptune’s mysterious dark spot has reversed course

 

Neptune’s mysterious dark spot has reversed course


By Chris Ciaccia, Fox News, December 28, 2020



A massive dark storm on Neptune that was first spotted two years ago has suddenly changed directions, leaving experts without answers.

The storm was discovered by the Hubble Space Telescope in 2018, where it was seen on the planet’s Northern Hemisphere. In 2019, it was seen moving toward the planet’s Southern Hemisphere, but in August 2020, it started moving back north again, unlike other dark spots that have been spotted on the ice giant in the past. Another smaller, dark spot was also seen, believed to be a part of the larger storm that broke off into a separate storm.

“We are excited about these observations because this smaller dark fragment is potentially part of the dark spot’s disruption process,” Michael H. Wong of the University of California at Berkeley said in a statement. “This is a process that’s never been observed. We have seen some other dark spots fading away and they’re gone, but we’ve never seen anything disrupt, even though it’s predicted in computer simulations.”

NASA first flew by Neptune in 1989 with the Voyager 2 spacecraft and took pictures of two dark spots. It wasn’t until 1994 that it was observed on a regular basis by the Hubble. Since then, the space telescope has looked at the “Great Dark Spot” as well as other dark spots on the planet.

The dark storm in question is believed to be 4,600 miles across and is the fourth observed on Neptune since 1993. Unlike hurricanes on Earth, which are low-pressure and spin counterclockwise, these storms rotate clockwise and are high-pressure systems. But as they move toward the equator, they’re impacted by the Coriolis effect, which weakens them, ultimately disintegrating after it reaches a so-called “kill zone.” This particular storm did not.

“It was really exciting to see this one act like it’s supposed to act and then all of a sudden it just stops and swings back,” Wong said. “That was surprising.”

Wang believed the smaller storm, albeit one that is 3,900 miles across, was the result of the larger storm being disrupted, but that isn’t the case, adding intrigue to what’s causing it.

“I didn’t think another vortex was forming because the small one is farther towards the equator,” the researcher explained. “So it’s within this unstable region. But we can’t prove the two are related. It remains a complete mystery.”

Neptune's 'dark spots' spied by Hubble, VideoFromSpace, 15 Dec 2020

New time-lapsed Hubble Space Telescope imagery of Neptune shows two giant dark spots on the planet. These vortices are "high-pressure systems that can form at mid-latitudes and may then migrate toward the equator," according to NASA and the Space Telescope Science Institute


Neptune is still relatively unexplored, as is Uranus, even with the Voyager 2 snapping photos of both planets in 1986 and 1989.

In August, researchers developed computer models that suggest both planets are composed “primarily” of a strange form of water.

In March 2019, scientists at NASA JPL proposed a mission that would explore Neptune’s largest moon, Triton, which some have theorized could have an ocean hidden beneath the surface.

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Japanese pairing looking into using wood to build satellites

DECEMBER 29, 2020 REPORT : by Bob Yirka , Tech Xplore
https://techxplore.com/news/2020-12-japanese-pairing-wood-satellites.html


Japanese company Sumitomo Forestry has announced a joint development project with Kyoto University to test the idea of using wood as a component in satellite construction. As part of the announcement, officials with Sumitomo Forestry told reporters that work on the project will begin with experiments designed to test different types of wood in extreme environments.

Some of the major components in most satellites include aluminum, Kevlar and aluminum alloys, which are able to withstand both temperature extremes and constant bombardment by radiation—all in a vacuum. Unfortunately, these characteristics also allow satellites to remain in orbit long after their usefulness has ended, resulting in constant additions to the space junk orbiting the planet.

 According to the World Economic Forum, there are currently approximately 6,000 satellites circling the Earth but only 60% of them are still in use. Some in the field have predicted that nearly 1,000 satellites will be launched into space each year over the coming decade. Considering their lifespan, this suggests there could be thousands more dead satellites orbiting the planet in the coming years. This space debris poses a significant threat to other satellites (they all travel thousands of miles per hour) and also to manned space missions. Most in the space community agree that space junk is becoming a serious problem. 

And there is more bad news—the aluminum used in satellites has been found to break apart when a satellite returns to Earth, creating hundreds or thousands of tiny alumina particles that wind up floating in the upper atmosphere for many years, possibly posing an environmental problem. For all these reasons, the researchers with this new project are looking to replace these materials with wood.

The major benefit of wood-based satellites is they would burn up completely when returning to Earth. But another major bonus of using wood to create the outer shell of a satellite is that electromagnetic waves would pass right through it, which means antennas could be placed inside of satellite structures, making them simpler to design and deploy. The researchers plan to look for appropriate wood candidates and then to conduct experiments to see it they could be treated to stand up to space conditions. They predict they will have a product ready for testing by 2023.



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SPACE - S0 - 20201229 - MAJOR Earthquake, Atmospheric Electricity, Super-Flare

SPACE - S0 - 20201229 - MAJOR Earthquake, Atmospheric Electricity, Super-Flare

Good Morning, 0bservers!

   
    
Looks like we had a couple more three-hour outages on the DSCOVR charts - can somebody fit the Maytag Repairman with a space suit to fix that damn thing, please? 
 
Solar wind speeds calmed a bit from yesterday's peak of 580 KPS, currently holding in the 470-510 KPS range. Temperature and Density are steady, and the KP-Index has been solidly in the green for a couple days now. We did get a KP-3 just after midnight UTC blowing away the cosmic rays, but it's back down to the KP-2 range now. Electron Flux readings are calming down, not reaching the threshold, while the Proton Flux has remained delightfully dull per usual. Magnetometer readings seem to have smoothed out a bit from yesterday's rapid drop. The X-Ray Flux continues its mostly-calm readings, with only the barest bumps in the last 24 into the lower quarter of Class B, and the background range back to high Class A. The second of the two major sunspot groups passed the midpoint without incident, and we're seeing leading glows along the Eastern lim indicating (I know, shock! horror!) more incoming groups. What's got me a bit fascinated/concerned is the new coronal hole in the upper Northern latitudes. It is growing, and a tendril appears to be growing upward to try to connect to the polar hole system. It's still at least a day or two from the midpoint, so it'll be interesting to see how this develops.

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Monday, December 28, 2020

SPACE - S0 - 20201228 - Big Filament, CAPE, Quakes, Binaries

SPACE - S0 - 20201228 - Big Filament, CAPE, Quakes, Binaries

Good Morning, 0bservers!

   
    
Solar wind speeds rose yesterday around midday UTC, with a spike to 550 KPS with the ambient speed in the 470-530 KPS range, but it kept a steady increase overnight to the 510-560 KPS range with a second spike near 580 KPS around 1030 UTC. This was the second coronal hole stream, as illustrated by the rise in Particle Density a couple hours beforehand. The Temperature track followed the wind speed in its upward climb. Electron Flux readings breached the warning threshold again, but the Proton Flux was steady as a rock. The Magnetometer readings, however, had a hell of a drop after hitting a high of 120 nanoTeslas, then a nearly 40 nT drop in the span of moments. The KP-Index looks pretty good, all green with KP-1s and KP-2s for the past 36 hours. The X-Ray Flux was mostly calm again, but we did have a spike into the mid-Class B flare range just before noon UTC. Another one snuck in around 1000 UTC today, but it only made it up to about a third of the way into Class B. Couldn't really see any major flare activity on the video loop, but there is a new coronal hole developing in the Northeast quadrant, so we'll see how that works itself out...
* * *
Another new video from Suspicious0bservers, "THE NEXT DISASTER | Part 2 - Applied Galactic Astrophysics"

Enjoy!

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The Cost of Visiting Earth May Be Too Astronomical For Aliens

MATT WILLIAMS, UNIVERSE TODAY, 27 DECEMBER 2020.
https://www.sciencealert.com/it-may-just-be-too-expensive-for-aliens-to-visit-earth

(Colin Anderson Productions pty ltd/DigitalVision/Getty Images)

In 1950, Italian-American physicist Enrico Fermi sat down to lunch with some of his colleagues at the Los Alamos National Laboratory, where he had worked five years prior as part of the Manhattan Project.

According to various accounts, the conversation turned to aliens and the recent spate of UFOs. Into this, Fermi issued a statement that would go down in the annals of history: "Where is everybody?"

This became the basis of the Fermi Paradox, which refers to the disparity between high probability estimates for the existence of extraterrestrial intelligence (ETI) and the apparent lack of evidence.

Since Fermi's time, there have been several proposed resolutions to his question, which includes the very real possibility that interstellar colonization follows the basic rule of Percolation Theory.

One of the key assumptions behind the Fermi Paradox is that given the abundance of planets and the age of the Universe, an advanced exo-civilization should have colonized a significant portion of our galaxy by now.

This is certainly not without merit, considering that within the Milky Way galaxy alone (which is over 13.5 billion years old), there are an estimated 100 to 400 billion stars.

Another key assumption is that intelligent species will be motivated to colonize other star systems as part of some natural drive to explore and extend the reach of their civilization.

Last, but certainly not least, it assumes that interstellar space travel would be feasible and even practical for an advanced exo-civilization.

But this, in turn, comes down to the assumption that technological advances will provide solutions to the single-greatest challenge of interstellar travel.

In short, the amount of energy it would take for a spacecraft to travel from one star to another is prohibitively large, especially where large, crewed spacecraft would be concerned.

Relativity is a harsh mistress

In 1905, Einstein published his seminal paper in which he advanced his Special Theory of Relativity. This was Einstein's attempt to reconcile Newton's Laws of Motion with Maxwell's Equations of electromagnetism in order to explain the behavior of light.

This theory essentially states that the speed of light (in addition to being constant) is an absolute limit beyond which objects cannot travel.

This is summarized by the famous equation, E=mc2, which is otherwise known as the "mass-energy equivalence." Put simply, this formula describes the energy (E) of a particle in its rest frame as the product of mass (m) with the speed of light squared (c2) – approx. 300,000 km/s; 186,000 mi/s. A consequence of this is that as an object approaches the speed of light, its mass invariably increases.

Therefore, for an object to reach the speed of light, an infinite amount of energy would have to be expended accelerating it. Once c was achieved, the mass of the object would also become infinite.

In short, achieving the speed of light is impossible, never mind exceeding it. So barring some tremendous revolution in our understanding of physics, a Faster-Than-Light (FTL) propulsion system can never exist.

Such is the consequence of living in a relativistic Universe, where traveling at even a fraction of the speed of light requires tremendous amounts of energy.

And while some very interesting and innovative ideas have been produced over the years by physicists and engineers who want to see interstellar travel become a reality, none of the crewed concepts are what you might call "cost-effective."

A Matter of Principle

This raises a very important philosophical question that is related to the Fermi Paradox and the existence of ETIs. This is none other than the Copernican Principle, named in honor of famed astronomer Nicolaus Copernicus.

To break it down, this principle is an extension of Copernicus' argument about the Earth, how it was not in a unique and privileged position to view the Universe.

Extended to the cosmological realm, the principle basically asserts that when considering the possibility of intelligent life, one should not assume that Earth (or humanity) is unique.

Similarly, this principle holds that the Universe as we see it today is representative of the norm – aka, that it is in a state of equilibrium.

The opposing view that humanity is in a unique and privileged position to observe the Universe is what is known as the Anthropic Principle.

In a nutshell, this principle states that the very act of observing the Universe for signs of life and intelligence requires that the laws that govern it be conducive to life and intelligence.

If we accept the Copernican Principle as a guiding principle, we are forced to concede that any intelligent species would face the same challenges with interstellar flight as we do.

And since we do not foresee a way around these, barring major a breakthrough in our understanding of physics, perhaps no other species has found one either.

Could this be the reason for the "Great Silence"?

Origin

The notion that distance and time may be a factor (in relation to the Fermi Paradox) has received quite a bit of consideration over time.

Carl Sagan and William I. Newman suggested in their 1981 study, "Galactic civilizations: Population dynamics and interstellar diffusion," that signals and probes by ETIs may simply not have reached Earth yet. This was met with criticism by other scientists who argued that it contradicted the Copernican Principle.

By Sagan and Newman's own estimates, the time it would take for an ETI to have explored the entire galaxy is equal to or less than the age of our galaxy itself (13.5 billion years). If an exo-civilization's probes or signals have not reached us yet, this would imply that sentient life started to emerge in the more recent past.

In other words, the galaxy is in a state of disequilibrium, moving from a state of being uninhabited to inhabited.

However, it was Geoffrey A. Landis who made what is perhaps the most compelling argument about the limits imposed by the laws of physics.

In his 1993 paper, "The Fermi paradox: an approach based on percolation theory," he argued that as a consequence of Relativity, an exo-civilization would only be able to expand so far throughout the galaxy.

Central to Landis' argument was the mathematical and physics statistics concept known as "percolation theory," which describes how a network behaves when nodes or links are removed.

In accordance with this theory, when enough of the network's links are removed, it will break down into smaller connected clusters.

According to Landis, this same process is useful in describing what happens to people engaged in migration.

In short, Landis proposed that in a galaxy where intelligent life is statistically likely, there will not be a "uniformity of motive" among extraterrestrial civilizations. Instead, his model assumes a wide variety of motives, with some choosing to venture out and colonize while others choose to "stay at home."

As he explained it:

"Since it is possible, given a large enough number of extraterrestrial civilizations, one or more would have certainly undertaken to do so, possibly for motives unknowable to us. Colonization will take an extremely long time, and will be very expensive.

"It is quite reasonable to suppose that not all civilizations will be interested in making such a large expenditure for a pay off far in the future. Human society consists of a mixture of cultures which explore and colonize, some times over extremely large distances, and cultures which have no interest in doing so."

To summarize, an advanced species would not colonize the galaxy rapidly or consistently. Instead, it would "percolate" outwards to a finite distance, where increasing costs and the lag time between communications imposed limits and colonies evolved their own cultures.

Thus, colonization wouldn't be uniform but would happen in clusters with large areas remaining uncolonized at any given time.

A similar argument was made in 2019 by Adam Frank and a team of exoplanet researchers from NASA's Nexus for Exoplanetary Systems Science (NExSS).

In a study titled "The Fermi Paradox and the Aurora Effect: Exo-civilization Settlement, Expansion, and Steady States," they argued that settlement of the galaxy would also occur in clusters because not all potentially-habitable planets would be hospitable for a colonizing species.

Of course, Landis' model contains some inherent assumptions of its own, which he laid out beforehand.

First, there was the assumption that interstellar travel is difficult due to the laws of physics and that there is a maximum distance over which colonies can be directly established. Hence, a civilization will only colonize within a reasonable distance from its home, beyond which secondary colonization will occur later.

Second, Landis also makes the assumption that the parent civilization will have a weak grasp over any colonies it creates, and the time needed for these to develop their own colonization capability will be very long. Hence, any colony established will develop its own culture over time, and its people will have a sense of self and identity distinct from that of the parent civilization.

As we explored in a previous article, it would take between 1,000 and 81,000 years to reach Proxima Centauri (4.24 light-years away) using current technology.

While there are concepts that would allow for relativistic travel (a fraction of the speed of light), the travel time would still be anywhere from a few decades to over a century. What's more, the cost would be extremely prohibitive (more on that below).

But getting colonists to another star system is just the beginning.

Once they have settled a nearby habitable planet (and not all died off) and have the infrastructure for interstellar communications, it would still take eight-and-a-half years to send a message to Earth and receive an answer. That's simply not practical for any civilization hoping to maintain centralized control or cultural hegemony over its colonies.
Space is expensive!

To put things in perspective, consider the costs associated with humanity's own history of space exploration. Sending astronauts to the Moon as part of the Apollo Program between 1961 and 1973 cost a hefty US$25.4 billion, which works out to about US$150 billion today (when adjusted for inflation).

But Apollo did not occur in a vacuum, and first required Project Mercury and Project Gemini as stepping stones.

These two programs, which put the first American astronauts in orbit and developed the necessary expertise for getting to the Moon, respectively ran about US$2.3 billion and US$10 billion (when adjusted).

Add them all up, and you get a grand total of around US$163 billion spent from 1958 to 1972.

By comparison, Project Artemis, which will return astronauts to the Moon for the first time since 1972, will cost US$35 billion over just the next four years!

That doesn't include the costs of getting all the various components to this stage in the game, like the development of the SLS thus far, the Orion space capsule, and research into the Lunar Gateway, human landing systems (HLS), and robotic missions.

That's a lot of money just to get to Earth's only satellite. But that's nothing compared to the costs of interstellar missions!
Going interstellar?

Since the dawn of the Space Age, many theoretical proposals have been made for sending spacecraft to the nearest stars.

At the heart of each and every one of these proposals was the same concern: can we reach the nearest stars in our lifetimes?

In order to meet this challenge, scientists contemplated a number of advanced propulsion strategies that would be capable of pushing spacecraft to relativistic speeds.

Of these, the most straightforward was definitely Project Orion (1958 to 1963), which would rely on a method known as Nuclear Pulse Propulsion (NPP).

Led by Ted Taylor of General Atomics and physicist Freeman Dyson from the Institute for Advanced Study at Princeton University, this project envisioned a massive starship that would use the explosive force generated by nuclear warheads to generate thrust.

These warheads would be released behind the spacecraft and detonated, creating nuclear pulses. These would be absorbed by a rear-mounted pressure plate (aka, "pusher") that translate the explosive force into forward momentum.

Though inelegant, the system was brutally simple and effective, and could theoretically achieve speeds of up to 5 percent the speed of light (5.4×107km/hr, or 0.05c).

Alas, the cost. According to estimates produced by Dyson in 1968, an Orion spacecraft would weight between 400,000 and 4,000,000 metric tons.

Dyson's most conservative estimates also placed the cost of building such a craft at US$367 billion (US$2.75 trillion when adjusted for inflation). That's about 78 percent of the US government's annual revenue for 2019, and 10 percent of the country's GDP.

Another idea was to build rockets that rely on thermonuclear reactions to generate thrust.

Specifically, the concept of Fusion Propulsion was investigated by the British Interplanetary Society between 1973 and 1978 as part of a feasibility study known as Project Daedalus.

The resulting design called for a two-stage spacecraft that would generate thrust by fusing pellets of a deuterium/helium-3 in a reaction chamber using electron lasers.

This would create a high-energy plasma that would then be converted to thrust by a magnetic nozzle.

The first stage of the spacecraft would operate for just over 2 years and accelerate the spacecraft to 7.1 percent the speed of light (0.071c). This stage would then be jettisoned and the second stage would take over and accelerate the spacecraft up to about 12 percent of light speed (0.12c) over the course of 1.8 years.

The second-stage engine would then be shut down, and the ship would enter into a 46-year cruise period.

According to the Project's estimates, the mission would take 50 years to reach Barnard's Star (less than 6 light-years away). Adjusted for Proxima Centauri, the same craft could make the trip in 36 years.

But in addition to technological barriers identified by the Project, there was also the sheer costs involved.

Even by the modest standard of an uncrewed concept, a fully-fueled Daedalus would weigh as much as 60,000 metric tons cost over [US$5.2 trillion] (based on 2012 estimates). Adjust to 2020, the price tag for a fully-assembled Daedalus would cost close to US$6 trillion. Icarus Interstellar, an international organization of volunteer citizen scientists (founded in 2009), has since attempted to revitalize the concept with Project Icarus.

Another bold and daring idea is Antimatter Propulsion, which would rely on the annihilation of matter and antimatter (hydrogen and antihydrogen particles).

This reaction unleashed as much energy as a thermonuclear detonation, as well as a shower of subatomic particles (pions and muons).

These particles, which would then travel at one-third the speed of light, are channeled by a magnetic nozzle to generate thrust.

Unfortunately, the cost of producing even a single gram of antimatter fuel is estimated to be around US$1 trillion.

According to a report by Robert Frisbee of NASA's Advanced Propulsion Technology Group (NASA Eagleworks), a two-stage antimatter rocket would need over 815,000 metric tons (900,000 US tons) of fuel to make the journey to Proxima Centauri in approximately 40 years.

A more optimistic report by Dr. Darrel Smith & Jonathan Webby of the Embry-Riddle Aeronautical University states that a spacecraft weighing 400 metric tons (441 US tons) and 170 metric tons (187 US tons) of antimatter fuel could reach 0.5 the speed of light.

At this rate, the craft could reach Proxima Centauri in a little over 8 years, but there's no cost-effective way to do this and no guarantees there ever will be.

In all cases, propellant makes up a large fraction of these concept's overall mass. To address this, variations have been proposed that could generate their own propellant.

In the case of fusion rockets, there's the Bussard Ramjet, which uses an enormous electromagnetic funnel to "scoop" hydrogen from the interstellar medium and magnetic fields to compress it to the point that fusion occurs.

Similarly, there's the Vacuum to Antimatter Rocket Interstellar Explorer System (VARIES), which also creates its own fuel out of the interstellar medium. Proposed by Richard Obousy of Icarus Interstellar, a VARIES ship would rely on large lasers (powered by enormous solar arrays) that would create particles of antimatter when fired at empty space.

Alas, neither of these ideas are possible using current technology, nor are they within the realm of cost-effectiveness (not by a long shot).

Under the circumstances, and barring several major technological developments that would reduce the associated costs, it would be fair to say that any idea for interstellar crewed missions is simply impractical.

Sending probes to other stars within our lifetimes is still within the realm of possibility, especially those that rely on Directed-Energy Propulsion (DEP).

As proposals like Breakthrough Starshot or Project Dragonfly show, these sails could be accelerated to relativistic speeds and have all the necessary hardware to gather pictures and basic data on any orbiting exoplanets.

However, such probes are a potentially-reliable and cost-effective means of interstellar exploration, not colonization.

What's more, the time-lag involved in interstellar communications would still place constraints on how far these probes could explore while still reporting back to Earth.

Therefore, an exo-civilization is not likely to send probes very far beyond the boundaries of its territory.
Criticisms

A possible criticism of percolation theory is that it allows for many scenarios and interpretations that would permit contact to have happened at this point.

If we assume that an intelligent species would similarly take 4.5 billion years to emerge (the time between Earth's formation and modern humans), and consider that our galaxy has been around for 13.5 billion years, that still leaves a 9 billion years window.

For 9 billion years, multiple civilizations could have come and gone, and while no one species could have colonized the entire galaxy, it's hard to imagine that this activity would have gone unnoticed.

Under the circumstances, one may be forced to conclude that in addition to their being limits to how a civilization can reach that there are other limiting factors at work here (Great Filter, anyone?)

However, it is important to remind ourselves that no proposed resolution to the Fermi Paradox is without its share of holes.

Also, expecting a theory or theorist to have all the answers to a subject as complex (yet data-poor) as the existence of extraterrestrials is about as unrealistic as expecting consistency in the behavior of ETIs themselves!

Overall, this hypothesis is highly useful because of the way it breaks down many of the assumptions inherent to "Fact A."

It also presents an entirely logical starting point for answering the fundamental question. Why haven't we heard from any ETIs? Because it's unrealistic to conclude that they should have colonized the better part of the galaxy by now, especially when the laws of physics (as we know them) preclude such a thing.


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