Tuesday, August 31, 2021

GOLD's bird's-eye reveals dynamics in Earth's interface to space

AUGUST 30, 2021, by Sarah Frazier, NASA

Processes in Earth’s upper atmosphere create bright swaths of color known as airglow, as seen here in an image taken from the International Space Station.
 Credit: NASA

New research using data from NASA's Global-scale Observations of the Limb and Disk, or GOLD, mission, has revealed unexpected behavior in the swaths of charged particles that band Earth's equator—made possibly by GOLD's long-term global view, the first of its kind for this type of measurement.

GOLD is in geostationary orbit, which means it orbits around Earth at the same pace the planet turns and "hovers" over the same spot overhead. This allows GOLD to watch the same area for changes over time across longitude and latitude, something that most satellites studying the upper atmosphere can't do.

"Since GOLD is on a geostationary satellite, we can capture 2D time evolution of these dynamics," said Dr. Xuguang Cai, a researcher at the High Altitude Observatory in Boulder, Colorado, and lead author on a new research paper.

GOLD focuses on parts of Earth's upper atmosphere stretching from about 50 to 400 miles in altitude, including a neutral layer called the thermosphere and the electrically charged particles that make up the ionosphere. Unlike the neutral particles in most of Earth's atmosphere, the ionosphere's charged particles respond to the electric and magnetic fields threading through the atmosphere and near-Earth space. But because the charged and neutral particles are mixed together, something that influences one population can also impact the other.

This means the ionosphere and upper atmosphere are shaped by a host of complex factors, including space weather conditions—such as geomagnetic storms, driven by the Sun—and terrestrial weather. These regions also act as a highway for many of our communications and navigation signals. Changes in the ionosphere's density and composition can muddle the signals passing through, like radio and GPS.

https://youtu.be/vREIG7BSUJo
The shape of Earth’s magnetic field (represented by orange lines in this data visualization) near the equator drive charged particles (blue) away from the equator, creating two dense bands just north and south of the equator known as the equatorial ionization anomaly. 
Credit: NASA’s Scientific Visualization Studio

From its vantage point on a commercial communications satellite in geostationary orbit, GOLD makes hemisphere-wide observations of the ionosphere about every 30 minutes. This unprecedented birds-eye view is giving scientists new insights into how this region changes.

Mysterious movement

One of the nighttime ionosphere's most distinctive features are twin bands of dense charged particles on either side of Earth's magnetic equator. These bands—called the Equatorial Ionization Anomaly, or EIA—can change in size, shape, and intensity, depending on the conditions in the ionosphere.

The bands can also move position. Until now, scientists have relied on data captured by satellites passing through the region, averaging measurements over months to see just how the bands might be shifting in the long term. But short-term changes were more difficult to track.

Before GOLD, scientists suspected that any quick changes that happen in the bands would be symmetrical. If the northern band moves north, the southern band makes a mirror motion south. One night in November 2018, though, GOLD saw something that challenged this idea: the southern band of particles drifted southward, while the northern band remained steady—all in less than two hours.

(screen shot only CC)
NASA’s GOLD mission – short for Global-scale Observations of the Limb and Disk – saw a surprising asymmetric motion in one of the twin bands of charged particles that form in Earth’s atmosphere at night. GOLD’s unique perspective (right) made this observation possible, as other types of measurements made from ground-based instruments (left) can’t see changes that happen over open waters. The red dots show the peak of the electron band as measured by ground-based sensors that measure total electron content, while the black dots show the peak of the electron band measured by GOLD. Towards the end of the visualization, the measured peaks appear in different places. 
Credit: NASA's Scientific Visualization Studio

This isn't the first time scientists have seen the bands move like this, but this shorter event—only about two hours, compared to a more typical six to eight hours seen prior—was seen for the first time, and could only have been observed by GOLD. The observations are outlined in a paper published on Dec. 29, 2020, in the Journal of Geophysical Research: Space Physics.

The symmetrical drifting of these bands is caused by rising air that drags charged particles along with it. As night falls and temperatures cool, warmer pockets of air surge upwards. The charged particles carried within these warmer air pockets are bound by magnetic field lines, and for those pockets near Earth's magnetic equator the shape of Earth's magnetic field means that upward motion also pushes the charged particles horizontally. This creates the symmetrical northward and southward drift of the two charged particle bands.

The exact cause of the asymmetric drift observed by GOLD is still a mystery—though Cai suspects the answer lies in some combination of the many factors that shape the motion of electrons in the ionosphere: ongoing chemical reactions, electric fields, and high-altitude winds blowing through the region.

Though surprising, these findings can help scientists peer behind the curtain of the ionosphere and better understand what drives its changes. Because it's impossible to observe every process with a satellite or ground-based sensor, scientists rely heavily on computer models to study the ionosphere, much like models that help meteorologists predict weather on the ground. To create these simulations, scientists code in what they suspect are the underlying physics at work and compare the model's prediction to observed data.

Before GOLD, scientists got that data from occasional passing satellites and limited ground-based observations. Now, GOLD gives scientists a bird's-eye view.




Recommend this post and follow
Sputnik's Orbit






Posted by Hot air Chuck

SPACE - S0 - 20210831 - Magnetic Spin, GOLD Anomaly, Galaxy Rotation

SPACE - S0 - 20210831 - Magnetic Spin, GOLD Anomaly, Galaxy Rotation

Good Morning, 0bservers!

    

     
Quick Note: Glad to be back!!! I've missed reporting on that big glowy thing in the daytime skies, what's it called again?

Had a number of long outages on the DSCOVR satellite yesterday, almost 13 hours worth. The readings when it was working were a bit odd as well, but we've seen a drop in solar wind speeds from a peak of 440 KPS at midnight UTC on Monday morning to a calmer 380 KPS as of 1000 UTC. Particle Density had a brief rise and fall around 1730 UTC, but began a slow and steady rise around 0200 UTC. Temperatures followed the solar winds downward from a peak of around 5400°K at midnight UTC to a shade below 4100°K at last report. Phi Angle readings were a bit scrambled in the afternoon-evening hours yesterday, but they seem to have stabilized around 2200 UTC, once the Bt/Bz gap steadied and there were no more polarity collisions or near-misses. The KP-Index has been elevated to KP-3 for three readings since midnight UTC, but it's been in the green for the past two days so we may have dodged the worse of that expected CME impact predicted the other day. That said, NOAA is predicting a KP-5 late tomorrow night, which may be the remainder of the second CME following the first one. The Magnetometer has been like a ride at Cedar Point, peaking over 140 nT Sunday afternoon, and then nicking the 40 nT threshold around 0500 UTC this morning. The Proton Flux is its usual nominal self, but the Electron Flux has been above the alert threshold more than below it over the last three days. We're well passed the Class M flare from Saturday, but we had a number of "smaller" and shorter Class C flares pretty much all of yesterday. Oddly, they seem to have dropped off completely after 0200 UTC, with the background radiation dropping to the lower quarter of Class B. The ENLIL Spiral is showing a large ejection from just behind the Western lim, heading far away from Earth. However, there's no evidence of that on the LASCO C3 video loop, nor am I seeing that on the ENLIL Spiral animation on the NOAA site. Can't figure out the discrepancy between the two. The video loops at 193Å showed the solar surface acting like a popcorn machine, spewing out spurts of energy from a variety of locations. Also seeing a new coronal hole system developing from just South of the equator to the mid-latitudes. Should be crossing the midline in 36-48 hours. The loops at 304Å and 131Å ran as if the Sun was a giant Rice Krispie (snap/crackle/pop), small flares and sparks but a lot of 'em. That sunspot group in the South is well passed the centerline, but it is a big honkin' sucker when you look at the magnetometer. Its BGD complexity looks more like an OMG, so it'll be good when it finally gets out of striking range of Earth.
* * *
New videos from Suspicious0bservers, "Ben vs Entire NASA Climate Team", "The Waters Below, Lightning & Earth's Magnetic Disaster", and "Electromagnetic Atmospheric Physics | For Beginners & NASA".



 
Enjoy!
  
Please Recommend this page and be sure to follow the Sputnik's Orbit 


AND WHILST YOU ARE HERE BE SURE TO FOLLOW AND RECOMMEND THE THANK GOODNESS ITS OWEN FRIDAY BLOGSPOT! https://tgiof.blogspot.com/

Sunday, August 29, 2021

New Nanomaterial Resists Projectile Impact Better Than Kevlar

By CALIFORNIA INSTITUTE OF TECHNOLOGY AUGUST 28, 2021
https://scitechdaily.com/new-nanomaterial-resists-projectile-impact-better-than-kevlar/


Engineers at MIT, Caltech, and ETH Zürich find “nanoarchitected” materials designed from precisely patterned nanoscale structures (pictured) may be a promising route to lightweight armor, protective coatings, blast shields, and other impact-resistant materials.
 Credit: Courtesy of the researchers


Thinner than a human hair, new material can absorb impacts from microparticles traveling at supersonic speeds.

Engineers at Caltech, MIT, and ETH Zürich have developed a nano-architected material made from tiny carbon struts that is, pound for pound, more effective at stopping a projectile than Kevlar, a material commonly used in personal protective gear.

Pioneered by Caltech materials scientist Julia R. Greer, nano-architected materials have a structure that is designed at a nanometer scale and exhibit unusual, often surprising properties—for example, exceptionally lightweight ceramics that spring back to their original shape, like a sponge, after being compressed.

“The knowledge from this work could provide design principles for ultra-lightweight impact resistant materials for use in efficient armor materials, protective coatings, and blast-resistant shields desirable in defense and space applications,” says Greer, the Ruben F. and Donna Mettler Professor of Materials Science, Mechanics and Medical Engineering, whose lab led the material’s fabrication. Greer is co-corresponding author of a paper on the new material that was published in Nature Materials.



The team tested the material’s resilience by shooting it with microparticles at supersonic speeds, and found that the material, which is thinner than the width of a human hair, prevented the miniature projectiles from tearing through it. 
Credit: Courtesy of the researchers



The material, which is thinner than a human hair, consists of interconnected tetrakaidecahedrons made out of carbon struts that have been formed under extreme heat (known as pyrolytic carbon). Tetrakaidecahedrons are structures with 14 faces: six with four sides and eight with eight sides. They are also called “Kelvin cells” because, in 1887, Lord Kelvin (physicist William Thomson, 1st Baron Kelvin, in whose honor we state absolute temperatures in units of “Kelvin”) suggested that they would be the best shape to fill an empty three-dimensional space with equal-sized objects using minimal surface area.

“Historically this geometry appears in energy-mitigating foams, says Carlos Portela (MS ’16, PhD ’19), assistant professor of mechanical engineering at MIT and lead/co-corresponding author of the Nature Materials paper. Portela and his lab investigated the use of the foam-like structures to lend flexibility to the stiff carbon. “While carbon is normally brittle, the arrangement and small sizes of the struts in the nano-architected material gives rise to a rubbery, bending-dominated architecture,” he says.

While the strength of nano-architected materials has been studied using slow deformation (compression and tension, for example), Portela wanted to know how such a material might survive a high-speed impact.




Using a high-speed camera, researchers captured videos of the microparticles making impact with the nanoarchitected material. 
Credit: MIT / Courtesy of the researchers





While a postdoc at Caltech in the Greer lab, Portela first fabricated the material out of photosensitive polymer using two-photon lithography, a technique that uses a fast high-powered laser to solidify and sculpt microscopic structures. His team then pyrolized the structures; that is, they burnt them in a furnace at a very high temperature to convert the polymer to pyrolytic carbon. The scientists created two versions of the material: a denser and a looser one. Portela’s lab then blasted both versions with 14-micron-diameter spherical silicon oxide particles, one at a time. The particles traveled at between 40 and 1,100 meters per second; for reference, the speed of sound is 340 meters per second.

The researchers found that the denser version of the material was more resilient, with the microparticles tending to embed in the material rather than tearing straight through, as would be the case with either fully dense polymers or carbon sheets of the same thickness. Under closer examination, they discovered that individual struts directly surrounding the particle would crumple, but the overall structure remained intact until the projectile stopped. Pound for pound, the new material outperformed steel by more than 100 percent and Kevlar composites by more than 70 percent.

“We show the material can absorb a lot of energy because of this shock compaction mechanism of struts at the nanoscale versus something that’s fully dense and monolithic, not nano-architected,” Portela says.

For the material to be used in real-world applications, researchers next will need to find ways to scale up its production and to explore how other nano-architected materials, including those made out of materials other than carbon, hold up under high-speed impacts. In the meantime, the study has demonstrated the viability of nano-architected materials for impact resistance, opening up a new avenue of research.

Co-authors include Caltech former graduate student Bryce Edwards; David Veysset, Yuchen Sun, and Keith A. Nelson of MIT’s Institute for Soldier Nanotechnologies and department of chemistry; and Dennis M. Kochmann of ETH Zürich. This research was supported in part by the Office of Naval Research, the Vannevar Bush Faculty Fellowship, and the U.S. Army Research Office through the Institute for Soldier Nanotechnologies at MIT.


Recommend this post and follow 
Sputnik's Orbit




Posted by Armoured Chuck

Saturday, August 28, 2021

Norway sets timeline to deploy sub-hunting aircraft in the Arctic

By Gerard O'Dwyer, Aug 27, 2021

Norway signed a contract to purchase five P-8A aircraft in March 2017. 
(MC2 Sean Rinner/U.S. Navy)

HELSINKI — Norway’s announcement that it plans to deploy P-8A Poseidon surveillance aircraft to the Arctic in 2022 marks significant progress in the country’s long-term effort to bolster defense capabilities and readiness in the region.

The Ministry of Defence unveiled the timeline Aug. 13, having already approved Evenes Air Station as the main base for its future Boeing-made fleet.

The Royal Norwegian Air Force ordered five P-8A Poseidons to replace its in-service fleet of six Lockheed Martin P-3C/N Orion maritime patrol aircraft and two Dassault Falcon 20 special mission aircraft. The service’s P-3 Orions operate from the Andoya Air Station, located 190 miles inside the Arctic Circle.

Evenes Air Station offers the P-8As shorter flying times to key strategic areas within Norway’s maritime security zone in the high north. The aircraft to be are equipped with submarine-detection sonobuoy technology, and they can identify and launch torpedoes to eliminate hostile submarines.

Norway signed a contract to purchase five P-8As in March 2017, with delivery dates in 2022 and 2023. The first of the P-8As on order underwent tests during the first week of August, jointly conducted by Boeing and Norway’s MoD in the United States.

The acquisition forms part of the Norwegian Armed Forces’ strategic plan to beef up maritime surveillance in the high north against the backdrop of increasing submarine activity by Russia’s Northern Fleet and foreign surface vessels in areas west of the Barents Sea, including the Norwegian Sea and the northern Atlantic Ocean.

“We have a challenging strategic environment that constantly reminds us that we cannot take our freedom and security for granted. Norway will continue to invest substantially in defense and security to ensure we remain a reliable, responsible and capable partner on the Northern flank of the Alliance [NATO],” Defence Minister Frank Bakke-Jensen said in an August update on the Poseidon buy.

The Norwegian military has developed a plan to strengthen its ability to track newer Russian vessels, including the fourth-generation, Yasen-class multimission submarines equipped with superior stealth features, compared to other subs in Russia’s Northern Fleet. Armed with long-range cruise missiles, Yasen subs pose a new level of concern for Norway and its NATO allies.

The scale of Norway’s reinforcement in the high north is reflected in its planned spending from 2021 to 2024. The government raised spending from $6.9 billion in 2020 to almost $7.3 billion in 2021. Military spending it to increase to about $7.85 billion in 2024, second only to Sweden in terms of defense spending by a Nordic country.

The spending is largely driven by the government’s “Long Term Defence Plan,” released in October.

Amid the procurement of pricey P-8As and F-35 fighter jets, the long-term effort includes a capital investment plan to upgrade the military’s NASAMS II air defense systems with modern sensors. “This will contribute to countering threats against bases, and protect allied reception areas and other vital infrastructure,” the plan’s summary document read.

Additionally, the 2021 budget includes a provision to equip the special forces with new and improved transport helicopters able to operate in extreme climates, meant to replace Bell 412 helos.

Norway is also considering a long-term option to add long-range air defense systems to its inventory.

The long-term plan also embraces closer collaboration with NATO forces in the high north, and particularly in joint training that leads to allied growth in the region. Already, Britain’s separate decision to acquire and deploy P-8As is expected to complement long-term, joint operations with Norway.

The ongoing restructuring of the Royal Norwegian Air Force, including in sub-Arctic Norway, is also expected to substantially buttress air defenses. This major capital project includes the development of new bases to house newly acquired capacities such as F-35s, NH90 multirole helicopters and AW101 rescue helicopters.

The Orland Air Station will serve as the main base for the 52-strong fleet of F-35s, slated to become fully operational in 2025. Farther north, Evenes Air Station is the service’s primary “quick reaction alert” base, conducted on behalf of NATO.

The Air Force created a maritime helicopter wing at Bardufoss Air Station in the north of the country in 2019 as part of an air-defense restructuring plan. Station Group Gardermoen, located outside Oslo, was expanded to house the service’s C-130J Hercules and DA-20 aircraft, while the Army’s Bell 412 helicopters operate out of the Rygge Air Base.

Recommend this post and follow
Sputnik's Orbit





Posted by Chuck

Friday, August 27, 2021

How extreme cold can crack lithium-ion battery materials, degrading performance

AUGUST 26, 2021, by Nathan Collins, Stanford University

The drone Ingenuity as seen by NASA's Mars Perseverance rover. SLAC researchers are working to understand the effects of the extreme temperatures of distant planets—or Midwest winters—on the rechargeable batteries that power devices like these.
 Credit: NASA/JPL-Caltech / Arizona State University / Malin Space Science Systems

Lithium ion batteries are a bit famous for their poor cold-weather performance, and that has consequences for some of their most important applications—everything from starting an electric car in a Wisconsin winter to flying a drone on Mars.

Now, researchers at the Department of Energy's SLAC National Accelerator Laboratory have identified an overlooked aspect of the problem: Storing lithium-ion batteries at below-freezing temperatures can crack some parts of the battery and separate them from surrounding materials, reducing their electric storage capacity.

SLAC scientist Yijin Liu and postdoctoral fellow Jizhou Li made the discovery while looking at the cold-weather performance of the cathode, the part of the battery electrons flow into when it's in use. Initial studies found that storing cathodes at temperatures below zero degrees Celsius led batteries to lose up to 5% more of their capacity after 100 charges than batteries stored at warmer temperatures.

To understand why, the researchers turned to a combination of X-ray analysis methods at SLAC's Stanford Synchrotron Radiation Lightsource and machine learning techniques that Li has been working on over the last several years. The combination allows them to identify individual cathode particles—meaning the team could study thousands of particles at once, compared to just the handful they could identify with their eyes alone.

Together, those methods revealed that cold temperatures were shrinking the meatball-like particles within the cathode and in the process cracking them—or making existing cracks even worse, Liu said. And, since materials differ in the way they expand and contract in response to changing temperatures, extreme cold was also detaching the cathodes from surrounding materials.

The results point to some possible fixes, Liu said. By looking for battery materials that are better matched in terms of their temperature response, scientists could address the detachment issue. Doing so could help improve other batteries as well, since all batteries expand and contract as they heat up and cool down. And by engineering different particle structures inside a battery—notably, building them up from smoother, less meatball-like particles—researchers could help prevent cracking and improve long-term lithium-ion battery capacity.


Recommend this post and follow
Sputnik's Orbit




Posted by DC Chuck

Thursday, August 26, 2021

Discovery of fastest ever magnetic wave propagation

AUGUST 26, 2021, by Radboud University

Credit: Radboud University

Like light waves, magnetic waves move through materials at a fixed maximum velocity. However, at the smallest possible length scale (nanometres) and the shortest possible time scale (femtoseconds), magnetism behaves differently.

Physicists at Radboud University have discovered that magnetic waves with very short wavelengths can propagate up to 40% faster than previously thought. This supermagnonic propagation offers opportunities for even faster, smaller and more energy-efficient ways of data processing in future computers. The research will be published in Physical Review Letters on 25 August.

"The concept is comparable to supersonic aircrafts, which move faster than the maximum speed of sound waves. We therefore call these fastest magnetic waves supermagnonic," explains physicist Johan Mentink. Thanks to a new theoretical methodology inspired by machine learning, the researchers managed to perform calculations on two-dimensional magnets. These calculations revealed that the smallest magnetic waves can travel up to 40% faster than the maximum propagation speed. "Thanks to the machine learning simulations by colleague Giammarco Fabiani and the analytical calculations by Master's student Martijn Bouman, we now understand why these supermagnonic magnetic waves can exist."

Faster, more energy efficient and smaller

In today's computers, information is transferred from A to B by electrons. However, the speed of this information transfer has its limits. In addition, there is an energy loss due to the resistance electrons experience along the way. Alternatively, light pulses can be used for information transfer, as is done in fiber internet, for example. Information transfer using light is faster and more energy efficient.

"However, our objective lies beyond that," Johan Mentink says. "We are looking for a way to make data transfer faster, more energy-efficient and smaller. Light waves are fast, but the wavelength of light is quite long. In order to find smaller solutions, we will have to look at shorter waves: like magnetic waves, for example."

Being faster, smaller and more efficient is vital for future computers. Consider, for example, the huge data centers in our country that already today use a significant part of our power grid's capacity: this consumption will only increase in the future. Johan Mentink: "Our research has shown that, in theory, data transfer using supermagnonic motion can be even faster than was thought possible. However, we do not yet know exactly how magnetism works at the smallest length scales and shortest time scales. In order to eventually use magnetism for data processing in practice, we must first understand the underlying fundamental physics. This research pushes the boundaries of our knowledge and takes us one step closer."


Recommend this post and follow
Sputnik's Orbit



Posted by Chuck

Wednesday, August 25, 2021

Cosmic rays may be key to understanding galactic dynamics

AUGUST 24, 2021, by American Institute of Physics

This illustration shows how waves and particles interact -- wave amplitude is growing while particle drift speed is dropping due to scattering. 
Credit: A. Marcowith, A.J. van Marle, and I. Plotnikov

Cosmic rays are charged subnuclear particles that move close to the speed of light, constantly raining down on the Earth. These particles are relativistic, as defined by Albert Einstein's special relativity, and manage to generate a magnetic field that controls the way they move within the galaxy.

Gas within the interstellar medium is composed of atoms, mostly hydrogen and mostly ionized, meaning its protons and electrons are separated. While moving around within this gas, cosmic rays kickstart the background protons, which causes a collective plasma wave movement akin to the ripples on a lake when you toss in a stone.

The big question is how cosmic rays deposit their momentum into the background plasma that composes the interstellar medium. In Physics of Plasmas, plasma astrophysicists in France review recent developments within the field of studying the streaming instability triggered by cosmic rays within astrophysical and space plasma.

"Cosmic rays may help explain aspects of our galaxy from its smallest scales, such as protoplanetary disks and planets, to its largest scales, such as galactic winds," said Alexandre Marcowith, from the University of Montpellier.

Until now, cosmic rays were viewed as being a bit apart within galaxy "ecology." But because instability works well and is stronger than expected around cosmic ray sources, such as supernova remnants and pulsars, these particles likely have far more impacts on galactic dynamics and the star formation cycle than previously known.

"This is not really a surprise, but more of a paradigm shift," Marcowith said. "In science and astrophysics, everything is connected."

Supernova shock waves expanding the interstellar/intergalactic medium "are known to accelerate cosmic rays, and because cosmic rays are streaming away, they may have contributed to generating the magnetic field seeds necessary to explain the actual magnetic field strengths we observe around us," said Marcowith.

After the amplitude of a plasma wave is reduced or damped over time, much like those generated by a stone thrown into a lake, it heats the gas of the plasma. Meanwhile, it helps scatter cosmic rays.

For this to occur, the waves need wavelengths of the same order as the cosmic ray gyro radius. Cosmic rays possess a helical (spiral) motion around the magnetic field, and its radius is called the Larmor radius.

"Say you are driving a car on a winding road. If the wavelength is of the same order as your wheel size, it will be difficult to drive," said Marcowith.

Cosmic rays are strongly scattered by these waves, and the main instability at the origin of these perturbations (waves) is the streaming instability associated with the collective streaming motion of cosmic rays.

"There are several fields of research in astrophysics using similar numerical techniques to investigate the impact of this streaming instability within different astrophysical contexts such as supernova remnants and jets," said Marcowith. "This instability and turbulence it creates may be the source of many astrophysical phenomena, and it shows how cosmic rays play a role in the big circus of our Milky Way."


Recommend this post and follow
Sputnik's Orbit






Posted by Helical Chuck

Tuesday, August 24, 2021

General Dynamics to Establish Centre of Excellence for RPAS Technologies in Québec

20.08.2021 - Canadian Defence Magazine


General Dynamics Mission Systems–Canada announced the establishment of a Centre of Excellence in Sherbrooke for remotely piloted aircraft systems (RPAS) technologies, leveraging the $9 million contribution of the Government of Québec, through Investissement Québec.

In addition to Investissement Québec's contribution, this $9.7 million investment by General Dynamics Mission Systems merges the world-class engineering, commercialization and export expertise of General Dynamics, together with the imagination and technological prowess of Laflamme Aero Inc., one of Québec's emerging aerospace innovators. Leveraging forward-thinking academia, and the critical support of government, these investments will all serve to further develop the aerospace industry.

General Dynamics has also made a strategic investment in Laflamme Aero to support the development and maturation of its LX300 tandem rotor RPAS platform. Investissement Québec, also a shareholder of Laflamme Aero, is contributing a further close to $1.9 million to industrialize and commercialize the LX300, demonstrating a firm commitment to further position Québec at the forefront of aerospace technology and innovation.

"The Centre of Excellence will position the province of Québec at the leading edge of emerging RPAS technology and advanced autonomous airborne mission systems integration," said David Ibbetson, vice president and general manager of General Dynamics Mission Systems–International. "Remotely Piloted Aircrafts are the future of aerospace and our investment will generate Québec and Canadian intellectual property, create and enhance domestic capacity, and Science, Technology, Engineering and Mathematics jobs – while developing world-leading RPAS technologies to address the growing needs of Canada and countries across the globe."

The Centre's initial focus is to mature Laflamme's LX300 for new markets. For its part, General Dynamics has developed a mission-ready Command, Control, Communications, Computers, Intelligence, Surveillance and Reconnaissance (C4ISR) suite to meet the requirements of both domestic and international RPAS opportunities.

"This support positions Laflamme for the future. What began as a passion for aviation from my father has become something much larger. With the support of Investissement Québec and General Dynamics, we now have the opportunity to leverage our success and compete on a larger scale – both at home and abroad," said Enrick Laflamme, president of Laflamme Aero.

"This remotely piloted aircraft system is the first of its kind to be fully developed and manufactured in Québec. This is a testament to the growth of our aerospace industry and our expertise in security and defence. With the creation of the Centre of Excellence in Sherbrooke and the commercialization of this innovative project, Québec will continue to stand out as a leader," said Eric Girard, Minister of Finance and Minister of Economy and Innovation.

Through the Centre of Excellence, General Dynamics Mission Systems will be expanding its investment in Canada to include a presence in Québec, while generating opportunities for small and medium-sized businesses and strengthening the domestic RPAS ecosystem through the design, development, manufacturing, and sustainment of world-leading systems.

The Centre will create and sustain up to 45 highly skilled jobs in Québec.


Recommend this post and follow
Sputnik's Orbit

Monday, August 23, 2021

Here comes the sun: Planetary scientists find evidence of solar-driven change on the moon

AUGUST 20, 2021, by Heather Tate, Northern Arizona University

Credit: CC0 Public Domain

Tiny iron nanoparticles unlike any found naturally on Earth are nearly everywhere on the moon—and scientists are trying to understand why. A new study led by Northern Arizona University doctoral candidate Christian J. Tai Udovicic, in collaboration with associate professor Christopher Edwards, both of NAU's Department of Astronomy and Planetary Science, uncovered important clues to help understand the surprisingly active lunar surface. In an article recently published in Geophysical Research Letters, the scientists found that solar radiation could be a more important source of lunar iron nanoparticles than previously thought.

Asteroid impacts and solar radiation affect the moon in unique ways because it lacks the protective magnetic field and atmosphere that protect us here on Earth. Both asteroids and solar radiation break down lunar rocks and soil, forming iron nanoparticles (some smaller, some larger) that are detectable from instruments on satellites orbiting the moon. The study used data from National Aeronautics and Space Administration (NASA) and Japan Aerospace Exploration Agency (JAXA) spacecraft to understand how quickly iron nanoparticles form on the moon over time.

"We have thought for a long time that the solar wind has a small effect on lunar surface evolution, when in fact it may be the most important process producing iron nanoparticles," Tai Udovicic said. "Since iron absorbs a lot of light, very small amounts of these particles can be detected from very far away—making them a great indicator of change on the moon".

Surprisingly, the smaller iron nanoparticles seemed to form at a similar rate as radiation damage in samples returned from the Apollo missions to the moon, a hint that the sun has a strong influence in their formation.

"When I saw the Apollo sample data and our satellite data side by side for the first time, I was shocked," Tai Udovicic said. "This study shows that the solar radiation could have a much larger influence in active change on the moon than previously thought, not only darkening its surface, but it might also create small quantities of water usable in future missions."

As NASA prepares to land the first woman and the next man on the surface of the moon by 2024 as part of the Artemis mission, understanding the solar radiation environment and possible resources on the moon are critical. In future work recently awarded a NASA Future Investigators in Space Science and Technology (FINESST) grant, Tai Udovicic plans to broaden his targeted study to the entire moon, but is also eager to take a closer look at mysterious lunar swirls, one of which was recently selected as a landing site for the upcoming Lunar Vertex rover. He also studies lunar temperatures and water ice stability to inform future missions.

"This work helps us understand, from a bird's eye view, how the lunar surface changes over time," said Tai Udovicic. "While there is still a lot to learn, we want to make sure that when we have boots back on the moon, that those missions are backed by the best science available. It's the most exciting time to be a lunar scientist since the tail end of the Apollo era in the 70s."


Recommend this post and follow
Sputnik's Orbit

SPACE - S0 - Ben Davidson Kicks "Karen's Butt...

SPACE - S0 - Ben Davidson Kicks "Karen's" Butt...

Oh, this one can't wait until I'm off the On-Call rotation, folks. Watch this. I'll be providing the link, Ben's e-Mail address, and my own reply to Dr. Karen St. Germain - yes, that really IS her name...
  
 

    My letter:

To Dr. Karen St. Germain: We Demand An Explanation  

 
Dr. St. Germain,  
 
Please view this YouTube video, and also check the links it includes in the Description. 
 
 
Your team has made a LOT of critical, and some would say egregious, mistakes in their so-called "Science". As head of that team, I feel it is incumbent upon you to investigate this. And please, don't just "take their word for it". As a Scientist yourself, that is the last thing you should ever do. You can reach Mr. Davidson at s0@suspicious0bservers.org.  
 
Respectfully,  
 
Doc Farmer  
Fort Wayne, IN
  
Please Recommend this page and be sure to follow the Sputnik's Orbit 


AND WHILST YOU ARE HERE BE SURE TO FOLLOW AND RECOMMEND THE THANK GOODNESS ITS OWEN FRIDAY BLOGSPOT! https://tgiof.blogspot.com/
 

Sunday, August 22, 2021

Why Cosmic Radiation Could Foil Plans for Farming on Mars

Friday, August 20, 2021 - Karen Kwon, Contributor

Media credits - Sergey DV via Shutterstock

(Inside Science) -- What would it take for humans to live on Mars? The first step is to successfully get people to the red planet, of course. Once there, the astronauts would face a task that could be even more difficult: figuring out how to survive in an environment that is vastly different from Earth's. A new study demonstrates one of the challenges -- Earth's plants don’t grow as well when exposed to the level of radiation expected on Mars.

Wieger Wamelink, an ecologist at Wageningen University in the Netherlands who describes himself as a space farmer, has been frustrated by sci-fi depictions of growing plants on Mars. "What you often see is that they do it in a greenhouse," he said, "but that doesn't block the cosmic radiation," which consists of high-energy particles that may alter the plants' DNA. Mars lacks the same degree of protection from cosmic radiation that the Earth's atmosphere and magnetic field provide. To prove his suspicion that cosmic radiation could be dangerous to plants, Wamelink decided to test the hypothesis himself.

First, Wamelink and his team had to recreate the cosmic radiation. The team settled on using gamma rays generated by radioactive cobalt, even though the actual cosmic radiation that bombards Mars' surface consists of various types of radiation, including alpha and beta particles. But, generating alpha and beta rays on Earth is much more difficult, Wamelink said. It would require a particle accelerator, which Wamelink would love to use, "but I would have to put some plants in the collider for, let's say, two or three months." Considering the high demand for the equipment, "I think it's not ever going to happen," he said.

Once Wamelink and his team secured radioactive cobalt, the team grew rye and garden cress in two groups: one with typical growing conditions and the other had similar conditions but added gamma radiation. Four weeks after germination, the scientists compared the two groups and saw that the leaves of the group exposed to gamma rays had abnormal shapes and colors. The weights of the plants also differed; the rye plants in the gamma-ray group weighed 48% less than the regular group, and the weight of the garden cress exposed to gamma rays was 32% lower than their unblasted counterparts. Wamelink suspects the weight difference is due to the gamma rays damaging the plants' proteins and DNA. The results were published in the journal Frontiers in Astronomy and Space Sciences this month.

Michael Dixon, who studies agriculture at the University of Guelph in Canada and wasn't involved in the study, said this research did a reasonable job replicating the cosmic radiation considering that it's impossible to copy it perfectly. Ultimately, researchers would need to study plants on the Martian surface to get a full understanding of the impacts.

Dixon is a part of a team that's planning to attempt to grow barley on the Moon, which should happen in the next ten years, he said. One of the first questions that Dixon and his co-workers plan to study is whether or not plants can survive the exposure to lunar radiation.

Wamelink said space agencies should step up their research into crops to improve the quality of the food that astronauts eat. "People at ISS [International Space Station] still eat astronaut food. And that's not very nice," Wamelink said. "I don't know if you ever tasted it, but, well, you don't get happy from it."

Researching space farming and food production is "way more important than some people think," he said. "Radiation is a problem, but it's solvable, I think."


Recommend this post and follow
Sputnik's Orbit



Posted by PlantPartnerChuck

Saturday, August 21, 2021

Under the northern lights: Mesospheric ozone layer depletion explained

AUGUST 20, 2021, by Nagoya University

In geospace, the Arase satellite observes chorus waves and energetic electrons, while on the ground, EISCAT and optical instruments observe pulsating aurorae and electron precipitation in the mesosphere.
 Credit: ERG science team

The same phenomenon that causes aurorae—the magical curtains of green light often visible from the polar regions of the Earth—causes mesospheric ozone layer depletion. This depletion could have significance for global climate change and therefore, understanding this phenomenon is important.

Now, a group of scientists led by Prof. Yoshizumi Miyoshi from Nagoya University, Japan, has observed, analyzed, and provided greater insight into this phenomenon. The findings are published in Nature's Scientific Reports.

In the Earth's magnetosphere—the region of magnetic field around the Earth—electrons from the sun remain trapped. Interactions between electrons and plasma waves can cause the trapped electrons to escape and enter the Earth's upper atmosphere (thermosphere). This phenomenon, called electron precipitation, is responsible for aurorae. But, recent studies show that this is also responsible for local ozone layer depletions in the mesosphere (lower than thermosphere) and may have a certain impact on our climate.

What's more, this ozone depletion at the mesosphere could be occurring specifically during aurorae. And while scientists have studied electron precipitation in relation to aurorae, none have been able to sufficiently elucidate how it causes mesospheric ozone depletion.

Prof. Miyoshi and team took the opportunity to change this narrative during a moderate geomagnetic storm over the Scandinavian Peninsula in 2017. They aimed their observations at "pulsating aurorae" (PsA), a type of faint aurora. Their observations were possible through coordinated experiments with the European Incoherent Scatter (EISCAT) radar (at an altitude between 60 and 120 km where the PsA occurs), the Japanese spacecraft Arase, and the all-sky camera network.

Arase data showed that the trapped electrons in the Earth's magnetosphere have a wide energy range. It also indicated the presence of chorus waves, a type of electromagnetic plasma wave, in that region of space. Computer simulations then showed that Arase had observed plasma waves causing precipitations of these electrons across the wide energy range, which is consistent with EISCAT observations down in the Earth's thermosphere.

Analysis of EISCAT data showed that electrons of a wide energy range, from a few keV (kilo electron volts) to MeV (mega electron volts), precipitate to cause PsA. These electrons carry enough energy to penetrate our atmosphere to lower than 100 km, up to an ~60 km altitude, where mesospheric ozone lies. In fact, computer simulations using EISCAT data showed that these electrons immediately deplete the local ozone in the mesosphere (by more than 10%) upon hitting it.

Prof. Miyoshi explains, "PsAs occur almost daily, are spread over large areas, and last for hours. Therefore, the ozone depletion from these events could be significant." Speaking of the greater significance of these findings, Prof. Miyoshi continues: "This is only a case study. Further statistical studies are needed to confirm how much ozone destruction occurs in the middle atmosphere because of electron precipitation. After all, the impact of this phenomenon on the climate could potentially impact modern life."



Recommend this post and follow
Sputnik's Orbit






Posted by Chuck charge

Friday, August 20, 2021

Can small modular reactors mitigate climate change?

AUGUST 18, 2021, by SciDev.Net

Research and development on small modular reactors and advanced reactors. Nuclear power is proposed as a greener alternative to fossil fuels.
 Credit: Canadian Nuclear Laboratories (https://flickr.com/photos/cnl_lnc/50827837168/), CC BY-NC-ND 2.0 (https://creativecommons.org/licenses/by-nd/2.0/)

As the world grapples with a climate emergency brought on by carbon emissions from the large-scale burning of fossil fuels, there is renewed interest in nuclear energy, specifically in the new generation of small modular reactors.

The UN Intergovernmental Panel on Climate Change (IPCC) forecast in its Sixth Assessment Report, released 9 August, that global average air temperatures may rise by more than 1.5 degrees Celsius over pre-industrial levels by 2040. The latest report brings new urgency to cut emissions drastically.

Under the 2015 Paris Agreement all countries are required to set targets to help stay within the 1.5 degrees Celsius limit and work towards a carbon-neutral goal by finding alternatives to coal, oil, natural gas and other fossil fuels.

Of the many alternatives, small modular reactors—defined by the International Atomic Energy Association as nuclear reactors that are 300 megawatts or less in capacity (conventional reactors produce 1,000 megawatts or more) – win out for having minimal environmental footprint. They also take up far less space than conventional power plants or wind and solar farms that produce renewable energy.

Nanda Kumar Janardhanan, who teaches energy studies at the Jawaharlal Nehru University, New Delhi, and operations coordinator in South Asia for the Institute for Global Environmental Strategies, Japan, says that "unlike conventional large nuclear power facilities, which can take a decade or more to build and become operational, small reactors can be ready in a fraction of that time" as they are small enough to be manufactured in a factory and transported to the operating site.

"Countries that need clean energy supply can possibly use small modular reactors as an alternative to depending on environmentally damaging thermal power. This is one of the direct benefits that it offers towards climate mitigation," Janardhanan says. As the demand for hydrogen as a fuel for transportation and industry grows, small modular reactors could also provide the energy needed to generate hydrogen, he adds.

"Despite these advantages, the wider usage of small modular reactors will demand a transformative change in safety measures so as to build public confidence and gain acceptance," says Janardhanan, referring to disasters like Chernobyl and Fukushima "which have led to anti-nuclear perceptions among certain societies or people."

Nuclear industry role

Nuclear power offers an opportunity to advance towards the Paris Agreement goals, says the World Nuclear Association (WNA). A white paper released on 27 May by the WNA suggests that the fear of risks associated with nuclear power have led to acceptance of fossil fuels despite causing millions of premature deaths from air pollution and contributed to climate change.

Reacting to the IPCC's sixth assessment report, WNA director-general Sama Bilbao y León, reiterated demands in the white paper that governments, regulators and industry work together to accelerate deployment of new nuclear projects, including small modular reactors, to help rapid decarbonisation.

Karthik Ganesan, fellow and director of research at the Council on Energy, Environment and Water in New Delhi, says Asia is one region where nuclear power capacity is increasing. "Developing Asia (China, India) and developed Asia (Korea and Japan), which already manage large civilian nuclear programs, must remain invested in small modular reactor technology," says Ganesan.

"But for the small modular reactors concept to succeed in Asia, it must satisfy the primary requirements of increased safety, simplicity in construction and operation and be comparable in economic terms with conventional nuclear power plants," says Ganesan.

Other top experts are less sanguine about the prospects for small modular reactors playing a significant role in decarbonisation over the next decade.

"Humanity does not have the time to invest in small modular reactors—the climate problem is urgent," says M. V. Ramana, a physicist at the Nuclear Futures Laboratory, Princeton University, who works on nuclear power in the context of climate change and nuclear disarmament.

"Entire supply chains would need to be established after the first small modular reactors have been built, tested, and proven," Ramana tells SciDev.Net. "There is no realistic prospect that it can make a significant dent in the need to transition rapidly to a carbon-free electricity system."

In a paper published in July in the Bulletin of the Atomic Scientists, Ramana argues that nuclear power reactors that generate enough electricity to contribute to climate mitigation will need complex technologies to control the reactions and deal with products of radioactive fission.

Proliferation risks

Ramana is also concerned that since small and medium reactor projects typically involve clusters of several small reactor modules, there is a heightened risk of nuclear proliferation.

"Every reactor is a potential source of plutonium or enriched uranium or both—the more the number of nuclear reactors, the more the potential to make nuclear weapons. Anyone with access to these materials is that much closer to a nuclear weapon," he says.

Like their larger counterparts, small modular reactors will also produce radioactive nuclear waste, the safe disposal of which is yet to be resolved satisfactorily. Ramana's paper says that the 1982 Nuclear Waste Policy Act in the US envisaged deep geological burial by 1998 but the US government continues to pay billions of dollars in fines for failing to take charge of spent fuel.

Such concerns have not stopped the development of small modular reactors. According to the International Atomic Energy Agency (IAEA), over 70 SMR designs are either under construction or being developed in 18 countries.

The world's first small modular reactor plant, located in Russia's remote Chukotka region, has been operational since 2019 December, while Argentina is developing a 25-megawatt plant, intended for small grids, according to IAEA. A small modular reactor plant in China's Shidao Bay is slated to begin operation in 2021.

India, which has an advanced nuclear power program with an installed capacity of 7,480 megawatts, has plans to develop small modular reactors partly based on its vast reserves of thorium, according to Sunil Ganju, a member of the nuclear controls and planning wing of India's Department of Atomic Energy.

Speaking at a February webinar on small modular reactors, organized by the India Energy Forum, Ganju said a 500-megawatt "protype fast breeder reactor" being developed at Kalpakkam, Tamil Nadu state, could be classified as a small reactor.

According to Janardhanan, the advantage of nuclear power is that it is a mature technology with a proven history of investment of millions of research hours. "The fact that there is hardly any other mature technology available makes it important for clean energy supply."


Recommend this post and follow
Sputnik's Orbit







Posted by nuclear Chuck