Galaxy-Sun-Earth Connection | Page 3 of 14 | Science Of Cycles News and Research

(NEW) Cosmic Ray Radiation Increasing in Earth’s Atmosphere to Its Core

This article as well as one I published on October 22nd titled: Cosmic Ray Particles That Tunnel Through Earth , tell the story of how legitimate research makes its way through the enormous pressure of peer review, ridicule, occasional self-questioning – and perhaps most of all, the 50-50 possibility that I will not get credit for my presented hypotheses first published in 2012.

My last point presented does indeed reflect ego, can’t sidestep this certitude, however they do tell me there is such a thing as ‘healthy ego’; so I hope my analogy reflects such. The facts have been provided in published papers and in two of my books “Solar Rain; The Earth Changes Have Begun” (2005) and “Global Warming; A Convenient Disguise” (2007).

You might remember my mentioning the term “space weather” – and perhaps more importantly – as it is defined today, began in the late 1990’s when both Mitch Battros and Tony Phillips (NASA contractor) launched our websites in 1997. My original site was www.earthchangestv.com and his is www.spaceweather.com. The Wayback Machine records indicate we both launched our site at the same time….December 1998. However, I know we both set up in 1997 and it may be that the Wayback Machine did not start recording until 1998.

Before my research and hypothesis was published, scientific disciplines spoke in terms of ‘climate’ which is measured in decades, centuries, and millennium. My studies highlighted the fact that symbiotic casual interaction perpetrated by various forms of charged particles. The actions and reactions of these storms would occur within minutes, hours, and days. This form of interaction is known as “weather.” Hence, space weather was born…..

The research below addresses the region of the United States; however, similar findings have been noted around the world except for one region. It is an area known as the South Atlantic Anomaly. A region that worries scientists at the moment is the South Atlantic Anomaly – a vast area stretching from Chile to Zimbabwe.

Here, the magnetic field is so weak that it is dangerous for the Earth’s satellites to pass through it because the high cosmic radiation in this area can destroy the electronics. Now a team of American researchers has found a possible reason for this anomaly, which, among other things, can pave the way for a better understanding of the weakening and reversal of magnetic poles.

High-altitude balloon flights conducted show that atmospheric radiation is intensifying from coast to coast over the USA, which would appear counter-intuitive as it directly corresponds with a decrease in solar activity during a cycles solar minimum.

Since 2015, we have been monitoring X-rays, gamma-rays and neutrons in the stratosphere, mainly over central California, but also in a dozen other states (NV, OR, WA, ID, WY, KS, NE, MO, IL, ME, NH, VT). Everywhere we have been there is an upward trend in radiation–ranging from +20% in central California to +33% in Maine. The latest points circled in red, were gathered during a ballooning campaign in August-October 2018.

How does Solar Minimum boost radiation? The answer lies in the yin-yang relationship between cosmic rays and solar activity. Cosmic rays are the subatomic debris of exploding stars and other violent events. Normally, the Sun’s magnetic field and solar wind hold cosmic rays at bay, however, during Solar Minimum these defenses weaken allowing a flood of galactic cosmic rays into the solar system.

Cosmic rays crashing into our plane’s atmosphere produce a spray of secondary particles and photons. That secondary spray is what we measure. Each balloon flight, which typically reaches an altitude greater than 100,00o feet, gives us a complete profile of radiation from ground level to the stratosphere. Our sensors sample energies between 10 keV and 20 MeV, spanning the range of medical X-ray machines, airport security devices, and “killer electrons” in Earth’s radiation belts.

Cosmic radiation at aviation altitudes is typically 50 times that of natural sources at sea level. Pilots are classified as occupational radiation workers by the International Commission on Radiological Protection (ICRP) and, according to a recent study from researchers at the Harvard School of Public Health, flight attendants face an elevated risk of cancer compared to members of the general population.

They listed cosmic rays as one of several risk factors. Weather and climate may also be affected, with some research linking cosmic rays to to the formation of clouds and lightning. Finally, there are studies (one recently published in Nature) asserting that heart rate variability and cardiac arrhythmia are affected by cosmic rays in some populations. If true, it means the effects reach all the way to the ground.

Comet Tails Blowing In The Solar Wind

Engineers and scientists gathered around a screen in an operations room at the Naval Research Laboratory in Washington, D.C., eager to lay their eyes on the first data from NASA’s STEREO spacecraft. It was January 2007, and the twin STEREO satellites — short for Solar and Terrestrial Relations Observatory — which had launched just months before, were opening their instruments’ eyes for the first time. First up: STEREO-B. The screen blinked, but instead of the vast starfield they expected, a pearly white, feathery smear — like an angel’s wing — filled the frame. For a few panicky minutes, NRL astrophysicist Karl Battams worried something was wrong with the telescope. Then, he realized this bright object wasn’t a defect, but an apparition, and these were the first satellite images of Comet McNaught. Later that day, STEREO-A would return similar observations.

Comet C/2006 P1 — also known as Comet McNaught, named for astronomer Robert McNaught, who discovered it in August 2006 — was one of the brightest comets visible from Earth in the past 50 years. Throughout January 2007, the comet fanned across the Southern Hemisphere’s sky, so bright it was visible to the naked eye even during the day. McNaught belongs to a rarefied group of comets, dubbed the Great Comets and known for their exceptional brightness. Setting McNaught apart further still from its peers, however, was its highly structured tail, composed of many distinct dust bands called striae, or striations, that stretched more than 100 million miles behind the comet, longer than the distance between Earth and the Sun. One month later, in February 2007, an ESA (European Space Agency) and NASA spacecraft called Ulysses would encounter the comet’s long tail.

“McNaught was a huge deal when it came because it was so ridiculously bright and beautiful in the sky,” Battams said. “It had these striae — dusty fingers that extended across a huge expanse of the sky. Structurally, it’s one of the most beautiful comets we’ve seen for decades.”

How exactly the tail broke up in this manner, scientists didn’t know. It called to mind reports of another storied comet from long ago: the Great Comet of 1744, which was said to have dramatically fanned out in six tails over the horizon, a phenomenon astronomers then couldn’t explain. By untangling the mystery of McNaught’s tail, scientists hoped to learn something new about the nature of comets — and solve two cosmic mysteries in one.

A key difference between studying comets in 1744 and 2007 is, of course, our ability to do so from space. In addition to STEREO’s serendipitous sighting, another mission, ESA/NASA’s SOHO — the Solar and Heliospheric Observatory — made regular observations as McNaught flew by the Sun. Researchers hoped these images might contain their answers.

Now, years later, Oliver Price, a planetary science Ph.D. student at University College London’s Mullard Space Science Laboratory in the United Kingdom, has developed a new image-processing technique to mine through the wealth of data. Price’s findings — summarized in a recently published Icarus paper — offer the first observations of striations forming, and an unexpected revelation about the Sun’s effect on comet dust.

Comets are cosmic crumbs of frozen gas, rock and dust left over from the formation of our solar system 4.6 billion years ago — and so they may contain important clues about our solar system’s early history. Those clues are unlocked, as if from a time capsule, every time a comet’s elliptical orbit brings it close to the Sun. Intense heat vaporizes the frozen gases and releases the dust within, which streams behind the comet, forming two distinct tails: an ion tail carried by the solar wind — the constant flow of charged particles from the Sun — and a dust tail.

Understanding how dust behaves in the tail — how it fragments and clumps together — can teach scientists a great deal about similar processes that formed dust into asteroids, moons and even planets all those billions of years ago. Appearing as one of the biggest and most structurally complex comets in recent history, McNaught was a particularly good subject for this type of study. Its brightness and high dust production made it much easier to resolve the evolution of fine structures in its dust tail.

Price began his study focusing on something the scientists couldn’t explain. “My supervisor and I noticed weird goings-on in the images of these striations, a disruption in the otherwise clean lines,” he said. “I set out to investigate what might have happened to create this weird effect.”

The rift seemed to be located at the heliospheric current sheet, a boundary where the magnetic orientation, or polarity, of the electrified solar wind changes directions. This puzzled scientists because while they have long known a comet’s ion tail is affected by the solar wind, they had never seen the solar wind impact dust tails before.

Dust in McNaught’s tail — roughly the size of cigarette smoke — is too heavy, the scientists thought, for the solar wind to push around. On the other hand, an ion tail’s miniscule, electrically charged ions and electrons easily sail along the solar wind. But it was difficult to tell exactly what was going on with McNaught’s dust, and where, because at roughly 60 miles per second, the comet was rapidly traveling in and out of STEREO and SOHO’s view.

“We got really good data sets with this comet, but they were from different cameras on different spacecraft, which are all in different places,” Price said. “I was looking for a way to bring it all together to get a complete picture of what’s happening in the tail.”

His solution was a novel image-processing technique that compiles all the data from different spacecraft using a simulation of the tail, where the location of each tiny speck of dust is mapped by solar conditions and physical characteristics like its size and age, or how long it’d been since it’d flown off the head, or coma, of the comet. The end result is what Price dubbed a temporal map, which layers information from all the images taken at any given moment, allowing him to follow the dust’s movements.

The temporal maps meant Price could watch the striations form over time. His videos, which cover the span of two weeks, are the first to track the formation and evolution of these structures, showing how dust fragments topple off the comet head and collapse into long striations.

But the researchers were most excited to find that Price’s maps made it easier to explain the strange effect that drew their attention to the data in the first place. Indeed, the current sheet was the culprit behind the disruptions in the dust tail, breaking up each striation’s smooth, distinct lines. For the two days it took the full length of the comet to traverse the current sheet, whenever dust encountered the changing magnetic conditions there, it was jolted out of position, as if crossing some cosmic speed bump.

“It’s like the striation’s feathers are ruffled when it crosses the current sheet,” University College London planetary scientist Geraint Jones said. “If you picture a wing with lots of feathers, as the wing crosses the sheet, lighter ends of the feathers get bent out of shape. For us, this is strong evidence that the dust is electrically charged, and that the solar wind is affecting the motion of that dust.”

Scientists have long known the solar wind affects charged dust; missions like Galileo Cassini, and Ulysses watched it move electrically charged dust through the space near Jupiter and Saturn. But it was a surprise for them to see the solar wind affect larger dust grains like those in McNaught’s tail — about 100 times bigger than the dust seen ejected from around Jupiter and Saturn — because they’re that much heavier for the solar wind to push around.

With this study, scientists gain new insights into long-held mysteries. The work sheds light on the nature of striated comet tails from the past and provides a crucial lens for studying other comets in the future. But it also opens a new line of questioning: What role did the Sun have in our solar system’s formation and early history?

“Now that we see the solar wind changed the position of dust grains in McNaught’s tail, we can ask: Could it have been the case that early on in the solar system’s history, the solar wind played a role in organizing ancient dust as well?” Jones said.

JUST IN: Newly Detected Gamma-Rays From Milky Way

The first-ever detection of highly energetic radiation from a microquasar has astrophysicists scrambling for new theories to explain the extreme particle acceleration. The team’s observations led by Hui Li, Los Alamos National Laboratory’s Theoretical Division says; “”What’s amazing about this discovery is that all current particle acceleration theories have difficulties explaining the observations.”

A microquasar is a black hole that gobbles up debris from a nearby companion star and blasts out powerful jets of material. The team’s observations, described in the Oct. 4 issue of the journal Nature, strongly suggest that particle collisions at the ends of the microquasar’s jets produced the powerful gamma rays. Scientists think that studying messages from this microquasar, dubbed SS 433, may offer a glimpse into more extreme events happening at the centers of distant galaxies.

The team gathered data from the High-Altitude Water Cherenkov Gamma-Ray Observatory (HAWC), which is a mountain-top detector in Mexico that observes gamma ray emission from supernova remnants, rotating dense stars called pulsars, and quasars. Los Alamos, funded by Department of Energy Office of High-Energy Physics, helped build HAWC, which was completed in 2015.

Based on their analysis, the researchers concluded that electrons in the jets attain energies that are about 1,000 times higher than can be achieved using earth-bound particle accelerators, such as the Large Hadron Collider. The jet electrons collide with the low-energy microwave background radiation that permeates space, resulting in gamma ray emission. This is a newly observed mechanism for getting high-energy gamma rays out of this kind of system and is different from what scientists have observed when the jets are aimed at Earth.

___________________

Alexa’s and Sophia’s Kids Heart Challenge Fundraiser (American Heart Association)

At my school, I’m learning how I can help make a difference by raising lifesaving donations to help kids with heart disease. I’m also learning about my own heart, and how to keep it healthy. And I’m getting active!

I’m excited about raising money for other kids – kids with hearts that don’t exactly work right and to help fund new medicines and treatments to be discovered. Please help me make a difference! Thank you!

Alexa’s Link: http://bit.ly/2y1xSV5

Sophia’s Link: http://bit.ly/2PgnhfK

Unstoppable Monster In The Early Universe

Astronomers obtained the most detailed anatomy chart of a monster galaxy located 12.4 billion light-years away. Using the Atacama Large Millimeter/submillimeter Array (ALMA), the team revealed that the molecular clouds in the galaxy are highly unstable, which leads to runaway star formation. Monster galaxies are thought to be the ancestors of the huge elliptical galaxies in today’s universe, therefore these findings pave the way to understand the formation and evolution of such galaxies.

“One of the best parts of ALMA observations is to see the far-away galaxies with unprecedented resolution,” says Ken-ichi Tadaki, a postdoctoral researcher at the Japan Society for the Promotion of Science and the National Astronomical Observatory of Japan, the lead author of the research paper published in the journal Nature.

Monster galaxies, or starburst galaxies, form stars at a startling pace; 1000 times higher than the star formation in our Galaxy. But why are they so active? To tackle this problem, researchers need to know the environment around the stellar nurseries. Drawing detailed maps of molecular clouds is an important step to scout a cosmic monster.

Tadaki and the team targeted a chimerical galaxy COSMOS-AzTEC-1. This galaxy was first discovered with the James Clerk Maxwell Telescope in Hawai`i, and later the Large Millimeter Telescope (LMT) in Mexico found an enormous amount of carbon monoxide gas in the galaxy and revealed its hidden starburst. The LMT observations also measured the distance to the galaxy, and found that it is 12.4 billion light-years (Note).

Researchers have found that COSMOS-AzTEC-1 is rich with the ingredients of stars, but it was still difficult to figure out the nature of the cosmic gas in the galaxy. The team utilized the high resolution and high sensitivity of ALMA to observe this monster galaxy and obtain a detailed map of the distribution and the motion of the gas. Thanks to the most extended ALMA antenna configuration of 16 km, this is the highest resolution molecular gas map of a distant monster galaxy ever made.

“We found that there are two distinct large clouds several thousand light-years away from the center,” explains Tadaki. “In most distant starburst galaxies, stars are actively formed in the center. So it is surprising to find off-center clouds.”

The astronomers further investigated the nature of the gas in COSMOS-AzTEC-1 and found that the clouds throughout the galaxy are very unstable, which is unusual. In a normal situation, the inward gravity and outward pressure are balanced in the clouds. Once gravity overcomes pressure, the gas cloud collapses and forms stars at a rapid pace. Then, stars and supernova explosions at the end of the stellar life cycle blast out gases, which increase the outward pressure. As a result, the gravity and pressure reach a balanced state and star formation continues at a moderate pace. In this way star formation in galaxies is self-regulating. But, in COSMOS-AzTEC-1, the pressure is far weaker than the gravity and hard to balance. Therefore this galaxy shows runaway star formation and has morphed into an unstoppable monster galaxy.

The team estimated that the gas in COSMOS-AzTEC-1 will be completely consumed in 100 million years, which is 10 times faster than in other star forming galaxies.

But why is the gas in COSMOS-AzTEC-1 so unstable? Researchers do not have a definitive answer yet, but galaxy merger is a possible cause. Galaxy collision may have efficiently transported the gas into a small area and ignited intense star formation.

“At this moment, we have no evidence of merger in this galaxy. By observing other similar galaxies with ALMA, we want to unveil the relation between galaxy mergers and monster galaxies,” summarizes Tadaki.

JUST IN: Another ‘Bingo’ for Science Of Cycles Research, New Study Shows Rhythmic Oscillation of Charged Particles

In an article I published on August 18th which was Part I of a three part series, I made the following statement. “As we gain increased knowledge of the when-where-how of various charged particles, which encompasses such things as Black Holes, Supernovas, Gamma Ray Blasts, and Coronal Mass Ejections – we develop a cognizance lending itself to a measure of predictability. As a naturally directed outcome of evolving research – it is the “Science Of Cycles” which takes us to the next level of aptitude which could very well bring us to the cusp of an extraterrestrial neighborhood.” Article Here

Now, in a new discovery just published reported in a paper published at Cornell University arXiv Library, the ‘science of cycles’ has made a significant leap. Astronomers have detected transient ‘rhythmic oscillations’ in the gamma-ray emission from the blazar Markarian 501. In general, blazars are perceived by astronomers as high-energy engines serving as natural laboratories to study particle acceleration, relativistic plasma processes, magnetic field dynamics and black hole physics. Rhythmic; movement or procedure with uniform or pattern, and Oscillation; source that repeatedly and regularly fluctuates.

A group of astronomers led by Gopal Bhatta of the Astronomical Observatory of the Jagiellonian University in Kraków, Poland, has analyzed the observational data of Mrk 501 collected by the Large Area Telescope (LAT) of NASA’s Fermi Gamma-ray Space Telescope, between August 2008 and June 2018. The study resulted in the detection of rhythmic oscillations in the blazar’s gamma-ray emission.

**Science Of Cycles keeps you tuned-in and knowledgeable of what we are discovering, and how some of these changes will affect our communities and ways of living. CLICK HERE

Blazars, are classified as active galaxies that host active galactic nuclei (AGN). Their characteristic features are relativistic jets pointed almost exactly toward the Earth. In general, blazars are perceived by astronomers as high-energy engines serving as natural laboratories to study particle acceleration, relativistic plasma processes, magnetic field dynamics and black hole physics.

Located some 456 million light-years away, Markarian 501 (or Mrk 501 for short) is a blazar with a spectrum extending to the highest energy gamma rays. It is one of the nearest blazars that shines bright in the X-ray and one of the earliest extragalactic sources detected in the TeV band. According to the study, astronomers found a strong signal of quasi-periodic oscillation (QPO) with a periodicity of around 332 days. They added that the gamma-ray flux modulation in this blazar gradually decayed in strength during the recent years.

The study presents several hypotheses about what could be the driving force behind such rhythmic oscillations in Mrk 501. The research team suggest various scenarios, including supermassive binary black holes, jet precession and accretion disk precessing under gravitational torque. Additionally, the researchers concluded that further analysis of Mrk 501 and discussion on the topic are needed in order to definitely determine the most plausible theory explaining the origin of the oscillations in this blazar.

__________________

Science Of Cycles Research Fund

Keep Us Going: Science Of Cycles keeps you tuned in and knowledgeable of what we are discovering, and how some of these changes will affect our communities and ways of living.

Part III (con’t) Cosmic Rays and There Effect to Our Solar System and Earth

The origin of ultrahigh-energy cosmic rays (UHECRs) is a half-century-old enigma. The mystery has been deepened by an intriguing coincidence: over ten orders of magnitude in energy, the energy generation rates of UHECRs, PeV neutrinos and isotropic sub-TeV gamma-rays are comparable, which hints at a grand unified picture.

Here we report that powerful black hole jets in aggregates of galaxies can supply the common origin for all of these phenomena. Once accelerated by a jet, low-energy cosmic rays confined in the radio lobe are adiabatically cooled; higher-energy cosmic rays leaving the source interact with the magnetized cluster environment and produce neutrinos and gamma-rays.

The highest-energy particles escape from the host cluster and contribute to the observed cosmic rays above 100 PeV. The model is consistent with the spectrum, composition and isotropy of the observed UHECRs, and also explains the IceCube neutrinos and the non-blazar component of the Fermi gamma-ray background, assuming a reasonable energy output from black hole jets in clusters.

__________________

Science Of Cycles Research Fund

Science Of Cycles keeps you tuned in and knowledgeable of what we are discovering, and how some of these changes will affect our communities and ways of living.

I Am Excited to be Back; and For More Than One Reason

Hello ‘Science Of Cycles’ patrons. I’m coming off a surgery to remove a large tumor from my upper leg. What would have been a mostly unenthusiastic surgery, took a turn with a false-positive biopsy. As you have probably surmised, the final result is a benign and known as Lipoma. However, not all Lipoma’s are the same. They usually do not exhibit pain, of course mine did; and they usually grow at a very slow pace, mine seem to be in a hurry.

It appears the lump was entangled in muscle which was the cause of pain. As for the apparent faster than usual growth, it seems to have something to do with muscle entanglement. So to end this somewhat morbid explanation to my absence of articles, I am now resting reasonable well – and most importantly, able to return to my research and of bringing you the latest cutting edge news in the fields of Earth Science, Space Weather, and AstroPhysics which in fact affirms almost on a daily basis, the defining a symbiotic connection with our galaxy and universe. To date, the element which connects our little home to the seemingly vast universe is ‘charged particles’.

Science Of Cycles Research Fund

Piggy Bank is empty…need your support as always to keep this machine running. I think you know I love what I do, but what’s really rewarding is when it loves me back. I attribute my thoughts to that of a healthy marriage. To give a hundred percent is a good thing, but many of us who are married, add a bit more if you have kids, have realized that sometimes a hundred percent is not enough. This is to say, even on those times you are absolutely right, it’s better to let your partner be right too.

To Support SOC – Click Here

As we gain increased knowledge of the when-where-how of various charged particles, which encompasses such things as Black Holes, Supernovas, Gamma Ray Blasts, and Coronal Mass Ejections – we develop a cognizance lending itself to a measure of predictability. As a naturally directed outcome of evolving research – it is the “Science Of Cycles” which takes us to the next level of aptitude which could very well bring us to the cusp of an extraterrestrial neighborhood.

ps, I should mention one of the shortcomings of my healing process, is a curtailed period on the keyboard. Hence, moving on, and expect a Part II and most likely a Part III to this and coming articles.

There has been a whirlwind of activity over the last few weeks. The July 27th 2018 total lunar eclipse was visible in large parts of Australia, Asia, Africa, Europe, and South America. Totality lasted for 103 minutes, making it the longest eclipse of the 21st century. Then, on August 11th a partial solar eclipse was visible from northern and Eastern Europe, northern parts of North America, and some northern and western locations in Asia, making it the most watched solar eclipse of 2018.

In Part II of this article, I will cover the 14 day prior and 14 day post events of July 27th total Lunar Eclipse, and the August 11th Partial Solar Eclipse – both of which my research has been able to identify a connection to significant earth changing events during these windows of opportunity. Events such as earthquakes, volcanoes, and extreme weather are among those which I will outline. Some outcomes are related to gravity, others with rapid temperature flux, and yet others with fluid displacement.

In Part III will encompass the incredible discoveries as it relates to Cosmic Rays, one of which is the identification of a ultra-high-energy cosmic ray, now labeled as the “OMG Particle”. Also, new information indicating a 30% increase of cosmic rays entering Earth’s atmosphere.

I hope this article refreshes your memory and enthusiasm that you can only find right here at ‘Science Of Cycles’ research and news service.

Stay Tuned…………

Support Science Of Cycles News and Research