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Dr. MercolaThe US government has finally admitted they’ve overdosed Americans on fluoride and, for first time since 1962, are lowering its recommended level of fluoride in drinking water.1,2,3About 40 percent of American teens have dental fluorosis,4 a condition referring to changes in the appearance of tooth enamel—from chalky-looking lines and splotches to dark staining and pitting—caused by long-term ingestion of fluoride during the time teeth are forming.In some areas, fluoro [...]
by G. William DomhoffNOTE: WhoRulesAmerica.net is largely based on my book,Who Rules America?, first published in 1967 and now in its7th edition. This on-line document is presented as a summary of some of the main ideas in that book.Who has predominant power in the United States? The short answer, from 1776 to the present, is: Those who have the money -- or more specifically, who own income-producing land and businesses -- have the power. George Washington was one of the biggest landowner [...]
Ethan Indigo Smith, ContributorThe recent “news” on the nuclear situation in Iran brings to light the madhouse of cards on which the postmodern world is built. Or rather, it would bring the madness to light if the major media outlets of the world were not bought up and sold out to the military industrial complex, and therefore completely misinformed on the actions and dangers of the nuclear experimentation industry.The story is not just about [...]
Excerpt from ancient-origins.net
Did an ancient meteor have such a life-changing impact on witnesses of the day that it shaped a religion and altered the course of history? Astronomers theorize that the dramatic flash and boom that converted Paul the Apostle may have been an exploding meteor.
In the Christian Bible, it is written that a man named Saul experienced an event so extreme that it changed his views in an instant, and he became one of the most influential evangelists in early Christianity.
Saul was said to have been a vehement persecutor of the followers of Jesus and was traveling in search of disciples of Jesus for punishment. It is written in the fifth book of the New Testament, Acts of the Apostles, that Saul was on the road to Damascus, Syria, when a bright light appeared in the sky. So intense was the light that he was blinded for three days. What he heard was described as a great thunderous sound, or a divine voice. He and his companions are said to have been knocked to the ground by the force of the event. The experience was so profound that Saul changed his name to Paul, took up missionary journeys across the Mediterranean, and became instrumental in spreading Christianity.
William Hartmann, co-founder of the Planetary Science Institute in the U.S. has connected Paul’s experience with similar accounts of exploding meteors, such as the well-recorded Chelyabinsk meteor which broke up over Russia in 2013, injuring over 1,500 people. The eyewitness descriptions and physical reactions to meteors or fireballs in the sky seem to parallel what is recorded about Paul.
If true, then it’s possible that an act of nature may have been contributory in the spread and evolution of Christianity in its early days, and therefore shaped the course of history.
In a study published in the journal Meteoritics and Planetary Science, Hartmann cites major events like the meteors or asteroids over Chelyabinsk, Russia and Tunguska, Siberia as offering “opportunities to compare reactions of modern eyewitnesses to eyewitness accounts of possible ancient fireball events.” There are consistencies among the many accounts suggesting the biblical descriptions of Paul’s experience closely match known modern events, reports NewScientist.
In the biblical accounts, Paul was blinded for three days due to the intense light from the sky; it was “brighter than the sun, shining round me,” according to the text. This matches the Chelyabinsk meteor, as it was calculated to be shining around three times as bright as the sun. The blazing fireball made shadows move around the ground as it travelled.
Paul and his companions were said to have been knocked to the earth, and this also corresponds to the shockwave generated by the powerful Chelyabinsk meteor as it blasted out windows, knocked people off their feet, shook cars and buildings, and collapsed roofs.
The divine voice is said to have either boomed like thunder, or questioned Paul’s behavior (the exact sound is debated). Meteors create great, explosive booms and roars which can be scary or painful even for those who know what they’re experiencing.
To the ancients the incredible and unfamiliar natural celestial events were interpreted through cultural understandings of the day – which is to say, they were considered divine or damning.
The Chelyabinsk meteor gave off small amounts of radiation, enough to cause sunburn and temporary blindness in witnesses. Harmann suggests that Paul could have suffered photokeratitis, a temporary blindness from intense ultraviolet radiation, and this explains the return of his sight after healing.
Hartmann told NewScientist, “Everything they are describing in those three accounts in the book of Acts are exactly the sequence you see with a fireball.”
IBTimes writes that the Acts of Apostles text describes three events of bright lights “from heaven” which took place around Damascus during the 30s B.C. If meteorites can be found in Syria, and accurately dated to the relevant timeframes, it might give support to the published theories.
Hartmann’s research aim is not to discredit Christianity, but to demonstrate how the interpretation of ancient events may have shaped how we exist today, spiritually and culturally.
This wouldn’t be the first meteorite in history to have potentially inspired worship or acted as an agent of change. In antiquity meteorites were seen as messages from the gods, or profound omens, and many cultures saw fallen meteorites as religious icons to be worshiped or as objects of protection. Jewelry and art has also been created from the space rocks.
Each year devout Muslims make the pilgrimage to Mecca in Saudi Arabia, circling the Kaaba, or black stone, and give a nod or a kiss to the meteorite that is said to rest inside the Grand Mosque. The worship of the Black Stone goes back to pre-Islamic shrines, when Semitic cultures used unusual stones to signify sites of reverence. According to Muslim belief, the stone originates from the time of Adam and the Islamic prophet Muhammad set the Black Stone in place after it fell from the skies.
In the Christian Bible, it is written that a man named Saul experienced an event so extreme that it changed his views in an instant, and he became one of the most influential evangelists in early Christianity.
Saul was said to have been a vehement persecutor of the followers of Jesus and was traveling in search of disciples of Jesus for punishment. It is written in the fifth book of the New Testament, Acts of the Apostles, that Saul was on the road to Damascus, Syria, when a bright light appeared in the sky. So intense was the light that he was blinded for three days. What he heard was described as a great thunderous sound, or a divine voice. He and his companions are said to have been knocked to the ground by the force of the event. The experience was so profound that Saul changed his name to Paul, took up missionary journeys across the Mediterranean, and became instrumental in spreading Christianity.
The Conversion of Saint Paul – Paul and his companions are knocked to the ground by a resounding boom and brilliant light. Did a meteor cause this ancient event?
Meteor trail over Chelyabinsk, Russia. Wikimedia Commons
If true, then it’s possible that an act of nature may have been contributory in the spread and evolution of Christianity in its early days, and therefore shaped the course of history.
In a study published in the journal Meteoritics and Planetary Science, Hartmann cites major events like the meteors or asteroids over Chelyabinsk, Russia and Tunguska, Siberia as offering “opportunities to compare reactions of modern eyewitnesses to eyewitness accounts of possible ancient fireball events.” There are consistencies among the many accounts suggesting the biblical descriptions of Paul’s experience closely match known modern events, reports NewScientist.
In the biblical accounts, Paul was blinded for three days due to the intense light from the sky; it was “brighter than the sun, shining round me,” according to the text. This matches the Chelyabinsk meteor, as it was calculated to be shining around three times as bright as the sun. The blazing fireball made shadows move around the ground as it travelled.
Paul and his companions were said to have been knocked to the earth, and this also corresponds to the shockwave generated by the powerful Chelyabinsk meteor as it blasted out windows, knocked people off their feet, shook cars and buildings, and collapsed roofs.
The divine voice is said to have either boomed like thunder, or questioned Paul’s behavior (the exact sound is debated). Meteors create great, explosive booms and roars which can be scary or painful even for those who know what they’re experiencing.
To the ancients the incredible and unfamiliar natural celestial events were interpreted through cultural understandings of the day – which is to say, they were considered divine or damning.
The Chelyabinsk meteor gave off small amounts of radiation, enough to cause sunburn and temporary blindness in witnesses. Harmann suggests that Paul could have suffered photokeratitis, a temporary blindness from intense ultraviolet radiation, and this explains the return of his sight after healing.
Paul having his sight restored after being blinded by a celestial light that might have been a meteor.
Hartmann told NewScientist, “Everything they are describing in those three accounts in the book of Acts are exactly the sequence you see with a fireball.”
IBTimes writes that the Acts of Apostles text describes three events of bright lights “from heaven” which took place around Damascus during the 30s B.C. If meteorites can be found in Syria, and accurately dated to the relevant timeframes, it might give support to the published theories.
Hartmann’s research aim is not to discredit Christianity, but to demonstrate how the interpretation of ancient events may have shaped how we exist today, spiritually and culturally.
This wouldn’t be the first meteorite in history to have potentially inspired worship or acted as an agent of change. In antiquity meteorites were seen as messages from the gods, or profound omens, and many cultures saw fallen meteorites as religious icons to be worshiped or as objects of protection. Jewelry and art has also been created from the space rocks.
Each year devout Muslims make the pilgrimage to Mecca in Saudi Arabia, circling the Kaaba, or black stone, and give a nod or a kiss to the meteorite that is said to rest inside the Grand Mosque. The worship of the Black Stone goes back to pre-Islamic shrines, when Semitic cultures used unusual stones to signify sites of reverence. According to Muslim belief, the stone originates from the time of Adam and the Islamic prophet Muhammad set the Black Stone in place after it fell from the skies.
 |
| A 1315 illustration inspired by the story of Muhammad and the Meccan clan elders lifting the Black Stone into place. Was the black stone a meteor from space? |
In a more modern example, after the dramatic Chelyabinsk event over Russia in 2013, the ‘Church of the Meteorite’ was set up, and the followers hold rites on the shores of Lake Chebarkul where pieces of the space rock fell.
Some scientists regard the Conversion of Paul theory as speculation, but seem to welcome further evidence.
Bill Cooke, head of NASA's Meteoroid Environment Office told NewScientist, “It’s well recorded that extraterrestrial impacts have helped to shape the evolution of life on this planet. If it was a Chelyabinsk fireball that was responsible for Paul’s conversion, then obviously that had a great impact on the growth of Christianity.”
Indeed, “Some scholars call Paul the second founder of Christianity” says Justin Meggitt, religious historian at the University of Cambridge. Without the fireball, and without Paul’s conversion, perhaps Christianity would be different than it is today.
“Christianity probably would be very different without him,” Meggitt concludes.
Illumination from 1450 depicting Paul's conversion – the bright light and sound come from the sky. The event was said to change Paul, and may have changed history. Public Domain
Featured Image: Detail, The Conversion of St. Paul. Paul and companions are knocked to the ground during the profound event. 
“Space is just the construct that gives the illusion that there are separate objects” – Dr. Quantum (see video below)There is a phenomenon so strange, so fascinating, and so counter to what we believe to be the known scientific laws of the universe, that Einstein himself could not wrap his head around it. It’s called “quantum entanglement,” though Einstein referred to it as “spooky action at a distance.”An [...]
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Excerpt from computerworld.com
By Sharon Gaudin
IBM scientists say they have made two critical advances in an industrywide effort to build a practical quantum computer, shaving years off the time expected to have a working system.
"This is critical," said Jay Gambetta, IBM's manager of theory of quantum computing. "The field has got a lot more competitive. You could say the [quantum computing] race is just starting to begin… This is a small step on the journey but it's an important one."
Gambetta told Computerworld that IBM's scientists have created a square quantum bit circuit design, which could be scaled to much larger dimensions. This new two-dimensional design also helped the researchers figure out a way to detect and measure errors.
Quantum computing is a fragile process and can be easily thrown off by vibrations, light and temperature variations. Computer scientists doubt they'll ever get the error rate down to that in a classical computer.
Because of the complexity and sensitivity of quantum computing, scientists need to be able to detect errors, figure out where and why they're happening and prevent them from recurring.
IBM says its advancement takes the first step in that process.
"It tells us what errors are happening," Gambetta said. "As you make the square [circuit design] bigger, you'll get more information so you can see where the error was and you can correct for it. We're showing now that we have the ability to detect, and we're working toward the next step, which would allow you to see where and why the problem is happening so you can stop it from happening."
Quantum computing is widely thought to be the next great step in the field of computing, potentially surpassing classical supercomputers in large-scale, complex calculations.
Quantum computing would be used to cull big data, searching for patterns. It's hoped that these computers will take on questions that would lead to finding cures for cancer or discovering distant planets – jobs that might take today's supercomputers hundreds of years to calculate.
IBM's announcement is significant in the worlds of both computing and physics, where quantum theory first found a foothold.
Quantum computing, still a rather mysterious technology, combines both computing and quantum mechanics, which is one of the most complex, and baffling, areas of physics. This branch of physics evolved out of an effort to explain things that traditional physics is unable to.
For instance, each bit, also known as a qubit, in a quantum machine can be a one and a zero at the same time. When a qubit is built, it can't be predicted whether it will be a one or a zero. A qubit has the possibility of being positive in one calculation and negative in another. Each qubit changes based on its interaction with other qubits.
Because of all of these possibilities, quantum computers don't work like classical computers, which are linear in their calculations. A classical computer performs one step and then another. A quantum machine can calculate all of the possibilities at one time, dramatically speeding up the calculation.
However, that speed will be irrelevant if users can't be sure that the calculations are accurate.
That's where IBM's advances come into play.
"This is absolutely key," said Jim Tully, an analyst with Gartner. "You do the computation but then you need to read the results and know they're accurate. If you can't do that, it's kind of meaningless. Without being able to detect errors, they have no way of knowing if the calculations have any validity."
If scientists can first detect and then correct these errors, it's a major step in the right direction to building a working quantum computing system capable of doing enormous calculations.
"Quantum computing is a hard concept for most to understand, but it holds great promise," said Dan Olds, an analyst with The Gabriel Consulting Group. "If we can tame it, it can compute certain problems orders of magnitude more quickly than existing computers. The more organizations that are working on unlocking the potential of quantum computing, the better. It means that we'll see something real that much sooner."
A year ago, D-Wave Systems Inc. announced that it had built a quantum system, and that NASA, Google and Lockheed Martin had been testing them.
Many in the computer and physics communities doubt that D-Wave has built a real quantum computer. Vern Brownell, CEO of the company, avows that they have.
"I think that quantum computing shows promise, but it's going to be quite a while before we see systems for sale," said Olds.
IBM's Gambetta declined to speculate on whether D-Wave has built a quantum computing but said the industry is still years away from building a viable quantum system.
"Quantum computing could be potentially transformative, enabling us to solve problems that are impossible or impractical to solve today," said Arvind Krishna, senior vice president and director of IBM Research, in a statement.
IBM's research was published in Wednesday's issue of the journal Nature Communications.
| Artist's concept of the black hole. |
Excerpt from finance.yahoo.com
Of all the bizarre quirks of nature, supermassive black holes are some of the most mysterious because they're completely invisible.
But that could soon change.
Black holes are deep wells in the fabric of space-time that eternally trap anything that dares too close, and supermassive black holes have the deepest wells of all. These hollows are generated by extremely dense objects thousands to billions of times more massive than our sun.
Not even light can escape black holes, which means they're invisible to any of the instruments astrophysicists currently use. Although they don't emit light, black holes will, under the right conditions, emit large amounts of gravitational waves — ripples in spacetime that propagate through the universe like ripples across a pond's surface.
And although no one has ever detected a gravitational wave, there are a handful of instruments around the world waiting to catch one.
Game-changing gravitational waves
This illustration shows two spiral galaxies - each with supermassive black holes at their center - as they are about to collide.
Albert Einstein first predicted the existence of gravitational waves in 1916. According to his theory of general relativity, black holes will emit these waves when they accelerate to high speeds, which happens when two black holes encounter one another in the universe.
As two galaxies collide, for example, the supermassive black holes at their centers will also collide. But first, they enter into a deadly cosmic dance where the smaller black hole spirals into the larger black hole, moving increasingly faster as it inches toward it's inevitable doom. As it accelerates, it emits gravitational waves.
Astrophysicists are out to observe these waves generated by two merging black holes with instruments like the Laser Interferometer Gravitational-Wave Observatory.
"The detection of gravitational waves would be a game changer for astronomers in the field," Clifford Will, a distinguished profess of physics at the University of Florida who studied under famed astrophysicist Kip Thorne told Business Insider. "We would be able to test aspects of general relativity that have not been tested."
Because these waves have never been detected, astrophysicists are still trying to figure out how to find them. To do this, they build computer simulations to predict what kinds of gravitational waves a black hole merger will produce.
Learn by listening
In the simulation below, made by Steve Drasco at California Polytechnic State University (also known as Cal Poly), a black hole gets consumed by a supermassive black hole about 30,000 times as heavy.
You'll want to turn up the volume.
What you're seeing and hearing are two different things.
The black lines you're seeing are the orbits of the tiny black hole traced out as it falls into the supermassive black hole. What you're hearing are gravitational waves.
"The motion makes gravitational waves, and you are hearing the waves," Drasco wrote in a blog post describing his work.
Of course, there is no real sound in space, so if you somehow managed to encounter this rare cataclysmic event, you would not likely hear anything. However, what Drasco has done will help astrophysicists track down these illusive waves.
Just a little fine tuning
Gravitational waves are similar to radio waves in that both have specific frequencies. On the radio, for example, the number corresponding to the station you're listening to represents the frequency at which that station transmits.
3D visualization of gravitational waves produced by 2 orbiting black holes. Right now, astrophysicists only have an idea of what frequencies two merging black holes transmit because they’re rare and hard to find. In fact, the first ever detection of an event of this kind was only announced this month.
Therefore, astrophysicists are basically toying with their instruments like you sometimes toy with your radio to find the right station, except they don’t know what station will give them the signal they’re looking for.
What Drasco has done in his simulation is estimate the frequency at which an event like this would produce and then see how that frequency changes, so astrophysicists have a better idea of how to fine tune their instruments to search for these waves.
Detecting gravitational waves would revolutionize the field of astronomy because it would give observers an entirely new way to see the universe. Armed with this new tool, they will be able to test general relativity in ways never before made possible.
Excerpt from thespacereporter.com
As explained by Nature World News, “a mathematical description of the Universe actually requires one fewer dimension than it seems” according to the “holographic principle,” which would indicate that what appears to be a 3-D universe may actually “just be the image of 2-D processes on a huge cosmic horizon.”
Prior to this study, scientists looked into this holographic principle by applying their calculations to a universe presenting Anti de Sitter space. Anti de Sitter is the term used to describe space as having a hyperbolic shape, much like a saddle. This hyperbolic space shape behaves, mathematically, as special relativity would predict.
Special relativity is a theory put forth by Albert Einstein to describe the relationship between space and time, and is especially useful when studying very small particles moving at extreme speeds over cosmic distances. The concept of Anti de Sitter space assumes that spacetime itself is hyperbolic in its natural state, in the absence of matter or energy.
A team at the Vienne University of Technology looked at the holographic principle not in the usual Anti de Sitter space framework, but instead applied the principle to flat spacetime, as represents our physical universe.“Our Universe, in contrast, is quite flat – and on astronomic distances, it has positive curvature,” team member Daniel Grumiller said in a statement.
The team created several gravitational theories that apply to flat space to see if calculations regarding quantum gravity would indicate a holographic description as has occurred in former calculations with theories applied to Anti de Sitter space.
“If quantum gravity in a flat space allows for a holographic description by a standard quantum theory, then there must be physical quantities, which can be calculated in both theories – and the results must agree,” Grumiller said.
The team found that the amount of quantum entanglement required for gravitational theory models expressed the same value in flat quantum gravity as in a low dimensional field theory, showing that the theory of a holographic universe can be successfully applied to the reality of the relatively flat field of spacetime evident in our universe.
“This calculation affirms our assumption that the holographic principle can also be realized in flat spaces. It is evidence for the validity of this correspondence in our universe” team member Max Riegler said.
The results were published in the journal Physical Review Letters.
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| It now seems more probable that a collision between two planets of similar composition led to the formation of the Moon. |
Excerpt from nature.com
A nagging problem at the heart of the leading theory of how the Moon formed seems to have been explained away.
But the theory also implies that the Moon is made up mostly of impactor material. Since lunar and Earth rocks have such similar compositions, this suggests that Earth and the planet that smacked into it resembled each other too. They would have needed to be sister planets, with a relationship much closer than that of any other planetary bodies we have studied in our Solar System. The odds of this being possible were thought to be around a 1% chance, or “uncomfortably rare”, according to Robin Canup, a planetary researcher at the Southwest Research Institute in Boulder, Colorado1.
Better odds
Now it seems that the scenario is not so far-fetched, says Hagai Perets, an astrophysicist at the Israel Institute of Technology in Haifa. He and his colleagues performed simulations of the Solar System’s formation, to investigate how similar planets tend to be to their last giant impactor. They estimated that for 20% to 40% of collisions, the two bodies would be sufficiently similar to explain the Moon’s composition — considerably better odds. The findings are published in Nature2.The planets would have closely resembled each other because of their similar distance from the Sun, meaning that they would have formed from the same kind of orbiting proto-planetary material. “The Earth and the Moon are not twins born from the same planet, but they are sisters in the sense that they grew up in the same environment,” says Perets.
Excerpt from foxnews.com
Eleven fast radio bursts from space seem to follow a strange mathematical pattern, according to a new study – and it has researchers scratching their heads.
According to study co–authors Michael Hippke of the Institute of Data Analysis in Neukirchen-Vluyn, Germany, and John Learned of the University of Hawaii in Manoa, the bursts– which were first detected in 2001 – all had dispersion measures that were integer multiples of the same number: 187.5. “The astronomers that found [the bursts] have not seen such things before and do not understand them,” Learned told FoxNews.com.
Nobody knows what causes fast radio bursts, known as FRBs. They only last a few milliseconds, and only one so far has been captured live (by the Parkes Telescope in Australia last year). Though the bursts release just as much energy in a few milliseconds as the sun does in a month, their brevity indicates that the source must be small, with estimates being several hundred miles across at most.
Researchers use dispersion measures, which records how much “space gunk” the burst has passed through, to estimate the distance an FRB has travelled. For instance, a low frequency FRB will have more gunk on it, indicating a longer trip, whereas a high frequency FRB will be cleaner, indicating it came from closer to Earth.
The fact that all of the FRBs’ dispersion measures are integer multiples of 187.5 has, according to Hippke and Learned’s team’s calculations, a 5 in 10,000 chance of being coincidental. The dispersion measures also indicate that their origin is relatively close to Earth, but unlikely from within our own galaxy.
There are numerous theories on where these bursts came from, including speculation that the messages are from extraterrestrial intelligence. To the scientific community, however, this theory doesn’t really hold water, and is seen as more of a last resort only after all other avenues have been exhausted.
“We think these are likely from some very energetic process, like a burst from a high magnetic field neutron star or energy released [when] two neutron stars merge,” Professor Maura McLaughlin of the West Virginia University Center for Astrophysics explained. “The thing that made people think they were possibly from ETs was a recent paper that showed that one fundamental property is quantized in a way that wouldn't be expected if the signals were naturally occurring. However, I imagine that correlation will totally go away once more are discovered.”
Learned himself is dubious of an alien source as well, noting that he and Hippke only noted the dispersion measures’ “peculiar” pattern, and that they may even be coming from Earth. “We are now leaning more towards a terrestrial, anthropogenic interpretation,” he said. “At this point I would place my money on some sort of governmental satellite, not a natural phenomena, but I would not bet much. More data, which reportedly [is] being analyzed but which we have no insider information about yet, will be most interesting and refute or confirm our hypotheses.” He also noted that he’d only look to an ETI interpretation once all other possibilities have been eliminated.
As for McLaughlin, she believes there’s no way the FRBs could be messages from aliens, as the signals are very broadband and emitted over a wide range of radio frequencies. “It would take a LOT of energy for an alien civilization to produce these bursts - they'd need to harness the energy of many, many suns - and there's no real advantage for communication to send a signal over such a large bandwidth.”
Excerpt from huffingtonpost.comWhen astronomers began studying other solar systems in the Milky Way galaxy back in the 1990s, they noticed something peculiar: most of these systems have big planets that circle their host stars in tight orbits, a fin...
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