Excerpt from autotrader.com By Josh Sadlier Seems like the only thing automakers want to talk about these days is how their cars suddenly get great fuel economy. Given this relentless chatter, it's tempting to conclude that mos...
Tag: returned (page 2 of 5)
Excerpt from independent.co.uk
By Jordan Gaines Lewis
In neuroscience, food is something we call a “natural reward.” In order for us to survive as a species, things like eating, having sex and nurturing others must be pleasurable to the brain so that these behaviours are reinforced and repeated.
Evolution has resulted in the mesolimbic pathway, a brain system that deciphers these natural rewards for us. When we do something pleasurable, a bundle of neurons called the ventral tegmental area uses the neurotransmitter dopamine to signal to a part of the brain called the nucleus accumbens. The connection between the nucleus accumbens and our prefrontal cortex dictates our motor movement, such as deciding whether or not to taking another bite of that delicious chocolate cake. The prefrontal cortex also activates hormones that tell our body: “Hey, this cake is really good. And I’m going to remember that for the future.”Not all foods are equally rewarding, of course. Most of us prefer sweets over sour and bitter foods because, evolutionarily, our mesolimbic pathway reinforces that sweet things provide a healthy source of carbohydrates for our bodies. When our ancestors went scavenging for berries, for example, sour meant “not yet ripe,” while bitter meant “alert – poison!”
Fruit is one thing, but modern diets have taken on a life of their own. A decade ago, it was estimated that the average American consumed 22 teaspoons of added sugar per day, amounting to an extra 350 calories; it may well have risen since then. A few months ago, one expert suggested that the average Briton consumes 238 teaspoons of sugar each week.
Today, with convenience more important than ever in our food selections, it’s almost impossible to come across processed and prepared foods that don’t have added sugars for flavour, preservation, or both.
These added sugars are sneaky – and unbeknown to many of us, we’ve become hooked. In ways that drugs of abuse – such as nicotine, cocaine and heroin – hijack the brain’s reward pathway and make users dependent, increasing neuro-chemical and behavioural evidence suggests that sugar is addictive in the same way, too.
Sugar addiction is real
Anyone who knows me also knows that I have a huge sweet tooth. I always have. My friend and fellow graduate student Andrew is equally afflicted, and living in Hershey, Pennsylvania – the “Chocolate Capital of the World” – doesn’t help either of us. But Andrew is braver than I am. Last year, he gave up sweets for Lent. “The first few days are a little rough,” Andrew told me. “It almost feels like you’re detoxing from drugs. I found myself eating a lot of carbs to compensate for the lack of sugar.”There are four major components of addiction: bingeing, withdrawal, craving, and cross-sensitisation (the notion that one addictive substance predisposes someone to becoming addicted to another). All of these components have been observed in animal models of addiction – for sugar, as well as drugs of abuse.
A typical experiment goes like this: rats are deprived of food for 12 hours each day, then given 12 hours of access to a sugary solution and regular chow. After a month of following this daily pattern, rats display behaviours similar to those on drugs of abuse. They’ll binge on the sugar solution in a short period of time, much more than their regular food. They also show signs of anxiety and depression during the food deprivation period. Many sugar-treated rats who are later exposed to drugs, such as cocaine and opiates, demonstrate dependent behaviours towards the drugs compared to rats who did not consume sugar beforehand.
Like drugs, sugar spikes dopamine release in the nucleus accumbens. Over the long term, regular sugar consumption actually changes the gene expression and availability of dopamine receptors in both the midbrain and frontal cortex. Specifically, sugar increases the concentration of a type of excitatory receptor called D1, but decreases another receptor type called D2, which is inhibitory. Regular sugar consumption also inhibits the action of the dopamine transporter, a protein which pumps dopamine out of the synapse and back into the neuron after firing.
In short, this means that repeated access to sugar over time leads to prolonged dopamine signalling, greater excitation of the brain’s reward pathways and a need for even more sugar to activate all of the midbrain dopamine receptors like before. The brain becomes tolerant to sugar – and more is needed to attain the same “sugar high.”
Sugar withdrawal is also real
Although these studies were conducted in rodents, it’s not far-fetched to say that the same primitive processes are occurring in the human brain, too. “The cravings never stopped, [but that was] probably psychological,” Andrew told me. “But it got easier after the first week or so.”In a 2002 study by Carlo Colantuoni and colleagues of Princeton University, rats who had undergone a typical sugar dependence protocol then underwent “sugar withdrawal.” This was facilitated by either food deprivation or treatment with naloxone, a drug used for treating opiate addiction which binds to receptors in the brain’s reward system. Both withdrawal methods led to physical problems, including teeth chattering, paw tremors, and head shaking. Naloxone treatment also appeared to make the rats more anxious, as they spent less time on an elevated apparatus that lacked walls on either side.
Similar withdrawal experiments by others also report behaviour similar to depression in tasks such as the forced swim test. Rats in sugar withdrawal are more likely to show passive behaviours (like floating) than active behaviours (like trying to escape) when placed in water, suggesting feelings of helplessness.
A new study published by Victor Mangabeira and colleagues in this month’s Physiology & Behavior reports that sugar withdrawal is also linked to impulsive behaviour. Initially, rats were trained to receive water by pushing a lever. After training, the animals returned to their home cages and had access to a sugar solution and water, or just water alone. After 30 days, when rats were again given the opportunity to press a lever for water, those who had become dependent on sugar pressed the lever significantly more times than control animals, suggesting impulsive behaviour.
These are extreme experiments, of course. We humans aren’t depriving ourselves of food for 12 hours and then allowing ourselves to binge on soda and doughnuts at the end of the day. But these rodent studies certainly give us insight into the neuro-chemical underpinnings of sugar dependence, withdrawal, and behaviour.
Through decades of diet programmes and best-selling books, we’ve toyed with the notion of “sugar addiction” for a long time. There are accounts of those in “sugar withdrawal” describing food cravings, which can trigger relapse and impulsive eating. There are also countless articles and books about the boundless energy and new-found happiness in those who have sworn off sugar for good. But despite the ubiquity of sugar in our diets, the notion of sugar addiction is still a rather taboo topic.
Are you still motivated to give up sugar? You might wonder how long it will take until you’re free of cravings and side-effects, but there’s no answer – everyone is different and no human studies have been done on this. But after 40 days, it’s clear that Andrew had overcome the worst, likely even reversing some of his altered dopamine signalling. “I remember eating my first sweet and thinking it was too sweet,” he said. “I had to rebuild my tolerance.”
And as regulars of a local bakery in Hershey – I can assure you, readers, that he has done just that.
Jordan Gaines Lewis is a Neuroscience Doctoral Candidate at Penn State College of Medicine
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| Titan |
Studies may suggest methane-based organic processes ... but maybe not
New findings have roused a great deal of hoopla over the possibility of life on Saturn's moon Titan, which some news reports have further hyped up as hints of extraterrestrials.
However, scientists also caution that aliens might have nothing to do with these findings.All this excitement is rooted in analyses of chemical data returned by NASA's Cassini spacecraft. One study suggested that hydrogen was flowing down through Titan's atmosphere and disappearing at the surface. Astrobiologist Chris McKay at NASA's Ames Research Center speculated that this could be a tantalizing hint that hydrogen is getting consumed by life.
"It's the obvious gas for life to consume on Titan, similar to the way we consume oxygen on Earth," McKay said.
Another study investigating hydrocarbons on Titan's surface found a lack of acetylene, a compound that could be consumed as food by life that relies on liquid methane instead of liquid water to live.
"If these signs do turn out to be a sign of life, it would be doubly exciting because it would represent a second form of life independent from water-based life on Earth," McKay said.
However, NASA scientists caution that aliens might not be involved at all.
McKay told Space.com that "both results are still preliminary."
To date, methane-based life forms are only speculative, with McKay proposing a set of conditions necessary for these kinds of organisms on Titan in 2005. Scientists have not yet detected this form of life anywhere, although there are liquid-water-based microbes on Earth that thrive on methane or produce it as a waste product.
On Titan, where temperatures are around minus-290 degrees Fahrenheit (-179 degrees Celsius), any organisms would have to use a substance that is liquid as its medium for living processes. Water itself cannot do, because it is frozen solid on Titan's surface. The list of liquid candidates is very short — liquid methane and related molecules such as ethane. Previous studies have found Titan to have lakes of liquid methane.
Missing hydrogen?
The dearth of hydrogen Cassini detected is consistent with conditions that could produce methane-based life, but do not conclusively prove its existence, cautioned researcher Darrell Strobel, a Cassini interdisciplinary scientist based at Johns Hopkins University in Baltimore. Strobel wrote the paper on hydrogen appearing online in the journal Icarus.
Strobel looked at densities of hydrogen in different parts of the atmosphere and at the surface. Previous models from scientists had predicted that hydrogen molecules, a byproduct of ultraviolet sunlight breaking apart acetylene and methane molecules in the upper atmosphere, should be distributed fairly evenly throughout the atmospheric layers.
Strobel's computer simulations suggest a hydrogen flow down to the surface at a rate of about 10,000 trillion trillion molecules per second.
"It's as if you have a hose and you're squirting hydrogen onto the ground, but it's disappearing," Strobel said. "I didn't expect this result, because molecular hydrogen is extremely chemically inert in the atmosphere, very light and buoyant. It should 'float' to the top of the atmosphere and escape."
Strobel said it is not likely that hydrogen is being stored in a cave or underground space on Titan. An unknown mineral could be acting as a catalyst on Titan's surface to help convert hydrogen molecules and acetylene back to methane.
Although Allen commended Strobel, he noted "a more sophisticated model might be needed to look into what the flow of hydrogen is."
Consumed acetylene?
Scientists had expected the sun's interactions with chemicals in the atmosphere to produce acetylene that falls down to coat Titan's surface. But when Cassini mapped hydrocarbons on Titan's surface, it detected no acetylene on the surface, according to findings appearing online in the Journal of Geophysical Research.
Instead of alien life on Titan, Allen said one possibility is that sunlight or cosmic rays are transforming the acetylene in icy aerosols in the atmosphere into more complex molecules that would fall to the ground with no acetylene signature.
"Titan's atmospheric chemistry is cranking out organic compounds that rain down on the surface so fast that even as streams of liquid methane and ethane at the surface wash the organics off, the ice gets quickly covered again," said Roger Clark, a Cassini team scientist based at the U.S. Geological Survey in Denver. "All that implies Titan is a dynamic place where organic chemistry is happening now."
All this speculation "is jumping the gun, in my opinion," Allen said.
"Typically in the search for the existence of life, one looks for the presence of evidence -- say, the methane seen in the atmosphere of Mars, which can't be made by normal photochemical processes," Allen added. "Here we're talking about absence of evidence rather than presence of evidence — missing hydrogen and acetylene — and oftentimes there are many non-life processes that can explain why things are missing."
These findings are "still a long way from evidence of life," McKay said. "But it could be interesting."
Excerpt from csmonitor.comA Chinese spacecraft service module has entered orbit around the moon, months after being used in the country's landmark test flight that sent a prototype sample-return capsule on a flight around the moon and returned it to...
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| A SpaceX Falcon 9 rocket stands ready to boost a Dragon capsule on its fifth commercial resupply mission to the International Space Station. If all goes as planned, the rocket will land on a barge on Saturday. |
Excerpt from
news.nationalgeographic.com
SpaceX chief aims to make rockets reusable by guiding them to a barge instead of letting them splash down.
Rockets have landed on the moon and on Mars, but now SpaceX rocket maven Elon Musk aims to land one someplace really exotic—a barge floating in the Atlantic Ocean.
The barge, or "autonomous spaceport drone ship" as SpaceX calls it, is scheduled to land its returned rocket on Saturday, about 17 minutes after the planned 4:47 a.m. (EST) launch of a Dragon cargo spacecraft heading to the International Space Station from the Cape Canaveral Air Force Station in Florida.
The point of the barge landing is to recover the rocket's expensive engines and reuse them. Until now, rocket engines have typically been allowed to burn up on reentry or plummet into the ocean, either for disposal or recovery later by boat. If SpaceX pulls off the barge landing, it will be a first for ocean landings.
The barge's landing site, just 300 feet by 170 feet in size (about 90 by 50 meters), will act as the outfielder's glove to catch the massive first stage of the Falcon 9 launch rocket, maneuvered into place by remote control.
"Our main mission is to get cargo to the space station," said SpaceX's Hans Koenigsmann, speaking last week at a NASA briefing. "I'm pretty sure it will be pretty exciting," he said of the attempted controlled landing of the 14-story-tall first stage of the rocket on a flat floating platform.
Failure an Option
SpaceX has successfully landed rocket stages on land, and made a controlled landing on water after a past cargo launch, which still led to the loss of the rocket stage in the drink. Musk has previously suggested that barge landings of stages would expedite their reuse, leading to cheaper rocketry.
Musk gave 50 percent odds of the barge landing working out. ("I pretty much made that up. I have no idea," he added in a recent web chat on Reddit.)
NASA has released a new image of the gorgeous Eagle Nebula, known by many as the 'Pillars of Creation', taken by the Hubble Space telescope in celebration of the telescope's upcoming 25th anniversary in April. Hubble returned to the spectacular space ...
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Minerals taken from lagoons reveal a century-long drought occurred between A.D. 800 and A.D. 900, right when the Mayan civilization disintegrated. |
Minerals taken from Belize's famous underwater cave, known as the Blue Hole, as well as lagoons nearby, show that an extreme, century-long drought occurred between A.D. 800 and A.D. 900, right when the Mayan civilization disintegrated. After the rains returned, the Mayans moved north — but they disappeared again a few centuries later, and that disappearance occurred at the same time as another dry spell, the sediments reveal.
Rise and decline
From A.D. 300 to A.D. 700, the Mayan civilization flourished in the Yucatan peninsula. These ancient Mesoamericans built stunning pyramids, mastered astronomy, and developed both a hieroglyphic writing system and a calendar system, which is famous for allegedly predicting that the world would end in 2012.
But in the centuries after A.D. 700, the civilization's building activities slowed and the culture descended into warfare and anarchy. Historians have speculatively linked that decline with everything from the ancient society's fear of malevolent spirits to deforestation completed to make way for cropland to the loss of favored foods, such as the Tikal deer.
The evidence for a drought has been growing in recent years: Since at least 1995, scientists have been looking more closely at the effects of drought. A 2012 study in the journal Science analyzed a 2,000-year-old stalagmite from a cave in southern Belize and found that sharp decreases in rainfall coincided with periods of decline in the culture. But that data came from just one cave, which meant it was difficult to make predictions for the area as a whole, Droxler said.
The main driver of this drought is thought to have been a shift in the intertropical convergence zone (ITCZ), a weather system that generally dumps water on tropical regions of the world while drying out the subtropics. During summers, the ITCZ pelts the Yucatan peninsula with rain, but the system travels farther south in the winter. Many scientists have suggested that during the Mayan decline, this monsoon system may have missed the Yucatan peninsula altogether.
Deep history
The team found that during the period between A.D. 800 and A.D. 1000, when the Mayan civilization collapsed, there were just one or two tropical cyclones every two decades, as opposed to the usual five or six. After that, the Maya moved north, building at sites such as Chichen Itza, in what is now Mexico.
But the new results also found that between A.D. 1000 and A.D. 1100, during the height of the Little Ice Age, another major drought struck. This period coincides with the fall of Chichen Itza.
The findings strengthen the case that drought helped usher in the long decline of the Mayan culture.
Excerpt from dailymail.co.ukThis is according to Argentinian scientists who found eclipse calendarThe calender included a solar eclipse that happened on May 12, 205 BC Previous radiocarbon dating analysis of had dates mechanism to 100 BCThe study&...
Excerpt from bostonglobe.com
Decades after that first small step, space thinkers are finally getting serious about our nearest neighbor By Kevin Hartnett
This week, the European Space Agency made headlines with the first successful landing of a spacecraft on a comet, 317 million miles from Earth. It was an upbeat moment after two American crashes: the unmanned private rocket that exploded on its way to resupply the International Space Station, and the Virgin Galactic spaceplane that crashed in the Mojave Desert, killing a pilot and raising questions about whether individual businesses are up to the task of operating in space. During this same period, there was one other piece of space news, one far less widely reported in the United States: On Nov. 1, China successfully returned a moon probe to Earth. That mission follows China’s landing of the Yutu moon rover late last year, and its announcement that it will conduct a sample-return mission to the moon in 2017. With NASA and the Europeans focused on robot exploration of distant targets, a moon landing might not seem like a big deal: We’ve been there, and other countries are just catching up. But in recent years, interest in the moon has begun to percolate again, both in the United States and abroad—and it’s catalyzing a surprisingly diverse set of plans for how our nearby satellite will contribute to our space future. China, India, and Japan have all completed lunar missions in the last decade, and have more in mind. Both China and Japan want to build unmanned bases in the early part of the next decade as a prelude to returning a human to the moon. In the United States, meanwhile, entrepreneurs are hatching plans for lunar commerce; one company even promises to ferry freight for paying customers to the moon as early as next year. Scientists are hatching more far-out ideas to mine hydrogen from the poles and build colonies deep in sky-lit lunar caves. This rush of activity has been spurred in part by the Google Lunar X Prize, a $20 million award, expiring in 2015, for the first private team to land a working rover on the moon and prove it by sending back video. It is also driven by a certain understanding: If we really want to launch expeditions deeper into space, our first goal should be to travel safely to the moon—and maybe even figure out how to live there.
Entrepreneurial visions of opening the moon to commerce can seem fanciful, especially in light of the Virgin Galactic and Orbital Sciences crashes, which remind us how far we are from having a truly functional space economy. They also face an uncertain legal environment—in a sense, space belongs to everyone and to no one—whose boundaries will be tested as soon as missions start to succeed. Still, as these plans take shape, they’re a reminder that leaping blindly is sometimes a necessary step in opening any new frontier.
“All I can say is if lunar commerce is foolish,” said Columbia University astrophysicist Arlin Crotts in an e-mail, “there are a lot of industrious and dedicated fools out there!”
At its height, the Apollo program accounted for more than 4 percent of the federal budget. Today, with a mothballed shuttle and a downscaled space station, it can seem almost imaginary that humans actually walked on the moon and came back—and that we did it in the age of adding machines and rotary phones.
“In five years, we jumped into the middle of the 21st century,” says Roger Handberg, a political scientist who studies space policy at the University of Central Florida, speaking of the Apollo program. “No one thought that 40 years later we’d be in a situation where the International Space Station is the height of our ambition.”
NASA/JPL/Northwestern University
An image of Earth and the moon created from photos by Mariner 10, launched in 1973.Without a clear goal and a geopolitical rivalry to drive it, the space program had to compete with a lot of other national priorities. The dramatic moon shot became an outlier in the longer, slower story of building scientific achievements.
Now, as those achievements accumulate, the moon is coming back into the picture. For a variety of reasons, it’s pretty much guaranteed to play a central role in any meaningful excursions we take into space. It’s the nearest planetary body to our own—238,900 miles away, which the Apollo voyages covered in three days. It has low gravity, which makes it relatively easy to get onto and off of the lunar surface, and it has no atmosphere, which allows telescopes a clearer view into deep space.
The moon itself also still holds some scientific mysteries. A 2007 report on the future of lunar exploration from the National Academies called the moon a place of “profound scientific value,” pointing out that it’s a unique place to study how planets formed, including ours. The surface of the moon is incredibly stable—no tectonic plates, no active volcanoes, no wind, no rain—which means that the loose rock, or regolith, on the moon’s surface looks the way the surface of the earth might have looked billions of years ago.
NASA still launches regular orbital missions to the moon, but its focus is on more distant points. (In a 2010 speech, President Obama brushed off the moon, saying, “We’ve been there before.”) For emerging space powers, though, the moon is still the trophy destination that it was for the United States and the Soviet Union in the 1960s. In 2008 an Indian probe relayed the best evidence yet that there’s water on the moon, locked in ice deep in craters at the lunar poles. China landed a rover on the surface of the moon in December 2013, though it soon malfunctioned. Despite that setback, China plans a sample-return mission in 2017, which would be the first since a Soviet capsule brought back 6 ounces of lunar soil in 1976.
The moon has also drawn the attention of space-minded entrepreneurs. One of the most obvious opportunities is to deliver scientific instruments for government agencies and universities. This is an attractive, ready clientele in theory, explains Paul Spudis, a scientist at the Lunar and Planetary Institute in Houston, though there’s a hitch: “The basic problem with that as a market,” he says, “is scientists never have money of their own.”
One company aspiring to the delivery role is Astrobotic, a startup of young Carnegie Mellon engineers based in Pittsburgh, which is currently positioning itself to be “FedEx to the moon,” says John Thornton, the company’s CEO. Astrobotic has signed a contract with SpaceX, the commercial space firm founded by Elon Musk, to use a Falcon 9 for an inaugural delivery trip in 2015, just in time to claim the Google Lunar X Prize. Thornton says most of the technology is in place for the mission, and that the biggest remaining hurdle is figuring out how to engineer a soft, automated moon landing.
Astrobotic is charging $1.2 million per kilogram—you can, in fact, place an order on its website—and Thornton says the company has five customers so far. They include the entities you might expect, like NASA, but also less obvious ones, like a company that wants to deliver human ashes for permanent internment and a Japanese soft drink manufacturer that wants to place its signature beverage, Pocari Sweat, on the moon as a publicity stunt. Astrobotic is joined in this small sci-fi economy by Moon Express out of Mountain View, Calif., another company competing for the Google Lunar X Prize.
Plans like these are the low-hanging fruit of the lunar economy, the easiest ideas to imagine and execute. Longer-scale thinkers are envisioning ways that the moon will play a larger role in human affairs—and that, says Crotts, is where “serious resource exploitation” comes in.
If this triggers fears of a mined-out moon, be reassured: “Apollo went there and found nothing we wanted. Had we found anything we really wanted, we would have gone back and there would have been a new gold rush,” says Roger Launius, the former chief historian of NASA and now a curator at the National Air and Space Museum.
There is one possible exception: helium-3, an isotope used in nuclear fusion research. It is rare on Earth but thought to be abundant on the surface of the moon, which could make the moon an important energy source if we ever figure out how to harness fusion energy. More immediately intriguing is the billion tons of water ice the scientific community increasingly believes is stored at the poles. If it’s there, that opens the possibility of sustained lunar settlement—the water could be consumed as a liquid, or split into oxygen for breathing and hydrogen for fuel.
The presence of water could also open a potentially ripe market providing services to the multibillion dollar geosynchronous satellite industry. “We lose billions of dollars a year of geosynchronous satellites because they drift out of orbit,” says Crotts. In a new book, “The New Moon: Water, Exploration, and Future Habitation,” he outlines plans for what he calls a “cislunar tug”: a space tugboat of sorts that would commute between the moon and orbiting satellites, resupplying them with propellant, derived from the hydrogen in water, and nudging them back into the correct orbital position.
In the long term, the truly irreplaceable value of the moon may lie elsewhere, as a staging area for expeditions deeper into space. The most expensive and dangerous part of space travel is lifting cargo out of and back into the Earth’s atmosphere, and some people imagine cutting out those steps by establishing a permanent base on the moon. In this scenario, we’d build lunar colonies deep in natural caves in order to escape the micrometeorites and toxic doses of solar radiation that bombard the moon, all the while preparing for trips to more distant points.
gical hurdles is long, and there’s also a legal one, at least where commerce is concerned. The moon falls under the purview of the Outer Space Treaty, which the United States signed in 1967, and which prohibits countries from claiming any territory on the moon—or anywhere else in space—as their own.
“It is totally unclear whether a private sector entity can extract resources from the moon and gain title or property rights to it,” says Joanne Gabrynowicz, an expert on space law and currently a visiting professor at Beijing Institute of Technology School of Law. She adds that a later document, the 1979 Moon Treaty, which the United States has not signed, anticipates mining on the moon, but leaves open the question of how property rights would be determined.
There are lots of reasons the moon may never realize its potential to mint the world’s first trillionaires, as some space enthusiasts have predicted. But to the most dedicated space entrepreneurs, the economic and legal arguments reflect short-sighted thinking. They point out that when European explorers set sail in the 15th and 16th centuries, they assumed they’d find a fortune in gold waiting for them on the other side of the Atlantic. The real prizes ended up being very different—and slow to materialize.
“When we settled the New World, we didn’t bring a whole lot back to Europe [at first],” Thornton says. “You have to create infrastructure to enable that kind of transfer of goods.” He believes that in the case of the moon, we’ll figure out how to do that eventually.
Roger Handberg is as clear-eyed as anyone about the reasons why the moon may never become more than an object of wonder, but he also understands why we can’t turn away from it completely. That challenge, in the end, may finally be what lures us back.
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| All four sides of the Sumerian kings list artifact |
The following work is a translation provided by Oxford University (England), of a prism now in the Weld-Blundell collection of the Ashmolean Museum in Oxford, England. Known more popularly as the Sumerian kings list, it is a list compiled from fifteen or more different texts, tracing the rulers of certain Sumerian cities in succession. The original form of the list is believed to go back to approximately 2,000 BC.
What is remarkable about this list is the lengths of reigns of a number of kings, some listed as long as 43,200 years. I find several possibilities for the long reigns inscribed on this artifact.
1. This artifact is a hoax. I do not see this as likely however, as this artifact appears to be taken seriously by credible sources, namely Oxford University.
2. The scribes and artisans who created the list erred. I do not see this as a very likely explanation either, as even the most mathematically challenged scribe would have noticed the hugely obvious oversights.
3. The lengths of reigns was propaganda, conning the masses into seeing their kings as more god-like. This scenario is at least plausible, as history books state that as recently as the 20th century, the Japanese people believed their emperor Hirohito was a god, only to be shocked to learn the truth as he made public appearances after Japan's defeat at the end of World War 2.
4. A handful of modern day scholars believe the years listed are multiplied equations, with kings receiving exaggerated lengths of reigns dependent upon their achievements while ruler. I see this as possible, though I am not convinced. Why choose such an odd way to honor a past king? Sumerians have preserved in tablet and other forms such accurate record keeping on so many varied subjects. Would they really choose to distort their records, records they carefully preserved for future generations, to honor past kings? There is also a lack of solid evidence to support this theory.
5. Humans lived far longer life spans in our past. I see this theory as certainly possible.
6. Ancient Sumerian kings were of extraterrestrial origin.
What I find most intriguing is that possibilities number 5 & 6 appear the most likely explanations to the Sumerian king list.
Greg Giles
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The Sumerian king list: Translation provided by Oxford University etcsl.orinst.ox.ac.uk
(In the following translation, mss. are referred to by the sigla used by Vincente 1995; from those listed there, mss. Fi, Go, P6, and WB 62 were not used; if not specified by a note, numerical data come from ms. WB.)1-39After the kingship descended from heaven, the kingship was in Eridug. In Eridug, Alulim became king; he ruled for 28800 years. Alaljar ruled for 36000 years. 2 kings; they ruled for 64800 years. Then Eridug fell and the kingship was taken to Bad-tibira. In Bad-tibira, En-men-lu-ana ruled for 43200 years. En-men-gal-ana ruled for 28800 years. Dumuzid, the shepherd, ruled for 36000 years. 3 kings; they ruled for 108000 years. Then Bad-tibira fell (?) and the kingship was taken to Larag. In Larag, En-sipad-zid-ana ruled for 28800 years. 1 king; he ruled for 28800 years. Then Laragfell (?) and the kingship was taken to Zimbir. In Zimbir, En-men-dur-ana became king; he ruled for 21000 years. 1 king; he ruled for 21000 years. Then Zimbir fell (?) and the kingship was taken to Curuppag. In Curuppag, Ubara-Tutu became king; he ruled for 18600 years. 1 king; he ruled for 18600 years. In 5 cities 8 kings; they ruled for 241200 years. Then the flood swept over.
40-94After the flood had swept over, and the kingship had descended from heaven, the kingship was in Kic. In Kic, Jucur became king; he ruled for 1200 years. Kullassina-bel ruled for 960 (ms. P2+L2 has instead: 900) years. Nanjiclicma ruled for (ms. P2+L2 has:) 670 (?) years. En-tarah-ana ruled for (ms. P2+L2 has:) 420 years ......, 3 months, and 3 1/2 days. Babum ...... ruled for (ms. P2+L2 has:) 300 years. Puannumruled for 840 (ms. P2+L2 has instead: 240) years. Kalibum ruled for 960 (ms. P2+L2 has instead:900) years. Kalumum ruled for 840 (mss. P3+BT14, Su1 have instead:900) years. Zuqaqip ruled for 900 (ms. Su1 has instead: 600)years. (In mss. P2+L2, P3+BT14, P5, the 10th and 11th rulers of the dynasty precede the 8th and 9th.) Atab (mss. P2+L2, P3+BT14, P5 have instead: Aba) ruled for 600 years. Macda, the son of Atab, ruled for 840 (ms. Su1 has instead:720) years. Arwium, the son of Macda, ruled for 720 years. Etana, the shepherd, who ascended to heaven and consolidated all the foreign countries, became king; he ruled for 1500 (ms. P2+L2 has instead: 635) years. Balih, the son of Etana, ruled for 400 (mss. P2+L2, Su1 have instead: 410) years. En-me-nuna ruled for 660 (ms. P2+L2 has instead:621) years. Melem-Kic, the son of En-me-nuna, ruled for 900 years. (ms. P3+BT14 adds:) 1560 are the years of the dynasty of En-me-nuna . Barsal-nuna, the son of En-me-nuna,(mss. P5, P3+BT14 have instead: Barsal-nuna) ruled for 1200 years. Zamug, the son of Barsal-nuna, ruled for 140 years. Tizqar, the son of Zamug, ruled for 305 years. (ms. P3+BT14 adds:) 1620 + X ....... Ilku ruled for 900 years. Iltasadum ruled for 1200 years. En-men-barage-si, who made the land of Elamsubmit, became king; he ruled for 900 years. Aga, the son of En-men-barage-si, ruled for 625 years. (ms. P3+BT14 adds:) 1525 are the years of the dynasty of En-men-barage-si. 23 kings; they ruled for 24510 years, 3 months, and 3 1/2 days. Then Kic was defeated and the kingship was taken to E-ana.
95-133In E-ana, Mec-ki-aj-gacer, the son of Utu, became lord and king; he ruled for 324 (ms. P2+L2 has instead: 325)years. Mec-ki-aj-gacer entered the sea and disappeared. Enmerkar, the son of Mec-ki-aj-gacer, the king of Unug, who built Unug (mss. L1+N1, P2+L2 have instead: under whom Unug was built), became king; he ruled for 420 (ms. TL has instead: 900 + X) years. (ms. P3+BT14 adds:) 745 are the years of the dynasty of Mec-ki-aj-gacer. (ms TL adds instead: ......; he ruled for 5 + X years.) Lugalbanda, the shepherd, ruled for 1200 years. Dumuzid, the fisherman, whose city was Kuara, ruled for 100 (ms. TL has instead: 110) years. (ms. P3+BT14 adds:) He captured En-me-barage-si single-handed. Gilgamec, whose father was a phantom (?), the lord of Kulaba, ruled for 126 years. Ur-Nungal, the son of Gilgamec, ruled for 30 years. Udul-kalama, the son of Ur-Nungal (ms. Su1 has instead: Ur-lugal), ruled for 15 years. La-ba'cum ruled for 9 years. En-nun-tarah-ana ruled for 8 years. Mec-he, the smith, ruled for 36 years. Melem-ana (ms. Su2 has instead:Til-kug (?) ......) ruled for 6 (ms. Su2 has instead: 900)years. Lugal-kitun (?) ruled for 36 (ms. Su2 has instead: 420)years. 12 kings; they ruled for 2310 (ms. Su2 has instead: 3588) years. Then Unug was defeated and the kingship was taken to Urim.
134-147In Urim, Mec-Ane-pada became king; he ruled for 80 years. Mec-ki-aj-Nanna(ms. P2+L2 has instead: Mec-ki-aj-nuna), the son of Mec-Ane-pada, became king; he ruled for 36 (ms. P2+L2 has instead: 30)years. Elulu ruled for (mss. L1+N1, P2+L2, P3+BT14 have:) 25 years. Baluluruled for (mss. L1+N1, P2+L2, P3+BT14 have:) 36 years. (mss. L1+N1, P2+L2 have:) 4 kings; they ruled for (mss. L1+N1, P2+L2, P3+BT14 have:) 171 years. Then Urim was defeated and the kingship was taken to Awan.
148-159In Awan, ...... became king; he ruled for ...... years. ...... ruled for ...... years. ...... ruled for 36 years. 3 kings; they ruled for 356 years. Then Awan was defeated and the kingship was taken to Kic.
160-178In Kic, Susuda, the fuller, became king; he ruled for 201 + X years. Dadasig ruled for (ms. vD has:) 81 years. Mamagal, the boatman, ruled for 360 (ms. L1+N1 has instead: 420) years. Kalbum, the son of Mamagal (ms. WB has instead:Magalgal), ruled for 195 (ms. L1+N1 has instead: 132)years. Tuge (?) ruled for 360 years. Men-nuna, (ms. L1+N1 adds:) the son of Tuge (?), ruled for 180 years. (in mss. L1+N1, TL, the 7th and 8th rulers of the dynasty are in reverse order) ...... ruled for 290 years. Lugalju ruled for 360 (ms. L1+N1 has instead:420) years. 8 kings; they ruled for 3195 (ms. L1+N1 has instead: 3792) years. Then Kic was defeated and the kingship was taken to Hamazi.
179-185In Hamazi, Hadanic became king; he ruled for 360 years. 1 king; he ruled for 360 years. Then Hamazi was defeated and the kingship was taken (ms. P3+BT14 has instead: was returned a second time) to Unug.
(In mss. IB, L1+N1, TL, the 2nd dynasty of Unug of ll. 185-191 is preceded by the 2nd dynasty of Urim of ll. 192-203.)
186-192In Unug, En-cakanca-ana became king; he ruled for 60 years. Lugal-ure(ms. P3+BT14 has instead: Lugal-kinice-dudu (?)) ruled for 120 years. Argandea ruled for 7 years. (ms. L1+N1 has:) 3 kings; they ruled for (ms. L1+N1 has:) 187 years. Then Unug was defeated (ms. TL has instead:destroyed) and the kingship was taken to Urim.
193-204In Urim, Nani became king; he ruled for (ms. vD has:) 120 + X (ms. IB has instead: 54 + X) years. Mec-ki-aj-Nanna, the son of Nani, ruled for (ms. vD has:) 48years. ......, the son (?) of ......, ruled for (ms. IB has:) 2 years. (ms. IB has:) 3 kings; they ruled for (ms. IB has:) 582 (ms. TL has instead:578) years. (ms. vD has instead: 2 kings; they ruled for 120 + X years.) Then Urimwas defeated (ms. TL has instead: destroyed) and the kingship was taken to Adab.
205-210In Adab, Lugal-Ane-mundu became king; he ruled for (mss. L1+N1, TL have:) 90 years. (mss. L1+N1, TL have:) 1 king; he ruled for (mss. L1+N1, TL have:) 90 years. Then Adab was defeated (ms. TL has instead:destroyed) and the kingship was taken to Mari.
211-223In Mari, Anbu (?) became king; he ruled for 30 (ms. TL has instead:90) years. Anba (?), the son of Anbu (?), ruled for 17 (ms. TL has instead: 7) years. Bazi, the leatherworker, ruled for 30 years. Zizi, the fuller, ruled for 20 years. Limer, the gudu priest, ruled for 30 years. Carrum-iter ruled for 9 (ms. TL has instead: 7) years. 6 kings; they ruled for 136 (ms. TL has instead:184) years. Then Mari was defeated (ms. TL has instead:destroyed) and the kingship was taken to Kic.
224-231In Kic, Kug-Bau, the woman tavern-keeper, who made firm the foundations of Kic, became king; she ruled for 100 years. 1 king; she ruled for 100 years. Then Kic was defeated (ms. TL has instead:destroyed) and the kingship was taken to Akcak.
232-243In Akcak, Unzi became king; he ruled for 30 years. Undalulu ruled for 6(mss. L1+N1, S have instead: 12) years. Urur ruled for (ms. IB has instead: was king (?) for) 6 years. Puzur-Nirah ruled for (mss. IB, L1+N1, S, Su1 have:) 20 years. Icu-Il ruled for (mss. IB, L1+N1, S, Su1 have:) 24 years. Cu-Suen, the son of Icu-Il, ruled for (mss. IB, L1+N1, S, TL have:) 7 (ms. Su1 has instead: 24) years. (mss. S, Su1, TL have:) 6 kings; they ruled for (mss. L1+N1, S, TL have:) 99(ms. Su1 has instead: 116) years (ms. IB has instead: 5 kings; they ruled for (ms. IB has:) 87 years). Then Akcak was defeated (ms. S has instead: Then the reign of Akcak was abolished) and the kingship was taken to Kic.
(mss. IB, S, Su1, Su3+Su4 list the 3rd and 4th dynasty of Kic of ll. 224-231 and ll. 244-258, respectively, as one dynasty)
244-258In Kic, Puzur-Suen, the son of Kug-Bau, became king; he ruled for 25 years. Ur-Zababa, the son of Puzur-Suen, ruled for 400 (mss. P3+BT14, S have instead:6) (ms. IB has instead: 4 + X) years. (ms. P3+BT14 adds:) 131 are the years of the dynasty of Kug-Bau. Zimudar (ms. TL has instead: Ziju-iake) ruled for 30 (ms. IB has instead: 30 + X)years. Uß³i-watar, the son of Zimudar (ms. TL has instead: Ziju-iake), ruled for 7 (ms. S has instead: 6) years. Ectar-muti ruled for 11 (ms. Su1 has instead: 17 (?)) years. Icme-Camacruled for 11 years. (ms. Su1 adds:) Cu-ilicu ruled for 15 years. Nanniya, the jeweller, (ms. Su1 has instead: Zimudar) (ms. IB has instead: ......) ruled for 7 (ms. S has instead: 3) years. 7 kings; they ruled for 491 (ms. Su1 has instead: 485) years (ms. S has instead: 8 kings; they ruled for (ms. S has:) 586 years). Then Kic was defeated (ms. S has instead: Then the reign of Kic was abolished) and the kingship was taken (ms. P3+BT14 has instead: was returned a third time) to Unug.
(ms. IB omits the 3rd dynasty of Unug of ll. 258-263)
259-265In Unug, Lugal-zage-si became king; he ruled for 25 (ms. P3+BT14 has instead: 34) years. 1 king; he ruled for 25 (ms. P3+BT14 has instead: 34)years. Then Unug was defeated(ms. S has instead: Then the reign of Unug was abolished) and the kingship was taken to Agade.
266-296In Agade, Sargon, whose father was a gardener, the cupbearer of Ur-Zababa, became king, the king of Agade, who built Agade (ms. L1+N1 has instead:under whom Agade was built); he ruled for 56 (ms. L1+N1 has instead:55) (ms. TL has instead: 54) years. Rimuc, the son of Sargon, ruled for 9 (ms. IB has instead:7) (ms. L1+N1 has instead: 15) years. Man-icticcu, the older brother of Rimuc, the son of Sargon, ruled for 15 (ms. L1+N1 has instead:7) years. Naram-Suen, the son of Man-icticcu, ruled for (mss. L1+N1, P3+BT14 have:) 56 years. Car-kali-carri, the son of Naram-Suen, ruled for (ms. L1+N1, Su+Su4 have:) 25 (ms. P3+BT14 has instead:24) years. (ms. P3+BT14 adds:) 157 are the years of the dynasty of Sargon. Then who was king? Who was the king? (ms. Su3+Su4 has instead: who was king? Who indeed was king?) Irgigi was king, Imi was king, Nanûm was king (in mss. L1+N1, Su3+Su4, Imi and Nanûm are in reverse order) , Ilulu was king, and the (mss. P3+BT14, S have:) 4 of them ruled for only (mss. P3+BT14, S have:) 3years. Dudu ruled for 21 years. Cu-Durul, the son of Dudu, ruled for 15 (ms. IB has instead: 18) years. 11 kings; they ruled for 181 years (ms. S has instead: 12 kings; they ruled for (ms. S has:) 197 years) (mss. Su1, Su3+Su4, which omit Dudu and Cu-Durul, have instead: 9 kings; they ruled for (ms. Su1 has:) 161 (ms. Su3+Su4 has instead: 177) years. Then Agade was defeated (ms. S has instead: Then the reign of Agade was abolished) and the kingship was taken to Unug.
297-307In Unug, Ur-nijin became king; he ruled for 7 (mss. IB, S have instead: 3) (ms. Su1 has instead:15) (ms. Su3+Su4 has instead: 30)years. Ur-gigir, the son of Ur-nijin, ruled for 6 (ms. IB has instead: 7) (ms. Su1 has instead: 15) (ms. Su3+Su4 has instead: 7) years. Kuda ruled for 6 years. Puzur-ili ruled for 5 (ms. IB has instead: 20) years. Ur-Utu ruled for 6(ms. Su3+Su4 has instead: Ur-Utu), the son of Ur-gigir, ruled for 25 (ms. Su1 has instead: Lugal-melem, the son of Ur-gigir, ruled for 7) years. 5 kings; they ruled for 30 (ms. IB has instead:43) (mss. PÝ+Ha, S have instead:26) years (ms. Su3+Su4, which omits Kuda and Puzur-ili, has instead: 3 kings; they ruled for (ms. Su3+Su4 has:) 47 years). Unug was defeated (ms. S has instead: Then the reign of Unug was abolished) and the kingship was taken to the army (ms. Su3+Su4 has instead:land) of Gutium.
308-334In the army (ms. Su3+Su4 has instead:land) of Gutium, at first no king was famous; they were their own kings and ruled thus for 3 years(ms. L1+N1 has instead: they had no king; they ruled themselves for 5 years). Then Inkicuc (ms. Su3+Su4 has instead:......) ruled for 6 (ms. L1+Ni1 has instead: 7) years. Zarlagabruled for 6 years. Culme (ms. L1+N1 has instead: Yarlagac) ruled for 6 years. Silulumec (ms. Mi has instead:Silulu) ruled for 6(ms. G has instead: 7) years. Inimabakec ruled for 5 (ms. Mi has instead: Duga ruled for 6) years. Igecauc ruled for 6 (ms. Mi has instead: Ilu-an (?) ruled for 3) years. Yarlagab ruled for 15 (ms. Mi has instead: 5) years. Ibate ruled for 3 years. Yarla (ms. L1+N1 has instead:Yarlangab (?)) ruled for 3 years. Kurum (ms. L1+N1 has instead: ......) ruled for 1 (ms. Mi has instead: 3) years. Apil-kin ruled for 3 years. La-erabum (?) ruled for 2 years. Irarum ruled for 2 years. Ibranum ruled for 1 year. Hablumruled for 2 years. Puzur-Suen, the son of Hablum, ruled for 7 years. Yarlaganda ruled for 7 years. ...... ruled for 7 years. Tiriga (?) ruled for 40 days. 21 kings; they ruled for (ms. L1+N1 has:) 124 years and 40 days (ms. Su3+Su4 has instead: 25 years). Then the army of Gutium was defeated (ms. TL has instead: destroyed) and the kingship was taken to Unug.
335-340In Unug, Utu-hejal became king; he ruled for 427 years, ...... days (ms. IB has instead: 26 years, 2 + X months, and 15 days) (ms. J has instead: 7 years, 6 months, and 15 days) (ms. TL has instead: 7 years, 6 months, and 5 days). 1 king; he ruled for 427 years, ...... days (ms. J has instead: 7 years, 6 months, and 15 days) (ms. TL has instead: 7 years, 6 months, and 5 days). Then Unug was defeated and the kingship was taken to Urim.
341-354In Urim, Ur-Namma became king; he ruled for 18 years. Culgi, the son of Ur-Namma, ruled for 46 (mss. Su3+Su4, TL have instead: 48) (ms. P5 has instead:58) years. Amar-Suena, the son of Culgi, ruled for 9(ms. Su3+Su4 has instead: 25) years. Cu-Suen, the son of Amar-Suena, ruled for 9 (ms. P5 has instead: 7) (ms. Su1 has instead: 20 + X) (ms. Su3+Su4 has instead: 16) years. Ibbi-Suen, the son of Cu-Suen, ruled for 24 (mss. P5, Su1 have instead:25) (ms. Su3+Su4 has instead: 15)(ms. TL has instead: 23 (?)) years. 4 kings; they ruled for 108 years (mss. J, P5, Su1, Su3+Su4 have instead: 5 kings; they ruled for (ms. P5 has:) 117 (ms. Su1 has instead: 120 + X) (ms. Su3+Su4 has instead: 123) years). Then Urim was defeated (ms. P5 has instead: Then the reign of Urim was abolished). (ms. Su3+Su4 adds:) The very foundation of Sumer was torn out (?). The kingship was taken to Isin.
355-377In Isin, Icbi-Erra became king; he ruled for 33(ms. P5 has instead: 32) years. Cu-ilicu, the son of Icbi-Erra, ruled for 20 (ms. P5 has instead: 10) (ms. Su1 has instead: 15) years. Iddin-Dagan, the son of Cu-ilicu, ruled for 21 (ms. Su1 has instead: 25) years. Icme-Dagan, the son of Iddin-Dagan, ruled for (mss. P2, P5 have:) 20 (ms. Mi has instead:18) years. Lipit-Ectar, the son of Icme-Dagan (ms. P2 has instead:Iddin-Dagan), ruled for (mss. L1+N1, P2, P5 have:) 11 years. Ur-Ninurta (mss. L1+N1, P2 add:) , the son of Ickur-- may he have years of abundance, a good reign, and a sweet life --ruled for (ms. P5 has:) 28 years. Bur-Suen, the son of Ur-Ninurta, ruled for 21 years. Lipit-Enlil, the son of Bur-Suen, ruled for 5 years. Erra-imitti ruled for 8 (mss. P5, TL have instead: 7)years. (ms. P5 adds:) ...... ruled for ...... 6 months. Enlil-bani ruled for 24 years. Zambiya ruled for 3 years. Iter-pica ruled for 4 years. Ur-dul-kugaruled for 4 years. Suen-magirruled for 11 years. (ms. P5 adds:) Damiq-ilicu, the son of Suen-magir, ruled for 23 years. 14 kings; they ruled for 203 years (ms. P5 has instead: 225 years and 6 months).
(Mss. P2+L2, L1+N1 and P4+Ha conclude with a summary of the post-diluvian dynasties; the translation of ll. 378-431 uses numerical data from each mss. but follows the wording of P2+L2 and L1+N1)
378-431A total of 39 kings ruled for 14409 + X years, 3 months and 3 1/2 days, 4 times in Kic. A total of 22 kings ruled for 2610 + X years, 6 months and 15 days, 5 times in Unug. A total of 12 kings ruled for 396 years, 3 times in Urim. A total of 3 kings ruled for 356 years, once in Awan. A total of 1 king ruled for 420 years, once in Hamazi.16 lines missing
A total of 12 (?) kings ruled for 197 (?) years, once in Agade. A total of 21 (ms. P4+Ha has instead: 23) kings ruled for 125 years and 40 days (ms. P4+Ha has instead: 99 years), once in the army of Gutium. A total of 11 (ms. P4+Ha has instead: 16) kings ruled for 159 (ms. P4+Ha has instead: 226)years, once in Isin. There are 11 cities, cities in which the kingship was exercised. A total of 134 (ms. P4+Ha has instead: 139) kings, who altogether ruled for 28876 + X (ms. P4+Ha has instead: 3443 + X) years. 21.
Revision history
03.ix.1999 : GZ : adapting translation04.xii.1999 : JAB : proofreading
08.xii.1999 : GC : tagging
14.i.2000 : ER : proofreading SGML
14.i.2000 : ER : converting to HTML 4.0
7.ix.2001 : ER : header and footer reformatted; substantive content of file not changed
Excerpt from nbcnews.com
By Devin ColdeweyNo one seems to know much about the Air Force's X-37B secret space plane except that it appears to be working exactly as designed. The unmanned Boeing-built craft, which resembles a miniature space shuttle, returned to Earth on Friday after nearly two years — 674 days, to be exact — in space. It's the X-37B program's third mission to space and by far the longest.
The plane landed at 9:24 a.m. local time on Oct. 17 at Vandenberg Air Force Base in California, the Air Force's 30th Space Wing announced.
"The 30th Space Wing and our mission partners, Air Force Rapid Capabilities Office, Boeing, and our base support contractors, have put countless hours of hard work into preparing for this landing and today we were able to see the culmination of that dedication," Colonel Keith Balts, 30th Space Wing commander, said in a release. "I'm extremely proud of our team for coming together to execute this third safe and successful landing. Everyone from our on console space operators to our airfield managers and civil engineers take pride in this unique mission and exemplify excellence during its execution."
But just what did the X-37B do up there? Officially, the Air Force isn't telling.
What is known is that the X-37B has no human pilot, or at least not one in its windowless cockpit. It's operated remotely and lands on its own.
The plane's size means there isn't room on board for much except avionics equipment, fuel for the thrusters, and a mysterious cavity about the size of a truck bed that could contain all manner of sensors, experiments, hardware — perhaps some bacterial colonies, or a bomb. No one can be sure what's inside.
Untersberg is a mountain on German-Austrian border which is one of the key vortex points for the planetary liberation. For many millennia, many caves on the mountain served as entry points into vast underground tunnel system which led into...
I originally posted this article a couple of years ago, but its one of my favorite of all the articles I have shared over the years here at Ascension Earth. I feel this very real experience is worth sharing with you all once again, and I hope you enjoy it as much as I enjoy sharing it with you.
Greg
In a recent article, I shared the story of my Uncle Sonny who, upon leaving this realm from his hospital bed, emphatically and excitedly claimed his friends who had passed on years before him had come for him and were standing right there in the corner of the small hospital room waving him to come with them. My uncle had awoken from a coma he was under for weeks for just that moment, and upon the site of his friends smiling and waving to him he closed his eyes and left this Earth, I am sure to follow his friends into the afterlife.
My uncle though, is not the only member of our family who has left one last gift for our family, as my mother also left this Earth just one year ago and she too had one last remarkable tale of her own to tell before she said goodbye to all of us. During a long surgical procedure that my mother survived, she was given the opportunity to leave here. After my mother awakened after her surgery in her hospital recovery room, this is what she had to share with all of us. My mother said that during her surgical procedure she suddenly materialized in a small, plainly decorated room. There in front of her was a table with a small glass filled to the top with crystal clear water. She didn't know why the glass of water sat there on the table, and before she could even think about it too long the door to the room opened and a young, handsome man walked in. She said he looked in his early 20s, which corroborates other evidence that beyond the veil of our current reality we can choose our own age and it appears that the low 20s are a very popular choice.
So this young man walked in and he greeted my mother by saying hello Anne, as if he knew her, and I'm sure he does. Without any further conversation he simply said, ‘If you are now ready to leave Earth and return home all you need to do is drink some of the water from this glass. I'm going to leave now for a few minutes to let you think about this and when I return, if you have drank any water from this glass you can come with me through this door. If I return and you have not drank any of the water from this glass, this will be your answer that you are not yet ready to leave your current life and you will be returned to your body back in the hospital.’
The young man then exited the small room and was gone, according to my mother’s account, for about three or four, maybe five minutes tops. My mother thought carefully about whether she wished to leave her life and her family here on Earth, and finally decided to leave the glass of water on the table untouched. The young man, who my mother refers to as one of her spirit guides, though she did not recognize him, returned to the room, looked at the glass of water on the table and said, ‘Okay Anne, then you will now return to your body in the hospital.’ My mother then had second thoughts and said to her guide, ‘Wait, I think I changed my mind. I want to drink some of the water.’ The young man looked at her and surprised her greatly when he said, ‘Sorry, you have already made your choice and now you must return to your life and to your body in the hospital.’
When my mother told us this story we all broke out in laughter and my mother laughed the hardest, saying, ‘Of all the spirit guides in the world I get some kid whose a stickler for the rules.’ My mother always had a great sense of humor and I thank her for that, because I believe I have inherited mine from her side of the family. I'm sure her spirit guide was strictly following procedure, and I am also sure he is a very gifted guide. One would have to be if they were charged with watching over our big family, as every one of us is certainly a handful, and that's putting it mildly.
My mother returned to her body and awoke in the recovery room where she immediately shared with us her story. There is no way I would ever believe that she was hallucinating or anything like that, and this is also quite out of character for her, as she has never felt comfortable speaking about spirituality or life after death or anything of that nature. She certainly was quite surprised to be standing in a room with her spirit guide who offered her the choice to return home. She couldn't stop thinking about what existed beyond the door of that small room, and she immediately knew that if she was ever offered a sip of that water again she would not hesitate to quench her thirst for adventure and a new beginning. She felt she had made a mistake not sipping the water, and she felt she allowed the fear of leaving here and the fear of leaving her family behind to influence greatly her choice, though, she has selflessly looked after us long enough and she certainly deserves the paradise that awaited her just beyond that door.
My poor mom suffered as well after hesitating to take a sip of that water, as she was in much pain in the days following her surgery. It would not be long before she received a second chance however, and although she did not get the chance to share another story with us of her amazing experience in the afterlife, I’m convinced that somewhere a half filled glass of water sits on a table, and a girl, young again, smiles and laughs with all her old friends.
Greg Giles
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