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3/4/2012 — Steaming Plumes appear in Arkansas = DORMANT VOLCANOES BEING FRACKED !

 

It took me a minute to find it — but now you can see it for sure — a Fracking (frac well drilling) operation JUST WEST of the Plume area — so all together we have a giant natural gas frack operation — a series of dormant volcanoes, town names like Sulphur Springs, Hot Springs, and Crater of Diamonds/Murfreesboro — the plumes appear on VISIBLE SATELLITE from space.. only for a short time , at MULTIPLE SITES always near sunset… and gone by the AM (thus ruling out a large fire of some kind).

To me, IMO, it has all the pieces there to put together.. a geologic steaming event of some kind … the steam is coming from this dormant volcanic area BEING FRACKED (injected with water) !!!!!


Great idea to INJECT WATER into an area permeated with old deep volcanic tubes connected to very old magma chambers…….. I think it is highly possible that water injected from this nearby fracking operation could indeed cause a STEAM PLUME event to occur at the dormant volcano chain right next door !

Not a good development for the area. This increases the chances of a larger seismic event along the New Madrid Seismic Zone… and may indeed be the VERY CAUSE of our recent midwest earthquake uptick… now there is a DIRECT CONNECTION between fracking / dormant volcanoes / and plumes appearing .

todays plumes seen in the 3/3 video:

35 14 21.13 N , 93 28 53.62 W location of the most current plume appearing on visible satellite = west of Sulphur Springs AR.

34°46’11.98″N , 94°11’33.94″W location of the 2nd plume (central west Arkansas) near the state line .

Here are the past two videos on the subject:

3/3/2012 — A must see if you want to know what Im talking about in this current video above:
http://www.youtube.com/watch?v=FcJjTQyZW5s&feature=channel_video_title

Original Video from 3/1/2012 showing multiple plumes, multiple areas at the same time erupting(appearing):

http://www.youtube.com/watch?v=dEMR2BSgBwg&feature=channel_video_title

 
Here are my past videos on all the different plumes appearing on the west coast :

http://www.youtube.com/results?search_query=dutchsinse+pisgah+volcano+volcanos+volcanic+erupt+plume+cloud+unrest&oq=dutchsinse+pisgah+volcano+volcanos+volcanic+erupt+plume+cloud+unrest&aq=f&aqi=&aql=&gs_sm=3&gs_upl=1035287l1071324l0l1072527l98l94l10l0l0l4l780l20207l20.27.11.8.7.10.1l84l0

Here are my past videos on fracking/earthquakes:

http://www.youtube.com/results?search_query=dutchsinse+frack+fracking+frac+well+earthquake+earth+quake+quakes+&oq=dutchsinse+frack+fracking+frac+well+earthquake+earth+quake+quakes+&aq=f&aqi=&aql=&gs_sm=3&gs_upl=23383l43444l0l44157l76l74l3l0l0l2l676l13027l26.24.7.7.3.4l71l0

Here are my past videos on dormant / extinct volcano recent uptick in earthquake in activity:

http://www.youtube.com/results?search_query=dutchsinse+dormant+volcano+volcanos+volcanic+earthquake+earth+quake+quakes+&oq=dutchsinse+dormant+volcano+volcanos+volcanic+earthquake+earth+quake+quakes+&aq=f&aqi=&aql=&gs_sm=3&gs_upl=54987l78592l0l82219l89l85l5l9l10l4l656l16045l19.24.8.6.6.8l71l0

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1/3/2012 — VISIBLE TONIGHT in North America — Large meteor shower — Quadrantids

watch the video here:

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Go meteor hunting tonight on the SLOOH telescope (if you can’t get outside to view this first hand):

http://events.slooh.com/

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General information about Quadrantids

The first major shower of 2012 is the Quadrantids meteor shower. This annual shower has one of the highest predicted hourly rates of all the major showers, and is comparable to the two of the most lively, the August Perseids and the December Geminids. This celestial event is active from December 28th through January 12th and peaks on the morning of January 4th. In relation to meteor showers, the peak is defined as the moment of maximum activity when the most meteors can be seen by the observer.

While the plus side of this annual shower is its ability to produce fireballs, and its high hourly rates, the downside is its short peak. Quadrantids has an extremely narrow peak, occurring over just a few short hours. The Quadrantids are also well known for producing fireballs, meteors that are exceptionally bright. These meteors can also, at times, generate persistent trails (also identified as trains).

Those living in the northern hemisphere have an opportunity to experience a much better view of the Quadrantids, as the constellation Boötes never makes it above the horizon in the southern hemisphere. This is great for those living in North America, much of Europe, and the majority of Asia.

Unfortunately, those of you living in Australia and lower portions of South America will have a difficult time observing the Quadrantids. Observers in higher latitudes will have better gazing conditions, but nevertheless will need to be wary of cloud cover, as conditions are typically cloudy during this time of year.

The Quadrantids in 2012

This year, the large and bright waning gibbous Moon (72% full) will coincide with the peak of the Quadrantids meteor shower. This is a stark contrast to the Quadrantids of last year, which occurred during a moonless night. While the light of the moon may reduce the quantity of meteors you’ll be able to see, you should still be able to observe all but the faintest meteors. While thus year will not be ideal for watching this January event, those willing to patiently wait it out in the cold (or warmth, for those in warmer environments) will be treated to the very first major meteor shower of 2012.

This year, the large and bright waning gibbous Moon (72% full) will coincide with the peak of the Quadrantids meteor shower. This is a stark contrast to the Quadrantids of last year, which occurred during a moonless night. While the light of the moon may reduce the quantity of meteors you’ll be able to see, you should still be able to observe all but the faintest meteors. While thus year will not be ideal for watching this January event, those willing to patiently wait it out in the cold (or warmth, for those in warmer environments) will be treated to the very first major meteor shower of 2012.

The radiant of a meteor shower is the point in the sky from where the meteors appear to come (or radiate) from. In the case of Quadrantids, its radiant lies within the now extinct constellation Quadrans Muralis. Unlike all the other major annual showers, this one is named after a constellation which longer exists. For example, the Perseids meteor shower, occurring in August, is named after the constellation Perseus. The Geminids meteor shower, occurring in December, is named after the constellation Gemini.

The constellation Quadrands Muralis was made up of a faint group of stars between the top of Boötes and the handle of the Big Dipper. Quadrands Muralis is now part of the constellation Boötes, thus making Boötes the radiant of the Quadnrantids meteor shower. To find the location of the radiant, we recommend you first find Polaris (a middling-bright star, also known as the North Star) and observe in close proximity to that area. For more specificity, it lies between the end of the handle of the Big Dipper and the four-sided figure of stars marking the head of the constellation Draco.

Particles from a minor planet, potentially hundreds to see

While this wintery spectacle appears to radiate from a constellation, they are actually caused by the Earth passing through the dust particles of the minor planet 2003 EH1. Every January, Earth passes into a trail of dust left by this minor planet, and as a result, all the dust and debris burning up in our atmosphere, produces the spectacle known as the Quadrantids meteor shower, or what are popularly recognized as “shooting stars”.

There’s no danger to sky watchers, though. The fragile grains disintegrate long before they reach the ground. While the meteors are certainly bright, they are typically not much larger than a grain of sand. However, as they travel at immense speeds, these tiny particles put on an exciting show.

During the 4th of January, shower rates will be a portion of what they could be due to the radiant lying low in the northwestern sky. On average, and under clear skies, observers should see 40 to 70 meteors per hour. However, every so often, these rates can exceed up to 90 meteors per hour in dark-sky locations. In ideal condition—no cloud cover, precipitation, city lights, and no moonlight, the Quadrantids meteor shower should host a spectacular viewing experience!

How do I know the sky is dark enough to see meteors?

If you happen to live near a brightly lit city, if possible, we recommend that you drive away from the glow of city light. After you’ve escaped the glow of the city, find a dark, safe, and possibly isolated spot where oncoming vehicle headlights will not occasionally ruin your sensitive night vision.

Look for state or city parks or other safe, dark sites. Once you have settled down at your observation spot, face toward the northeastern portion of the heavens. This way you can have the Quadrantid’s radiant within your field of view. If you can see each star of the Little Dipper, your eyes have “dark adapted,” and your chosen site is probably dark enough. Under these conditions, you will see plenty of meteors.

For many meteor showers it is often recommended to look straight up, but for this year’s Quadrantids we advise that observers face as low as possible toward the horizon without being looking at the ground. In other words, have the bottom of your field of view on the horizon. While you can still catch meteors while looking straight up, you will have an improved opportunity to observe more by looking toward the horizon. Meteors will grab your attention as they streak by!

Waning Gibbous. Quadrantids shower gazing conditions will not be ideal. The moon will obstruct all but the brightest Quadrantids.
First apeared: Early-1830’sName origin: Appears inside the constellation Boötes.Parent: 2003 EH1 (minor planet)Radiant positon: 230° (RA) +49° (DEC)

Active start date: December 28th

Peak date: January 4th (7:30UTC)

ZHR/Rate on peak: 60-120 per hour

Active end date: January 12th

Quadrantids 1
Quadrantids 2
Quadrantids 3

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CNN article shown in the video:

Quadrantid meteor shower to light up night sky

A false-color image of a rare early Quadrantid was taken by a NASA meteor camera in 2010.

Quadrantid meteor shower to light up night sky

Meteor watchers in North America can expect to see 60 to 200 meteors an hour streak across the sky early Wednesday.

NASA says the Quadrantid meteor shower should be perfect for viewing around 3 a.m. local time Wednesday after the waxing gibbous moon sets.

But the light show won’t last long, NASA says only a few hours.

The Quadrantids were first noted in 1825 and got their name from the constellation of Quadrans Muralis, which is no longer considered a constellation by astronomers, according to NASA.

The material that is burning up in Earth’s atmosphere during the Quadrantids likely comes from a comet that broke into fragments centuries ago, NASA says.

“After hundreds of years orbiting the sun, they will enter our atmosphere at 90,000 mph, burning up 50 miles above Earth’s surface,” a NASA press release says.

 

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http://spaceweather.com/meteors/quadrantids/quadrantids.html

The Quadrantid meteor shower is one of the year’s best, often producing more than 100 meteors per hour from a radiant near the North Star. In 2012 forecasters expect the shower to peak around 07:20 UT (02:20 am EST) on Wednesday, January 4.
The peak is brief, typically lasting no more than an hour or so, and it does not always occur at the forecasted time, so observers are encouraged to be alert for meteors throughout the early hours of January 4th. Although the Quadrantids are a major shower, they are seldom observed. One reason is weather. The shower peaks in early January when northern winter is in full swing. Storms and cold tend to keep observers inside.
Above: In 2008, NASA-supported scientists flew an airplane above the clouds and over the Arctic Circle to gain a good view of the shower. Jeremie Vaubaillon of Caltech recorded these Quadrantids streaking through the aurora borealis outside the window of the plane.
Another reason is brevity. The shower doesn’t last long, a few hours at most. Even dedicated meteor watchers are likely to miss such a sharp peak. In his classic book Meteor Astronomy, Prof. A.C.B. Lovell lamented that “useful counts of the Quadrantid rate were made in [only] 24 Januaries out of a possible 68 between 1860 and 1927. … The maximum rate appears to have occurred in 1932 (80 per hour) although the results are influenced by unfavorable weather.”
The source of the Quadrantid meteor shower was unknown until Dec. 2003 when Peter Jenniskens of the NASA Ames Research Center found evidence that Quadrantid meteoroids come from 2003 EH1, an “asteroid” that is probably a piece of a comet that broke apart some 500 years ago. Earth intersects the orbit of 2003 EH1 at a perpendicular angle, which means we quickly move through any debris. That’s why the shower is so brief.
Quadrantid meteors take their name from an obsolete constellation, Quadrans Muralis, found in early 19th-century star atlases between Draco, Hercules, and Bootes. It was removed, along with a few other constellations, from crowded sky maps in 1922 when the International Astronomical Union adopted the modern list of 88 officially-recognized constellations.
The Quadrantids, which were “re-zoned” to Bootes after Quadrans Muralis disappeared, kept their name–possibly because another January shower was already widely-known to meteor watchers as the “Bootids.”Got clouds? No problem. You can stay inside and listen to the Quadrantids. Tune into SpaceWeather Radio for a live audio stream from the Air Force Space Surveillance Radar. When a Quadrantid passes over the facility, you will hear a “ping” caused by the radar’s powerful transmitter echoing from the meteor’s ion trail. During the shower’s peak, the soundtrack is guaranteed to entertain.