Tag Archives: de vulcão

5/20/2016 — West Coast United States / Oregon struck by M4.9 (M5.0) earthquake

A noteworthy M4.9 earthquake has struck off the West coast of the United States (Pacific Northwest / Oregon).

west coast oregon earthquake may 20 2016

It has been several weeks (going into months) since we’ve seen this size earthquake occur off the West coast of the United States.

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This earthquake was expected, and forecast to occur.

See the earthquake forecast video issued for this week.  The forecast specifically warned the coast of Oregon for M4.0 to M5.0 earthquake activity to strike.

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As the above video explained roughly 3-4 days ago, we were watching the coast of Oregon based upon the movement occurring in other nearby areas.

Swarms of earthquakes struck at dormant volcanoes up the coast preceding this event.  These volcanic earthquakes are always a warning sign of coming larger release off the coast.

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Information on this earthquake from the USGS:

Magnitude/uncertainty 4.9 mb± 0.0
Location/uncertainty 43.965°N 127.921°W± 8.3 km
Depth/uncertainty 10.0 km± 2.0
Origin Time
Number of Stations
Number of Phases 121
Minimum Distance 312.6 km (2.81°)
Travel Time Residual 0.98 s
Azimuthal Gap 199°
FE Region OFF THE COAST OF OREGON (30)

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5/03/2016 — Scientists say CRATON EDGE Earthquakes caused by new UPWELLING magma from the ASTHENOSPHERE

The American Geophysical Union, and the Journal for Geophysical Research has printed a new study ON THE CRATON EDGE and the ASTHENOSPHERE .

Wait a second!  Earthquakes striking along interior craton plate edge up the East coast, are related to movement in the Asthenosphere?

Earthquakes related to upwelling pressure from magma below?

Where have we heard this before?

The new findings conclude that the interior “edge” of the craton (plate) is breaking off into the Asthenosphere far below.  New magma is then rising below the North American plate, and PUSHING UP to fill the void left from the broken off pieces of the plate.

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asthenosphere
Above: Diagram showing the Asthenosphere in relation to the mantle and the upper crust / lithosphere

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These new findings explain the upwelling pressure which has been displacing the fracking operations and dormant volcanoes all along the interior of the plate – causing noteworthy earthquakes as the pressure transfers upwards, and across the plate to the East.

I’ve talked about this at length, both topics have been covered in detail even recently : the interior craton moving from upwelling pressure, and the Asthenosphere causing the upwelling pressure to begin with.

past 72 hours of earthquakes north america November 25 2015 progression craton
Above: 72 hours of Earthquakes up to November 25, 2015 shows a clear progression of earthquakes along the interior craton plate edge from the West coast to the East coast, coming up from below the plate, and pushing all the way to the Southeast USA in the Carolinas from the Pacific Northwest near Washington State.

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I covered the craton movement AND the asthenosphere in this video here from last year (just one of many I’ve made over the past 6+ years on the topic):

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The new study confirms chucks of the plate are breaking off below, being replaced by new upwelling magma.

The upwelling magma below the plate also explains the metamorphic rock forming at the bottom of some deep drilled frack wells on the WEST coast, AND this explains the plumes popping off from frack wells during times of seismic unrest along the edge of the craton.

This also explains the transfer of earthquakes across the edge of the craton now that it is proved there is upwelling magma replacing rock below the plate.

We know pressure from below the plate exerts pressure on the interior edge of the craton above, which ultimately causes displacement + earthquakes to spread along the interior “edge” to the East.

craton movement feb 2016
Above: Graphic showing the interior craton “edge” and the direction of displacement that occurs from BELOW, pushing to the East Southeast while the pressure rises towards the surface. The upwelling pressure causes earthquakes along the interior edge of the plate at the weak points in the crust. Many of the weak points are man made drilling + pumping operations, as well as ancient long extinct volcanic chambers nestled into the interior of the plate.

 

Summed up, this study basically proves everything I’ve told you all for the last 6+ years about the craton, and the Asthenosphere upwelling pressure on the plate.

Love how they even go so far as to mention the East coast and Southeast volcanoes!  Pigeon mountain in Georgia didn’t make their short list though. 🙂

 

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Scientists find likely cause for recent southeast U.S. earthquakes

May 3, 2016

http://blogs.agu.org/geospace/2016/05/03/scientists-find-likely-cause-recent-southeast-u-s-earthquakes/

“The southeastern United States should, by all means, be relatively quiet in terms of seismic activity. It’s located in the interior of the North American Plate, far away from plate boundaries where earthquakes usually occur. But the area has seen some notable seismic events – most recently, the 2011 magnitude-5.8 earthquake near Mineral, Virginia that shook the nation’s capital.

Now, scientists report in a new study a likely explanation for this unusual activity: pieces of the mantle under this region have been periodically breaking off and sinking down into the Earth. This thins and weakens the remaining plate, making it more prone to slipping that causes earthquakes. The study authors conclude this process is ongoing and likely to produce more earthquakes in the future.

“Our idea supports the view that this seismicity will continue due to unbalanced stresses in the plate,” said Berk Biryol, a seismologist at the University of North Carolina Chapel Hill and lead author of the new study. “The [seismic] zones that are active will continue to be active for some time.”

The study was published today in the Journal of Geophysical Research – Solid Earth, a journal of the American Geophysical Union.

Compared to earthquakes near plate boundaries, earthquakes in the middle of plates are not well understood and the hazards they pose are difficult to quantify. The new findings could help scientists better understand the dangers these earthquakes present, according to the study’s authors.

Old plates and earthquakes

Tectonic plates are composed of Earth’s crust and the uppermost portion of the mantle. Below that is the asthenosphere: the warm, viscous conveyor belt of rock on which tectonic plates ride.

NorthAmericanPlate

A map of the North American Plate. Arrows show directions of its movement across Earth’s surface.
Credit: Alataristarion via Wikimedia Commons.

Earthquakes typically occur at the boundaries of tectonic plates, where one plate dips below another, thrusts another upward, or where plate edges scrape alongside each other. Earthquakes rarely occur in the middle of plates, but they can happen when ancient faults or rifts far below the surface reactivate.  These areas are relatively weak compared to the surrounding plate, and can easily slip and cause an earthquake.

Today, the southeastern U.S. is more than 1,700 kilometers (1,056 miles) from the nearest edge of the North American Plate, which covers all of North America, Greenland and parts of the Atlantic and Arctic oceans. But the region was built over the past billion years by periods of accretion, when new material is added to a plate, and rifting, when plates split apart. The authors of the new study suspected ancient fault lines or pieces of old plates extending deep in the mantle following episodes of accretion and rifting could be responsible for earthquakes in the area.

“This region has not been active for a long time,” Biryol said. “We were intrigued by what was going on and how we can link these activities to structures in deeper parts of the Earth.”

sidebarA CAT scan of the Earth

To find out what was happening deep below the surface, the researchers created 3D images of the mantle portion of the North American Plate. Just as doctors image internal organs by tracing the paths of x-rays through human bodies, seismologists image the interior of the Earth by tracing the paths of seismic waves created by earthquakes as they move through the ground. These waves travel faster through colder, stiffer, denser rocks and slower through warmer, more elastic rocks. Rocks cool and harden as they age, so the faster seismic waves travel, the older the rocks.

In the new study, researchers used tremors caused by earthquakes more than 3,500 kilometers (2,200 miles) away to create a 3D map of the mantle underlying the U.S. east of the Mississippi River and south of the Ohio River.

The study’s authors found plate thickness in the southeast U.S. to be fairly uneven – they saw thick areas of dense, older rock stretching downward and thin areas of less dense, younger rock.

“This was an interesting finding because everybody thought that this is a stable region, and we would expect regular plate thickness,” Biryol said.

At first, they thought the thick, old rocks could be remnants of ancient tectonic plates. But the shapes and locations of the thick and thin regions suggested a different explanation: through past rifting and accretion, areas of the North American Plate have become more dense and were pulled downward into the mantle through gravity. At certain times, the densest parts broke off from the plate and sank into the warm asthenosphere below. The asthenosphere, being lighter and more buoyant, surged in to fill the void created by the missing pieces of mantle, eventually cooling to become the thin, young rock in the images.

Mole_Hill_VA_1
Volcanoes were once active in the southeastern U.S. Mole Hill, pictured here, is a mound of volcanic rock in the Shenandoah Valley in Virginia that formed from an active volcano 48 million years ago (a relatively recent event, in geological time scales). Credit: Jstuby via Wikimedia Commons.

 

The researchers concluded this process is likely what causes earthquakes in this otherwise stable region: when the pieces of the mantle break off, the plate above them becomes thinner and more prone to slip along ancient fault lines. Typically, the thicker the plate, the stronger it is, and the less likely to produce earthquakes.

According to Biryol, pieces of the mantle have most likely been breaking off from underneath the plate since at least 65 million years ago. Because the researchers found fragments of hard rocks at shallow depths, this process is still ongoing and likely to continue into the future, potentially leading to more earthquakes in the region, he said.”