Geology And Geophysics
Lava flow during a rift eruption at Krafla volcano, northern Iceland, in 1984.

Geomagnetic Pole Shift Triggering Massive Superquakes



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Lava flow during a rift eruption at Krafla volcano, northern Iceland, in 1984.
Terrence Aym's image for:
"Geomagnetic Pole Shift Triggering Massive Superquakes"
Caption: Lava flow during a rift eruption at Krafla volcano, northern Iceland, in 1984.
Location: 
Image by: Michael Ryan, U.S. Geological Survey.
© Public domain - contains materials that originally came from the United States Geological Survey http://commons.wikimedia.org/wiki/File:Lava_flow_at_Krafla,_1984.jpg

Like the conductor of some mad orchestra, the twisting magnetic field is creating a perfect harmony of catastrophe, death and destruction.

As massive earthquakes rip the earth's crust, destroy cities and kill many thousands, scientists that have warned of the relationship between the ongoing magnetic polar shift, the planet's molten cores and tectonic plates are scrambling to recheck their calculations.

The titanic 9.1 superquake that destroyed much of northeastern Japan is a symptom of the growing devastation reverberating around the globe as the geomagnetic field continues to relentlessly warp, fluctuate and mutate.

Both the superquake and super-tsunami were generated by a gigantic tear in the earth's crust: the North American plate snapped upward. The mammoth fissure—150 miles long and 50 miles wide—gapes like a deadly wound in the seabed, plunging downwards into the depths of the crumbling, unstable mantle.

Changes in the geomagnetosphere affect plate tectonics

Most people are unaware that magnetic field fluctuations can precipitate earthquakes and initiate strange mass animal behavior—bizarre behavior like that reported since the final months of 2010.

Yet it's been demonstrated that changes in the geomagnetosphere affect the Earth's plate tectonics. The reason why tectonics are affected has to do with how the Earth is built geologically. The planet's primarily a core of superheated, dense viscous liquid with a relatively thin crust floating on the surface. That segmented crust—like a cracked pie crust—is what comprises the tectonic plates. They are in constant movement chiefly due to massive currents deep within the planet's mantle and molten core.    

The edges where two plates meet are called faults. Faults relieve the titanic internal pressure of the planet. The faults buckle and create mountains, rifts, and volcanic conduits. Some faults are structured different than others and exhibit different qualities.

Geodynamo creates earth's magnetic field

The mighty currents of molten rock, under intense pressure, boil beneath the crust creating earthquakes, volcanoes and continental drift. It is also the geodynamo that creates the earth's magnetic field and the interaction with the solar magnetosphere can initiate plate drift, tensions and the massive buckling and shearing between the plates called faults. The movement along the fault lines is called an earthquake.

Geomagnetic flux, often a precursor to mighty quakes, is sometimes accompanied by strange harmonics: people see colors dancing in the sky or hear what sounds like discordant music.

The growing abberations of the magnetic field—and the increasing level activity of the sun—is symptomatic of the change in the earth's core. A dangerous change. An uncontrollable change. A change that is leading to the possibility of greater and greater disasters.

Volcanic activity will also increase. The evidence is there.

Japan's superquake was followed by dozens of severe aftershocks and then an entirely new quake on a separate fault in central Japan measuring 6.6 magnitude.

Hours later a volcano in Indonesia along the famous Pacific Rim 'ring of fire" exploded into an intense eruption.

Like the conductor of some mad orchestra, the twisting field creates a perfect harmony of catastrophe, death and destruction.

The ominous emergence of magnetic torsion fields

As the flux in the Earth's dynamic magnetic field becomes more erratic and the intensity of the field fluctuates to a greater degree, the formation of energetic torsion fields withing the electrical matrix can increase.

A torsion field, as defined by A. Akimov, can manifest within an electrical field in a state of flux. They are distinct energy fields that can interact and affect both energy and matter. Some experimenters have found evidence that their emanations sometimes appear to exceed the speed of light.

Torsion fields can change the light frequency of laser beams, affect electrical components, modify gravity waves, and impact biological processes.

Beyond that, torsion fields can go rogue, create escalating feedback by looping upon themselves and generate massive, uncontrollable  forces upon the spinning molten core through permutations and episodes of erratic spin and pressure. It can be measured and deduced by the magnetic flux using supercomputers. But the data produced is always after the fact and is useless as a tool for prediction.

It serves only as a means to determine exactly what it was that killed or displaced hundreds of thousands of people.

As the field effects intensify and the geomagnetic field becomes ever more erratic, more superstorms can erupt into global titans of fury; more superquakes can occur shifting coastlines, submerging islands, and destroying whole regions; and more volcanoes can reignite bringing superheated death and destruction to the surface from the very bowels of the earth.

And when all of that occurs the impotent columns of mathematical formulas in a research notebook will have little, if any, value.

Links

"Ultralow-Frequency Magnetic Fields Preceding Large Earthquakes" - Antony C. Fraser-Smith Stanford University

See also: "Magnetic Fields and Earthquakes" - Antony C. Fraser-Smith Stanford University

"Statistical relationship of strong earthquakes with planetary geomagnetic field activity" - Harvard

"Detecting earthquake precursors by monitoring the earth's electrical field" - Dionysios Dimakos

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ARTICLE SOURCES AND CITATIONS
  • InfoBoxCallToAction ActionArrowhttp://soe.stanford.edu/pubs/Published%20Eos_1445.pdf
  • InfoBoxCallToAction ActionArrowhttp://adsabs.harvard.edu/abs/1984RpESc.......97P
  • InfoBoxCallToAction ActionArrowhttp://www.vlf.it/dionysios/dionysios.html