Note: written on Dec 15, 2001.
Mountain building during this coming shift will be in proportion to the compression any given range comes under.
Those areas in the world where mountain building has occurred in the past are obvious, as sheer rock is broken into
cliffs or juts skyward like a missile or monstrous rocks are in a jumble. The rock is fresh, not weathered and broken
down, and often covered with trees or vegetation, soil having formed from the dust that lodges there. Often these are
called new mountain ranges or old ranges, to differentiate. Why would a new range become an old range, and how
might this information help those seeking safe places during the coming shift?
At one point in the Earth's history, the land mass was all in one clump, the Earth having been injured with a gaping
wound where the Pacific is now, so that it became lopsided. Water pooled in the low places, leaving the land all on one
side. Repeated pole shifts jerked this land mass to and fro until weak spots tore and the continental drift, or rip as we
prefer to call it, began. Very old land shows less marks of mountain building and more hardened mud flats, but in the
interim, when the plates were separating, lava hardening in between, and then thrust against each other during
forthcoming pole shifts, mountain building began.
The Himalayas are a good example of a spot on the Earth where mountain building invariably occurs. These
mountains are backed up against a solid old land mass, with broken and smaller plates subducting under them at
each shift. Thus, these are both old and new mountain, never escaping fresh discombobulating.
The mountains lining the west coast of both North and South America are likewise never at peace, as they form
the cutting edge of land being pushed into the Pacific where the plates in the Pacific are being pushed under this
edge. Each time the Pacific shortens, these ranges go through rock and roll, with new mountain building
occurring.
The mountains on the east coast of both the North and South Americas are old mountains, with notably not
volcanoes active and no stress toward mountain building because the land to the east is being stretched, not
compressed. These old mountains were built when the plates first separated and were bumping against each
other during those early periods. These times are past, for these lands masses, now.
This is likewise the case within Africa, where the mountains are covered with trees unless to high to sustain
vegetation and the only sign of stress volcanoes caused by weak places make thin by the stretch of the land.
African volcanoes, recently active, can be expected to erupt, but very ancient volcanoes will not as the stress is
less on this land mass now.
The high deserts in Mongolia and the Urals in Russia are likewise not under stress, being too far inland to suffer
subduction of plates, and not being stretched. But where the land masses of Russia and Area front the Pacific
Rim, volcanoes will erupt with great force. This will devastate land from the Russian peninsula in the north
through Japan to Indonesia in the south. Mountain building in these areas will not be noticed, as death will come
from volcanic hot ash and gas.
The Mediterranean area is a weak spot in the plates, where movement has invariably occurred. During the times
when the plates were separating, the Alps were built, due to bumping between the plates on the move. As Africa
is a very solid land mass, Europe invariably was the loser during this bumping, creating the Alps. However,
during this coming shift, the strong stretch of the Atlantic will pull Africa away from Europe, not a push toward.
The volcanoes in the Mediterranean will explode due to churning of the core, and an increased thinning in the
crust. All mountains surrounding the area will not experience strong mountain building, as a consequence.
http://www.zetatalk2.com/poleshft/p137.htm[2/5/2012 9:55:31 AM]
ZetaTalk: Mountain Ranges
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ZetaTalk: Sinking or Rising
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ZetaTalk: Sinking or Rising
Note: written on Jun 15, 1997.
Periodically during severe pole shifts, land rises or drops, sometimes moving under the waves. This is caused quite
naturally by moving plates, which adjust to being squeezed against each other or pulled apart. Suddenly submerged
land can be the result of either dynamic. Likewise, land long under the sea can suddenly pop up, presenting gasping
and dying sea life and deep muck that eventually dries to form new and very fertile soil. Continents pulled apart, as in
the steadily widening St. Lawrence Seaway or African Rift, can cause land along the perimeter to rise, as the stretch
over the curvature of the Earth has been removed, so that the natural buoyancy or shape of the land can take effect.
Thus the land in the New England area of America is expected to lift somewhat when the St. Lawrence Seaway tears
further apart. Continents pulled apart, as in the widening Atlantic rift, cause sinking land along the shores for several
reasons:
1. The curvature of the Earth causes the mid-point between continents being pulled apart to drop.
2. There is less crust to cover the magma underneath, so that rips in the crust form at the weakest or lowest points.
3. Ripped crust at the bottom of ocean rifts allows heavy land along the edge to lose its support, thus it can sink
into the magma.
Continents squeezed together invariably find one plate or the other acting as the loser, subducting or fracturing into
pieces that slant at an angle to form new mountain ranges. For every adjustment where the continents or land are being
wrenched apart, there is a collateral squeezing of plates elsewhere. On the Earth, this squeezing occurs along the
Pacific Rim, with Japan and the Philippines, along with the whole western coast of the Americas, getting the brunt of
this squeeze. This is often the case, and thus as a result of the coming pole shift, new land will emerge near Antarctica
between the tip of Africa and South America due to pressure against the western coast of South America. Due to the
strength of the Antarctic plate, this pressure will be relieved by allowing the Antarctic plate to ride over the bordering
plates, thus creating new land.
Where this squeezing causes new land to rise is where plates fracture, freeing a portion of a plate to act on its own.
Squeezing can force land under, to relieve the stress, but can also pop land up, so that it rides above another plate.
What occurs when an overriding plate moves across or pushes against an underlying plate depends primarily on what
the underlying plate presents. If the land is fairly flat, the overriding plate will go for a ride, with anything on the
underlying plate scraped along or crushed underneath. If the land is hilly or mountainous itself, the hills and mountains
will be compressed and crumpled, creating a situation where rocks and earth are flying about, tumbling and spewing.