If we assume that the distances of these were approximately the same, then at the equator of the planet would be such cracks from 60 70. By the time when the initial pieces thus separated, would be elevated above the planet's surface to a height of 1 mile, resulting the cracks would have on the surface a width of approximately 170 yards. These large masses during their movement from the centre would, of course, themselves start to fall apart, especially on their surfaces. But, leaving side of the resulting complications, we see that when the masses moved to out for 10 miles, then every crack between them would be a mile in width. Despite the action of the vast forces would have to undergo some period of time before these are extremely large pieces of bark may to get any significant speed. Maybe our calculations will be slightly lower than it should be, if we assume that it would take 10 seconds to raise them for the first mile, and that after 20 seconds they would go up to 4 miles and by the end of 30 seconds 9 miles. Assuming it is, ask what would happen in each the crack depth of a thousand miles, which for half a minute revealed almost a mile, and in the next half-minute was formed a hole 3 miles width. Primarily it would have to fly huge fountains molten metals, comprising an internal liquid layer, and being thrown into space, these fountains would have to be divided into a relatively small mass. Then when the hole has reached least a few miles wide, after the molten metal would have to follow gaseous matter of the same density, which erupted along with the molten metals. Soon gases would cause part of the liquid layer, constantly Contracting while in this vortex is not rushed millions small masses, the smaller mass of billions and trillions of drops.
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If we assume that the distances of these were
approximately the same, then at the equator of the planet would be such cracks from 60
70. By the time when the initial pieces thus separated,
would be elevated above the planet's surface to a height of 1 mile, resulting
the cracks would have on the surface a width of approximately 170 yards. These
large masses during their movement from the centre would, of course, themselves
start to fall apart, especially on their surfaces. But, leaving
side of the resulting complications, we see that when the masses moved to
out for 10 miles, then every crack between them would be a mile in width.
Despite the action of the vast forces would have to undergo some
period of time before these are extremely large pieces of bark may
to get any significant speed. Maybe
our calculations will be slightly lower than it should be, if we assume that
it would take 10 seconds to raise them for the first mile, and that
after 20 seconds they would go up to 4 miles and by the end of 30 seconds 9
miles. Assuming it is, ask what would happen in each
the crack depth of a thousand miles, which for half a minute revealed
almost a mile, and in the next half-minute was formed a hole 3 miles
width. Primarily it would have to fly huge fountains
molten metals, comprising an internal liquid layer, and being
thrown into space, these fountains would have to be divided into
a relatively small mass. Then when the hole has reached least a few
miles wide, after the molten metal would have to follow
gaseous matter of the same density, which erupted along with
the molten metals. Soon gases would cause part of the liquid
layer, constantly Contracting while in this vortex is not rushed millions
small masses, the smaller mass of billions and trillions of drops.
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