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Difference between revisions of "Atmolayer Lip Hypothesis"

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See this interesting video about what happens to balloons when they are frozen (runtime: 4:26)
 
See this interesting video about what happens to balloons when they are frozen (runtime: 4:26)
  
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Description: {{cite|On the left the solar system is evolved forward in time using the Forward Euler method while on the right the Symplectic Euler method is used.  Both schemes may be evaluated explicitly; however, it should be noted that the Symplectic Euler method is defined implicitly and is only made explicit due to the form of the Hamiltonian being separable into functions of purely the positions and momenta.  The Forward Euler scheme does not preserve any properties of the system and is only 1st order accurate.  The Symplectic Euler scheme is also only 1st order accurate, but it preserves the structure of the elliptical orbits and Hamiltonian providing the time step is reasonably small.  Both methods used the same time step of 200 days with the rest of the parameters being drawn from Hairer, Lubich, and Wanner's text on geometric integration as in my previous video https://www.youtube.com/watch?v=b3J3lDYQRAs}}
 
  
 
==Freezing Atmolayer==
 
==Freezing Atmolayer==

Revision as of 20:15, 13 April 2020

The Flat Earth does not necessarily need to be physically infinite in order to contain the atmosphere. Just very big. Often we might hear "infinite earth" from Flat Earth proponents as an analogy for what exists beyond the 150 foot wall of ice at the Antarctic coast; a stretch of land incomprehensible by human standards.

In order for barometric pressure to rise and fall, an element of heat must be present. Heat creates pressure. A lack of heat results in a drop in pressure. These two elements are tightly correlated in modern physics.

In our local area the heat of the day comes from the sun, moving and swashing around wind currents between areas of low pressures and areas of high pressures with its heat. Beyond the known world, where the rays of the sun do not reach, the tundra of ice and snow lays in perpetual darkness. If one could move away from the Antarctic rim into the uncharted tundra the surrounding temperatures, and therefore pressures, would drop lower and lower. Defining the exact length of the gradient would take some looking into, but at a significant distance past the edge of the Ice Wall temperatures will drop to a point where barometric pressure nears the zero mark. At this point, whether it be thousands or millions of miles beyond the Antarctic rim, the environment will gradually match that of background space, and the world can physically end without the atmosphere leaking out of it.

The atmosphere may very well exist as a lip upon the surface of the earth, held in by vast gradients of declining pressure.

Freezing Balloons Example

See this interesting video about what happens to balloons when they are frozen (runtime: 4:26)

Freezing Atmolayer

It is known that temperatures in frigid environments such as Antarctica can get so cold that the atoms will freeze and drop out of the air entirely. This may be the fate of the atoms of the atmoplane at its extremes. Take a look at what happens at Antarctica:

http://scienceline.ucsb.edu/getkey.php?key=219

For scientists living [in Antarctica] in the dead of winter it can get as cold as minus 80 degrees Celsius. This makes it very hard for them to breath outside without a special air supply. At such cold temperatures, the carbon dioxide freezes and drops out of the air.
UCSB ScienceLine


Another source:

https://stevengoddard.wordpress.com/2014/06/03/antarctica-gets-cold-enough-to-freeze-co2/

Antarctica Gets Cold Enough To Freeze CO2
Posted on June 3, 2014 by stevengoddard

Last year, Antarctica reached -135ºF, which is 27ºF below the freezing point of CO2 at atmospheric pressure. This is cold enough to freeze CO2 right out of the air.
Steven Goddard


Freezing temperatures of other gasses:

Argon freezes at -308.7 °F
Nitrogen freezes at -346.18 °F
Oxygen freezes at -360.9 °F

Liquid Nitrogen Temperature Range: Between -320 °F and -346 °F

Liquid Nitrogen can freeze atmospheric atoms right out of the air. One may suggest that Oxygen, while perhaps not technically frozen at Liquid Nitrogen levels, does not have the potential to stay airborne at those temperatures. A little past that and it becomes technically frozen.

From http://scienceline.ucsb.edu/getkey.php?key=219

The first gas to freeze would be water vapor. This is why the air is so dry in very cold places. Then carbon dioxide would freeze, and then nitrogen. The last gases to freeze would be oxygen and argon.
UCSB ScienceLine


Questions and Answers

Q. From some sources it appears that Antarctica at sea level is quite a high pressure area, which doesn't play well with the idea of beyond it being increasingly lower pressure areas.

A. It has been demonstrated through a number of experiments that in a closed system there is a correlation between heat and barometric pressure. However, the atmosphere is not a container. Air is free to rise, cool, fall, etc. The behavior of the climate is very complex, but over a greater distance, beyond the heating influences of the sun's light, the behavior would presumably more closely match what is seen in a closed system.

See also: