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Lisa!
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Gravity & Everest: Why Can't We Go Higher Than 10km?
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In summary, mountains are limited by the number of geophysical processes that can produce them, the strength of the rocks used, and the thickness of the crust.
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tony873004
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Don't think of the Earth as a solid sphere. It's only solid on the surface. For the most part, the Earth is a molten ball of rock. Tall structures weigh a lot. Think about ice flows. There's some terrain to them, but structures in the thousands of feet do not exist. They just sink lower as their weight increases.
Solid rock on top of liquid rock acts similarly, but structures can grow into the 10's of thousands of feet.
Mathamatically... There's some formula for what percentage of an iceberg is above water, and what percentage is below water. The formula is derived from the density of frozen water compared to the density of liquid water. With knowledge of the densities of liquid rock vs. solid rock, a similar formula should exist.
Just my guess...
Solid rock on top of liquid rock acts similarly, but structures can grow into the 10's of thousands of feet.
Mathamatically... There's some formula for what percentage of an iceberg is above water, and what percentage is below water. The formula is derived from the density of frozen water compared to the density of liquid water. With knowledge of the densities of liquid rock vs. solid rock, a similar formula should exist.
Just my guess...
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It's possible to have higher peaks than Mt.Everest.Incidentally,there used to be said that,due to the continuous advancement of the Indian tectonic plate into the Asian continent (subduction (?)),Mt.Everest would be not only growing taller,but also moving its peak towards NE (i.e.into China).
I don't know whether the latest accurate geological info still claim this thing.
Daniel.
I don't know whether the latest accurate geological info still claim this thing.
Daniel.
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Nereid
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Several levels of explanation (science, BTW, not maths; the math is just a tool):
- real mountains are made of real rocks; rocks can only be so strong, you put more rocks on top of a (max height) mountain and it collapses
- mountains on Earth can only be made by a small number of geophysical processes (e.g. volcanism, plate tectonics); there are limits on how fast each process can make mountains, bearing in mind that there are processes which wear mountains down (e.g. erosion), and this leads to a limit on how high a mountain can be
- Earthly mountain building processes in turn are driven by the bulk composition of the Earth (esp the lack of H and He, and abundance of radionuclides) and its history (esp accretion and the collision that created the Moon); these limit the strength of volcanism and plate tectonics today
Note that if the main 'mountain building' process found on most solid bodies in the solar system were primary on Earth (i.e. that we had essentially no erosion or plate tectonics), then we'd be talking about craters and basins, like Mare Orientale, Caloris, or Valhalla.
- real mountains are made of real rocks; rocks can only be so strong, you put more rocks on top of a (max height) mountain and it collapses
- mountains on Earth can only be made by a small number of geophysical processes (e.g. volcanism, plate tectonics); there are limits on how fast each process can make mountains, bearing in mind that there are processes which wear mountains down (e.g. erosion), and this leads to a limit on how high a mountain can be
- Earthly mountain building processes in turn are driven by the bulk composition of the Earth (esp the lack of H and He, and abundance of radionuclides) and its history (esp accretion and the collision that created the Moon); these limit the strength of volcanism and plate tectonics today
Note that if the main 'mountain building' process found on most solid bodies in the solar system were primary on Earth (i.e. that we had essentially no erosion or plate tectonics), then we'd be talking about craters and basins, like Mare Orientale, Caloris, or Valhalla.
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Kazza_765
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I think there may be another limitation also, I'm not sure how much of an influence it is. As Tony mentioned, the crust floats on the asthenosphere, a partially molten layer of the mantle. Beneath mountain ranges the crust protrudes into the asthenosphere in order to maintain bouyancy. I would think that at a certain depth this crust begins to melt, and the mountains will sink.
Just a thought, not sure if I'm right.
Just a thought, not sure if I'm right.
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Andre
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For starters the Astenosphere is not nearly molten let alone partially molten. It's just a wee bit more ductile than the environment like the crust and the upper mantle. The lower mantle is even more plastic again.
As far as I know, there is no theoretical limit on the hight of a mountain. Those things get a bit too complicated to model mathematically. But most factors are mentioned. Buoyancy is probably prevailing. Try to think of Earth as being fluid like water. Due to rotation and gravity forces it will attain a geodic shape, now, throw an ice cube on it and there is your mountain, the emersed part of the ice. On million years time scale Earth behaves like fluid. As the crust is much less dense than the mantle it is assumed that, in equilibrium, the dept of the crust is reflected on it's elevation, like the floating ice cube. Most of the ice is submerged. In analogy, oceanic crust is assumed to be very thin. Continental crust is much thicker to have the land float higher like the ice cube.
http://mediatheek.thinkquest.nl/~ll125/en/crust.htm
Now, if two tectonic plates collide, one will subduct, the other will pass overhead but the local thickness of the (light) double crusts increases significantly, playing bouyant ice cube on the (heavy) ductile mantle, consequently the mountain range is build. And mountains literally have deep roots of crust material (presumably).
What would limit that mountain buiklding process? Outflowing of the mountain like ice sheets do? Erosion? It's all speculation.
As far as I know, there is no theoretical limit on the hight of a mountain. Those things get a bit too complicated to model mathematically. But most factors are mentioned. Buoyancy is probably prevailing. Try to think of Earth as being fluid like water. Due to rotation and gravity forces it will attain a geodic shape, now, throw an ice cube on it and there is your mountain, the emersed part of the ice. On million years time scale Earth behaves like fluid. As the crust is much less dense than the mantle it is assumed that, in equilibrium, the dept of the crust is reflected on it's elevation, like the floating ice cube. Most of the ice is submerged. In analogy, oceanic crust is assumed to be very thin. Continental crust is much thicker to have the land float higher like the ice cube.
http://mediatheek.thinkquest.nl/~ll125/en/crust.htm
Now, if two tectonic plates collide, one will subduct, the other will pass overhead but the local thickness of the (light) double crusts increases significantly, playing bouyant ice cube on the (heavy) ductile mantle, consequently the mountain range is build. And mountains literally have deep roots of crust material (presumably).
What would limit that mountain buiklding process? Outflowing of the mountain like ice sheets do? Erosion? It's all speculation.
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Related to Gravity & Everest: Why Can't We Go Higher Than 10km?
1. Why is 10km considered the limit for humans to climb?
The height limit for humans to climb without supplemental oxygen is approximately 8,000 meters or 26,247 feet, which is equivalent to 10km. This is because at this altitude, the air becomes significantly thinner and contains less oxygen, making it difficult for the human body to function properly.
2. What role does gravity play in limiting our ability to climb higher than 10km?
Gravity is a fundamental force that pulls objects towards the center of the Earth. As we climb higher, the gravitational force becomes weaker, making it harder for our bodies to function. This combined with the decrease in oxygen at higher altitudes makes it nearly impossible for humans to climb higher than 10km without the aid of supplemental oxygen.
3. Can technology help us overcome the limitations of gravity and climb higher than 10km?
While technology has advanced and allowed us to climb higher than ever before, it is still limited by the effects of gravity. Even with advanced equipment, humans are not able to withstand the harsh conditions and lack of oxygen at altitudes higher than 10km. However, technology such as pressurized cabins in airplanes and spacesuits have enabled us to briefly travel above this limit.
4. Are there any organisms that can survive at altitudes higher than 10km?
There are some organisms, such as certain types of birds and insects, that can survive at altitudes higher than 10km. However, these organisms have adapted to the extreme conditions at high altitudes and have different physiological mechanisms to cope with the lack of oxygen and low temperatures.
5. Will we ever be able to overcome the limitations of gravity and climb higher than 10km?
It is highly unlikely that humans will be able to climb higher than 10km without the aid of advanced technology. The human body is simply not designed to function at such extreme altitudes. However, advancements in technology may allow us to explore higher altitudes and potentially even settle on other planets with different gravitational forces.
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