That is interesting!
And it isn't a joke: http://en.wikipedia.org/wiki/Expanding_earth_theory
What I want to know is WHERE DID ALL THE WATER COME FROM?!
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Just a thought. I seem to recall that somewhere in the Qur'an we are told the universe is expnding. If the universe is expanding, and since we are part of the universe, isn't it logical that the earth is expanding?
Now if I can find the ayyats that refer to the universe expanding.
Noble Verse 51:47"And the firmament, We constructed with power and skill and verily We are expanding it."
The Universe will also shrink: "The Day that We roll up the heavens like a scroll rolled up for books (completed),- even as We produced the first creation, so shall We produce a new one: a promise We have undertaken: truly shall We fulfil it. (The Noble Quran, 21:104)"
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"The universe starts with a Big Bang, expands to a maximum dimension, then recontracts and collapses (to the Big Crunch); no more awe-inspiring prediction was ever made." Quotation from Charles W. Misner, Kip S. Thorne and John A. Wheeler in "Gravitation", W. H. Freeman, San Francisco, 1973, page 1196.
I wondered the same thing....and how rock expands...unless the Earth is really a baloon lol
I found this video about the expanding earth to be simply amazing. The explanation seemed plausible to me. Isn't there supposed to be an increase in earthquakes near the end of time? If so, this could be due to an accelerated expansion of the earth.That is interesting!
And it isn't a joke: http://en.wikipedia.org/wiki/Expanding_earth_theory
What I want to know is WHERE DID ALL THE WATER COME FROM?!
Lies!! =| Better not have been a joke. Anyways...I liked the video.
Spoiler Alert!
This isnt a real theory.....
I posted it because its a joke...
Spoiler Alert!
This isnt a real theory.....
I posted it because its a joke...
Here's a thought...
Look at the sun or any star and its life span. Some die out and become dwarfs and thus decrease in size and some become red stars or other super giants. So if the stars can change size, why not planets?
“Hold on!” cried Raed. “There are 400,000,000 of them on any ordinary night of the year. But, during April, August, and November, there are more, — sometimes vast showers like that of 1833: so, reckoning in these months, the average would be more than 400,000,000 per diem. Ques*tion arises, how much more?”
“As much again,” said Wash; “800,000,000 on an average.”
“One-half more,” said Wade; “600,000,000 on an average.”
“Split the difference!” cried Raed; “call it 700,000,000. Now how many pounds at one grain each?”
“Let’s see,” said Wade. “How many grains in a pound avoirdupois?”
“7,000,” said Wash. “Now we have it, then, — 100,000 pounds of meteors fall to the earth daily.”
“How much in a year?” demanded Raed.
“365 times 100,000,” repeated Wade; “36,500,000 pounds per year.”
“How much per century ?”
“3,650,000,000 pounds!” cried Wash.
“How many tons would that be? Divide by 2,000.”
“1,825,000 tons!” exclaimed Wade.
The decay rate of cosmological gravitational potential measures the deviation from Einsteinndashde Sitter universe and can put strong constraints on the nature of dark energy and gravity. The usual method to measure this decay rate is through the integrated Sachs-Wolfe (ISW) effectndashlarge-scale structure (LSS) cross-correlation. However, the interpretation of the measured correlation signal is complicated by galaxy bias and the matter power spectrum. This could bias and/or degrade its constraints on the nature of dark energy and gravity. But combining the lensing-LSS cross-correlation measurements, the decay rate of gravitational potential can be isolated. For any given narrow redshift bin of LSS, the ratio of the two cross-correlations directly measures dlnDphis/dlnaH(z)/W(chi,chis), where Dphis is the linear growth factor of the gravitational potential, H is the Hubble constant at redshift z, W(chi,chis) is the lensing kernel, and chi and chis are the comoving angular diameter distance to lens and source, respectively. This method is optimal in the sense that (1) the measured quantity is essentially free of systematic errors and is only limited by cosmic variance, and (2) the measured quantity depends only on several cosmological parameters and can be predicted from first principles unambiguously. Although fundamentally limited by the inevitably large cosmic variance associated with the ISW measurements, it can still put useful independent constraints on the amount of dark energy and its equation of state. It can also provide a powerful test of modified gravity and can distinguish the Dvali-Gabadadze-Porrati model from LambdaCDM at >2.5 sigma confidence level.
Here's a thought...
Look at the sun or any star and its life span. Some die out and become dwarfs and thus decrease in size and some become red stars or other super giants. So if the stars can change size, why not planets?
Yeah I agree, as I states this before to, however I do not think this temperature drop is enough to make significant differences in size.No seriously. The earth is shrinking. Why? Because the core which is made of liquid magma is cooling down. And remember what happen to a cake, when it comes out of the oven? It shrink inside the shape. Same thing happen to the earth.
The continents are drifting, because the tectonic plates are floating on the magma.
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