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Earth formation

Earth ​was formed approximately 4.6 billion years ago, likely as the result of a supernova (star explosion). The debris from this explosion began to collapse in on itself due to gravity, forming the sun. Gravity continued to draw the remaining particles together, clumping them into larger bodies, ultimately forming Earth and the other planets in our solar system. Created by Sal Khan.

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  • primosaur ultimate style avatar for user Jeremy Hwang
    Is Theia the moon?
    (58 votes)
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    • aqualine seedling style avatar for user NeonDragonessFox
      Thea is the planet that crashed into Earth during the early stage of both planets' development. The crash would have ripped both planets into nothing more than asteroids, but Thea hit Earth at an angle, merging halves of the planets together and forming (due to the gravity of Earth) the rest of the rock and dust that was almost flung out into space into the moon. So you could say Thea is PART of the moon AND Earth, if that answers your question.
      (98 votes)
  • blobby green style avatar for user O.61803398874
    Regarding section in the video of "Earth Formation: How the Earth is a the byproduct of a local supernova". It has been reported that the Moon rocks were dated older than then Earth. So the Moon could not had been of Earth, when it’s older than the Earth, right?
    (8 votes)
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    • aqualine ultimate style avatar for user Aman Jha
      rock in the inner core would be even older than anything in our crust, except we have to access to the unbelievable heat and pressure.

      moon is believed to have come it the early days when a mars size asteroid smashed into earth before the hadian eon, and all the debris gravitated together (after forming a temporary ring) and turning into the moon.
      (1 vote)
  • male robot hal style avatar for user 17zvoos
    What is Theia?
    (8 votes)
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  • male robot hal style avatar for user Drew Denson
    I believe I now have a clear understanding of how the terrestrial planets may have formed, but I have been wondering about the formation of the gas giants and why they are farther out in the solar system than terrestrial planets. Are gas giants failed brothers and sisters of the sun or did they form in a completely different way?
    (5 votes)
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    • marcimus pink style avatar for user Rainbow Dash
      No, gas giants aren't failed stars, that is a common but false myth.
      Here is the reason the gas giants are gas giants: there used to be gas throughout the solar system, when it was a nebula. As planets grew in size, they collected gas in the form of atmospheres. However, as the SUN grew, most of the gas was blown away by the subsequent solar wind and radiation. The closer you get, the stronger it is. That's why Mercury has practically no atmosphere, and the gas giants are so large.
      In addition, most gas giants have solid rocky cores on the inside, and those are, in fact, larger than Earth. This means they have a greater gravitational field, counteracting the solar wind.
      In short: a combination of large cores and distance from the Sun allowed Gas Giants to stay gassy, while rocky planets like mercury, Mars, Venus, or earth lost most or all of that gas to solar wind.
      Hope this answered your question! :)
      (9 votes)
  • male robot hal style avatar for user 17zvoos
    Is our inner core spinning really fast?
    (5 votes)
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  • marcimus pink style avatar for user av-ikim
    how did the earth`s water form?????????

    (3 votes)
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    • mr pants teal style avatar for user Bipin Chawla
      Water exists naturally on many, many worlds. There are oceans of liquid water on some moons of Jupiter and Saturn that are larger than all the oceans on Earth combined. There is solid ice comets in space almost everywhere. Water is found in so many places, that it isn't special to Earth. The Earth's temperature is just at the value where it is a liquid instead of solid ice or gaseous water vapour on most of the surface. There are moons with vast oceans under thick layers of ice on moons of Saturn and Jupiter. Water's everywhere and is not unique to earth.
      (7 votes)
  • blobby green style avatar for user vsherbukhin
    As far as I understand, the remnants of a supernova are very poor in hydrogen, which is burned up during the lifetime of the progenitor star. Where does the hydrogen essential for the formation of the Sun came from? Thank you!
    (2 votes)
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    • piceratops ultimate style avatar for user AegonTargaryen
      Actually, type 2 supernovae (the more common type) have lots of hydrogen. Only a small percentage of the star supports fusion and during the explosion, vast amounts of hydrogen near the surface are blown off into space.

      Although, these nebula clouds are mostly remnants after the creation of hydrogen big bang.
      (6 votes)
  • aqualine ultimate style avatar for user Rhett Zhao
    So if Theia doesn´t smash into Earth, will Earth be bigger today?
    (4 votes)
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    • piceratops tree style avatar for user Owen Hanson
      Although Theia knocked a chunk off of Earth (which is now the moon) into orbit, Theia also merged with the Earth. Because we do not know the size or mass of Theia, I cannot say for certain whether the collision added to or subtracted from Earth's size today. However I do know this. If Theia was larger than the moon, then Earth got bigger in size from the collision.
      (3 votes)
  • piceratops ultimate style avatar for user Sairam P.
    When Sal mentions the formation of uranium due to the heat of a supernova, how would the uranium even form if uranium was an element? I mean, they are gas molecules that are being compressed. How are gas molecules supposed to form uranium?
    (2 votes)
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  • mr pants teal style avatar for user benanaju
    At , Sal talks about theia hitting the earth. After this, What happened to Theia?
    (3 votes)
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Video transcript

What I'm going to attempt to do in the next two videos is really just give an overview of everything that's happened to Earth since it came into existence. We're going start really at the formation of Earth or the formation of our Solar system or the formation of the Sun, and our best sense of what actually happened is that there was a supernova in our vicinity of the galaxy, and this right here is a picture of a supernova remnant, actually, the remnant for Kepler's supernova. The supernova in this picture actually happened four hundred years ago in 1604, so right at the center a star essentially exploded and for a few weeks was the brightest object in the night sky, and it was observed by Kepler and other people in 1604, and this is what it looks like now. What we see is kinda the shockwave that's been traveling out for the past 400 years, so now it must be many light years across. It wasn't, obviously, matter wasn't traveling at the speed of light, but it must've been traveling pretty, pretty fast, at least relativistic speeds, a reasonable fraction of the speed of light. This has traveled a good bit out now, but what you can imagine is when you have the shockwave traveling out from a supernova, let's say you had a cloud of molecules, a cloud of gas, that before the shockwave came by just wasn't dense enough for gravity to take over, and for it to accrete, essentially, into a solar system. When the shockwave passes by it compresses all of this gas and all of this material and all of these molecules, so it now does have that critical density to form, to accrete into a star and a solar system. We think that's what's happened, and the reason why we feel pretty strongly that it must've been caused by a supernova is that the only way that the really heavy elements can form, or the only way we know that they can form is in kind of the heat of a supernova, and our uranium, the uranium that seems to be in our solar system on Earth, seems to have formed roughly at the time of the formation of Earth, at about four and a half billion years ago, and we'll talk in a little bit more depth in future videos on exactly how people figure that out, but since the uranium seems about the same age as our solar system, it must've been formed at around the same time, and it must've been formed by a supernova, and it must be coming from a supernova, so a supernova shockwave must've passed through our part of the universe, and that's a good reason for gas to get compressed and begin to accrete. So you fast-forward a few million years. That gas would've accreted into something like this. It would've reached the critical temperature, critical density and pressure at the center for ignition to occur, for fusion to start to happen, for hydrogen to start fusing into helium, and this right here is our early sun. Around the sun you have all of the gases and particles and molecules that had enough angular velocity to not fall into the sun, to go into orbit around the sun. They were actually supported by a little bit of pressure, too, because you can kinda view this as kind of a big cloud of gas, so they're always bumping into each other, but for the most part it was their angular velocity, and over the next tens of millions of years they'll slowly bump into each other and clump into each other. Even small particles have gravity, and they're gonna slowly become rocks and asteroids and, eventually, what we would call "planetesimals," which are, kinda view them as seeds of planets or early planets, and then those would have a reasonable amount of gravity and other things would be attracted to them and slowly clump up to them. This wasn't like a simple process, you know, you could imagine you might have one planetesimal form, and then there's another planetesimal formed, and instead of having a nice, gentle those two guys accreting into each other, they might have huge relative velocities and ram into each other, and then just, you know, shatter, so this wasn't just a nice, gentle process of constant accretion. It would actually have been a very violent process, actually happened early in Earth's history, and we actually think this is why the Moon formed, so at some point you fast-forward a little bit from this, Earth would have formed, I should say, the mass that eventually becomes our modern Earth would have been forming. Let me draw it over here. So, let's say that that is our modern Earth, and what we think happened is that another proto-planet or another, it was actually a planet because it was roughly the size of Mars, ran into our, what it is eventually going to become our Earth. This is actually a picture of it. This is an artist's depiction of that collision, where this planet right here is the size of Mars, and it ran into what would eventually become Earth. This we call Theia. This is Theia, and what we believe happened, and if you look up, if you go onto the Internet, you'll see some simulations that talk about this, is that we think it was a glancing blow. It wasn't a direct hit that would've just kinda shattered each of them and turned into one big molten ball. We think it was a glancing blow, something like this. This was essentially Earth. Obviously, Earth got changed dramatically once Theia ran into it, but Theia is right over here, and we think it was a glancing blow. It came and it hit Earth at kind of an angle, and then it obviously the combined energies from that interaction would've made both of them molten, and frankly they probably already were molten because you had a bunch of smaller collisions and accretion events and little things hitting the surface, so probably both of them during this entire period, but this would've had a glancing blow on Earth and essentially splashed a bunch of molten material out into orbit. It would've just come in, had a glancing blow on Earth, and then splashed a bunch of molten material, some of it would've been captured by Earth, so this is the before and the after, you can imagine, Earth is kind of this molten, super hot ball, and some of it just gets splashed into orbit from the collision. Let me just see if I can draw Theia here, so Theia has collided, and it is also molten now because huge energies, and it splashes some of it into orbit. If we fast-forward a little bit, this stuff that got splashed into orbit, it's going in that direction, that becomes our Moon, and then the rest of this material eventually kind of condenses back into a spherical shape and is what we now call our Earth. So that's how we actually think right now that the Moon actually formed. Even after this happened, the Earth still had a lot more, I guess, violence to experience. Just to get a sense of where we are in the history of Earth, we're going to refer to this time clock a lot over the next few videos, this time clock starts right here at the formation of our solar system, 4.6 billion years ago, probably coinciding with some type of supernova, and as we go clockwise on this diagram, we're moving forward in time, and we're gonna go all the way forward to the present period, and just so you understand some of the terminology, "Ga" means "billions of years ago" 'G' for "Giga-" "Ma" means "millions of years ago" 'M' for "Mega-" So where we are right now, the Moon has formed, and we're in what we call the Hadean period or actually I shouldn't say "period." It's the Hadean eon of Earth. "Period" is actually another time period, so let me make this very clear. It's the Hadean, we are in the Hadean eon, and an eon is kind of the largest period of time that we talk about, especially relative to Earth, and it's roughly 500 million to a billion years is an eon, and what makes the Hadean eon distinctive, well, from a geological point of view what makes it distinctive is really we don't have any rocks from the Hadean period. We don't have any kind of macroscopic-scale rocks from the Hadean period, and that's because at that time, we believe, the Earth was just this molten ball of kind of magma and lava, and it was molten because it was a product of all of these accretion events and all of these collisions and all this kinetic energy turning into heat. If you were to look at the surface of the Earth, if you were to be on the surface of the Earth during the Hadean eon, which you probably wouldn't want to be because you might get hit by a falling meteorite or probably burned by some magma, whatever, it would look like this, and you wouldn't be able to breathe anyway; this is what the surface of the Earth would look like. It would look like a big magma pool, and that's why we don't have any rocks from there because the rocks were just constantly being recycled, being dissolved and churned inside of this giant molten ball, and frankly the Earth still is a giant molten ball, it's just we live on the super-thin, cooled crust of that molten ball. If you go right below that crust, and we'll talk a little bit more about that in future videos, you will get magma, and if you go dig deeper, you'll have liquid iron. I mean, it still is a molten ball. And this whole period is just a violent, not only was Earth itself a volcanic, molten ball, it began to harden as you get into the late Hadean eon, but we also had stuff falling from the sky and constantly colliding with Earth, and really just continuing to add to the heat of this molten ball. Anyway, I'll leave you there, and, as you can imagine, at this point there was no, as far as we can tell, there was no life on Earth. Some people believe that maybe some life could've formed in the late Hadean eon, but for the most part this was just completely inhospitable for any life forming. I'll leave you there, and where we take up the next video, we'll talk a little bit about the Archean eon.