Cosmology and astronomy
Sal Khan describes the scale of our Solar System. Created by Sal Khan and NASA.
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- How can we see 13.8 billion miles away, at one of the furthest objects. but we cannot see the Oort cloud that surrounds us?(304 votes)
- We can't see it mostly because it doesn't radiate. Everything we can detect outside of our solar system is 'seen' because it is throwing off energy at us. It's very difficult to see the dark stuff. For example, we can infer of the presence of a planet around a star by the wobble of the star, and we 'see' things very far away by registering the energy that they emit. The Oort cloud does not emit detectable levels of energy, at least none that we can currently measure.(407 votes)
- How did the planets get their names?(113 votes)
- Many planets get their names from Roman gods and Goddesses.
1. Mercury is the Roman God of messengers
2. Venus is the Roman Goddess of love and beauty
3. Earth....Well,Terra is the Roman personification of the Earth(So, Earth is an exception)
4. Mars is the roman god of war
5. Jupiter is the Roman God of lightning(He is also the king of the gods)
6.Saturn -Well... He is not a god but is a titan(Titans are also immortal,just like gods). In fact, he is Jupiter's Father.
7.Uranus-He is the personification of the sky...and is Saturn's father
8.Neptune-He is the roman god of the sea.
9.Pluto - He is the Roman god of the Underworld.
Just out of interest, many moons are also named after children of these gods/goddesses:
1. Moons of mars: Phobos(god of fear) and Deimos(god of terror) are children of mars
2. Most important moon of Neptune: Triton(Neptune's immortal son)
3. Pluto's moon: Charon........It is believed in Greek and Roman mythology.that the dead go to the underworld. They are ferried across the fabled river Styx by Charon.
Hope that answers your question.There are many more asteroids and other heavenly objects that are named after characters in greek and roman mythology.I have enlisted whatever few I can.(221 votes)
- Why is neptune blue?(71 votes)
- Neptunes atmosphere is made up of gasses that absorb most of the Red light that hits it, so the relected blue light is what we see(146 votes)
- In the Solar System when we measure planets, why do we measure with astronomical units more than light years.(14 votes)
- For the same reason we do not measure the height of a person in miles. The diameter of the solar system is about 0.000790642257 lightyears(46 votes)
- How do we know where voyager is? it would be too far for us to receive a signal surely.(11 votes)
- It isn't too far to receive a signal. A radio telescope array is used to detect signals from both Voyagers. With antennae located in California, Spain and Australia, the array has an effective antenna the size of planet Earth.(25 votes)
- During1:40Sal says that Mercury is not debated whether it is a planet but Pluto is. Shouldn't BOTH these planets be considered moons or dwarf planets?(8 votes)
- Also to add to this, Mercury has cleared all debris out of its orbit while Pluto is surrounded by many other icy bodies and is actually just another (albeit large) body in the Kuiper Belt.
Another problem with Pluto is that it's mass is not sufficiently large enough to maintain it's own center of gravity in regards to it's many moons, as Pluto and it's largest moon Charon share a center of gravity. For example, our moon (Luna) orbits around earth, but Pluto and it's moon Charon orbit around a shared center of gravity that lies somewhere between Pluto and Charon. Therefore, Charon (Pluto's moon) does not orbit around Pluto, they orbit around each other.(19 votes)
- Why Voyager 2 has marked with number 2 even it was launched before Voyager 1 ?(7 votes)
- The spacecraft weren't named for when they would be launched, but for when they would arrive at Jupiter. Voyager 2 had a longer trajectory to get to jupiter, since it also had to visit the other planets and exit the solar system.(15 votes)
- If the sun is a white star why does it appear yellow?(4 votes)
- Why is Pluto a dwarf planet? It's just because of it's size, or it has other reasons?(3 votes)
- Because it does not have one of the characteristics to be a planet. A planet has to have these characteristics to be a planet. Here are the four characteristics:
Has to orbit a star
Has to have enough gravity to make it round
Must not be a moon
Must have cleared its orbit from any other objects (which Pluto hasn't done)(7 votes)
- @4:36what?? Why is Neptune and Uranus the same looking? Do they have the same atmosphere?(3 votes)
- Uranus' Atmosphere: Hydrogen,Helium, Ammonia, Methane,Hydrocarbons
Neptune's Atmosphere: Hydrogen,Helium, Methane,Ammonia and Water
To answer your question, their atmosphere's have a very similar composition and they thus have a blue/bluish-green look.They are also called sister planets.(4 votes)
Where we left off in the last video, I think we were getting a reasonably good appreciation for how huge the sun is, especially relative to the Earth, and how far the Earth is away from the sun. That most of these diagrams that we see in science textbooks-- they don't give justice. In fact, when I showed this sun over here that was about five or six inches across, I said Earth would be just this little speck, about 40 feet. It wouldn't be this distance. It would be about 40 feet to the left or the right. Or its orbit would have a radius of about 40 feet. You wouldn't even notice it if you were looking at this thing over here. It would be this little speck orbiting at this huge, huge distance. If you look at this sun over here, if I were to draw the whole sun, it looks like it would have a diameter of about 20 inches. So in this situation, this Earth right here-- and this is drawn to scale-- this Earth would not be anywhere near this close. It would be about 200 feet that way, or about 60 or 70 meters, 60 meters. So you can imagine if the sun was this size, sitting on something like a football field, this little speck of an Earth, this little thing right here, would be sitting on the other 40-yard line, 60 meters away. So you wouldn't even notice it. You might notice this from a distance, but you wouldn't even see this thing over here. And the other planets are even further. Well, not all of the other planets. Obviously, you have Mercury. I think most of us are familiar with these. But I'll just list them here, just in case. That's Mercury. This is Venus. Mercury is the smallest of the planets where it's not debated whether it's a planet. Pluto is the smallest, but some people debate whether it's really a planet or just a large solar body or a dwarf planet or any of those type of things. But then you have Venus, probably the closest in size to the Earth. Or it is the closest in size to the Earth. And then you have Mars. And then you have Jupiter. And just to give a sense of, once again, how far these things are, if I were to go back to the analogy of this being the size of the sun, then Jupiter is five times further than Earth. So this would be-- If I were to actually do the scale distance, this would be 300 meters away. So if I had a nice, big, maybe medicine-balled-size sun right over here, maybe basketball-sized. A little bit bigger than a basketball, this looks on my screen-- then this little thing that's smaller than a ping pong ball, I would put this three football fields away. That's how far Jupiter is. And then Saturn's about twice as far as that. Saturn is about nine times the distance. So let me make it clear. The Earth is one astronomical unit away from the sun, roughly. Its distance changes. It's not a perfectly circular orbit. Jupiter is approximately a little bit-- 5 plus astronomical units-- a little bit more than five times the distance of the sun to the Earth. And Saturn is approximately nine astronomical units, or nine times the distance from the sun to the Earth. So once again, this would be nine football fields away. Or another way to think about it would be, essentially, a kilometer away. If we had kind of a medicine-ball-size sun, this little smaller than a ping pong balled Saturn would be a kilometer away. And I just want to really reiterate that because you never visualize it that way. Because just for the sake of being able to draw it on a page, you see diagrams that look like this. And they really don't give you a sense of how small these planets are relative to the sun, and especially relative to their distance from the sun. And then after Saturn, you have Uranus and then Neptune. And obviously, these guys are even further. And just to give you a sense, it's very easy to start talking about galaxies and universes and all of the-- or the universe. But I really just want to get-- already, what we've talked about, we're talking about huge distances, huge scale. We already talked about that it would take a jet plane 17 years to travel from the Earth to the sun. Multiply that by five, about 100 years to go from Jupiter to the sun, 200 years to go from Saturn to the sun. So you could have had Abraham Lincoln get into a jet plane, and if he left from Saturn, he still would not have gotten to the sun. So these are huge, huge distances. But we're not done with the solar system, there. Just to give a sense of scale-- so this right here, that's the sun. And each of these planets are actually narrower than these orbits. So they just draw these orbits here, but you wouldn't actually even see the actual planets here at this type of a scale. But this is one astronomical unit right over here, the distance from the sun to the Earth. Then you have Mars. Then you have the asteroid belt. There you have the asteroid belt, which also has some pretty big things in it, itself. And it has these things that are kind of considered almost dwarf planets, things like Ceres. You could look those type things up. And then you have Jupiter out here. And once again, we said it would take 100 years, or roughly 100 years, for a jet plane to get from Jupiter to the sun. But even if you take this whole box here-- which is a huge amount of distance, of roughly about five astronomical units-- it would take about 40 minutes for light to get from the sun to Jupiter. So this is a huge, huge distance. But even this huge distance-- we can put it into this little box right over here. So this whole box right over there can be fit into this box. And you need to do that in order to appreciate the orbits of the outer planets. And so on this scale, Earth and Venus and Mercury and Mars, their orbits look pretty much-- you can't even differentiate them from the sun. They look so close. They almost look like they're part of the sun when you look at it on this scale. And then you have you have the outer planets-- Saturn, Uranus, Neptune. And they we have a Kuiper belt. And this is more asteroids, but these are kind of more frozen. And when we think of ice, you always think of water ice. But out here, it's so cold. And it's relatively getting dark, now, because we're pretty far from the sun that things that we normally associate as gases are going to be in their solid form out here. So this isn't just rocky elements. This will also be things that we normally associate as gases, like methane, frozen methane. But even here, we're not done. We're not even out of the solar system yet. And actually, just to give you a sense of the scale we're operating right here, I have this chart right here from the Voyager mission. So the Voyager missions-- Voyager 1 and 2-- actually, Voyager 2 left a little bit earlier, a month earlier. Voyager 1 is just traveling faster. They left about a year after I was born And their current velocity, just to give you a sense of how fast-- Voyager 1 right here is right now traveling at 61,000 kilometers per hour. That's about 17 kilometers per second. The size of a city every second-- it's going that fast. That's, at least in my mind, an unfathomably fast velocity. This thing has been traveling roughly that fast. It's been going around planets and gaining acceleration as it went around orbits. But for most of the time, it's been going at a pretty fast speed. And just to translate it to people who don't relate to kilometers, that's about 38,000 miles per hour, so this huge, huge unfathomably fast speed. And it's been doing it since 1977. I was learning to walk. And when I was learning to walk, it was traveling at this super fast speed. And then when I was learning to talk-- our whole lives, when we're sleeping, everything, we're eating, I'm in elementary school-- it's still rocketing out of the solar system at roughly this speed. Its velocity has changed, but especially, once it got outside of the planets, it's been roughly at this velocity. So it's just been rocketing out. And I don't want to say only, but it's gotten this far. If we look at it on this scale, it's gotten about that far right there. It's about 115, 116 astronomical units. And to give a sense-- so there's two ways to think about it. One says, like, wow, that's really far. Because we know that even on this scale, you can't even see Earth's orbit. So this looks like it's a pretty, pretty far distance. And just to give you a sense of how far 116 astronomical units are, if 2,000 years ago, Jesus got on a plane-- I actually cut and pasted a copy of Jesus, just for visualization purposes-- but if he'd got on a jet liner at 1,000 kilometers per hour and went straight in that direction, in the direction that Voyager, Voyager would only just now be catching up to Jesus. So this is a huge, huge, huge, huge distance. But at the same time, even though it's a huge distance, especially relative to everything else we've talked about, relative to just even the outer reaches of the solar system, we're still talking in terms of a small scale. So that's how far Voyager is. And just to give a sense, on this scale-- so this whole box over here can be contained in this box. And when you look at this box, Voyager's only gotten about that far after traveling at this unbelievable velocity for over 30 years, for about 33 years. And just to give you an idea of these other things, Sedna, right here, is a reasonably large-sized outer solar system object. It's one of the furthest objects that we know of in the solar system. And it has this very eccentric orbit. So it gets-- I don't want to say relatively close, but not unreasonably far away. And then it gets really far away from the sun. But even Sedna's orbit-- so if I were to look at this, so this whole box over here can be contained right over here. So in this diagram right here, you wouldn't even be able to see. It would be like a speck how far Voyager has traveled in 33 years at 38,000 miles per hour. You would not even be able to notice. You wouldn't even notice that distance. And even though you can't even notice that distance, we still have the sun's influence. The gravitational pull is still attracting things to it. And this right here, we speculate that there is the Oort cloud. And this is where the comets originate from. And this is just a bunch of frozen gases and ice particles and things like that. But we're starting to get to the outer reaches of the solar system. And this distance right here is about 50,000 astronomical units. And just to give a scale-- because you hear a lot about light years and all of that-- light years are about 63,000 astronomical units. So if you go a light year out from the sun, you'll end up in the Oort cloud, the hypothesized Oort cloud. And just to give a sense, another scale, the Oort cloud is actually-- most of the planets' orbits are roughly in the same plane. But this right here is the orbit of the planets. And once again, these lines are drawn too thick. They're just drawn the thinnest possible so that you can see them, but they're still drawn too thick. And this gets us all the way to the Kuiper belt. But all of this over here, so all the way out to the Kuiper belt, all the way out to all of the major planets-- this is Pluto's orbit right over here. This whole diagram is only sitting in right over there. You can barely see it. This whole diagram is just that dot in this. And then you can see the Oort cloud all around it. And it's more of a spherical cloud. And we think it exists. Obviously, it's hard to observe things at that distance. So hopefully, that gives you a beginning sense of the scale of the solar system. And what's really going to blow your mind-- if this hasn't blown your mind already-- is that this whole thing's going to start looking like a speck. When you even just look at the local area around our galaxy, much less the galaxy, much less the universe as a whole. Anyway, I don't want to get-- well, anyway. This is starting to get crazy.