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hi welcome to astro 101 the sun and it's
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neighbors
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this is already class seven in today's
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class we're going to be looking at one
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of the most
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challenging topics that we cover all
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semester in fact
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today's lecture and the one before us
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really are the
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kind of the hardest things to understand
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i think we're going to be able to do it
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um if we if we pay attention and while
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they're
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challenging it's they're also really
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cool the fact that there's these things
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that we see in the world
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that we can actually understand to
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introduce today's topic i've got a
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special guest
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ah sofia hey dad good morning hey guys
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so i'm here at crescent beach it is one
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or i guess just after two o'clock and it
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is currently low tide
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hello so i'm here at crescent beach at
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about 7 30 a.m and as you can see it is
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currently high tide
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so i guess uh you'll be here later this
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afternoon
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so you say alrighty then bye guys all
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right well i gotta go
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um bye sophia
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all right that's very cool um sophia
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left us
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with this really interesting video of
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um crescent beach
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at low tide and at high tide
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at low tide you can see the water is way
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out there and all this
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is basically dry whereas at high tide
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the waters come in and this is all
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flooded in fact in crescent beach
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the water levels rise by a couple of
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meters and so the water level comes from
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out there all the way
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in and we can see this difference
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between high tide
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and low tide and we you can look up
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online these tables that tell you when
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it's going to be high tide when it's
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going to be low tide
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but it took a very long time
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to figure out what is it that causes
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this phenomena
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where the water level is way out here at
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low tide way in here
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just half a half a day later um
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or quarter day later six six hours later
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at high tide
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um galileo who we've talked about before
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thought he had an under an explanation
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he thought it was because of the
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motion of the earth as this moon moved
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around the earth
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would cause the oceans to slosh around
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and he was convinced this is a great
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evidence
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for the fact the moon orbited the earth
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no that's not the case that is not what
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causes tides today we're going to find
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out
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let's but before we do that we need to
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go and go ahead and review
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what we covered last class that was a
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long class lots of difficult ideas
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let's review them again just to make
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sure we see what's going on is to start
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with newton's
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first law now newton's first law
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says if we recollect an object in motion
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remains in motion unless acted upon by
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an outside force
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in other words if something is moving it
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stays moving
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in the same direction at the same speed
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unless you apply a force to it
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that's newton's first law so in the
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picture here we have the
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figure skater and he is sliding along
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the ice in his very low friction skates
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and he will just keep on moving
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not speeding up not slowing down unless
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a force is applied to him newton's first
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law
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if it's moving it stays moving if it
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changes direction or speed
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it's because there is a force applied to
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it which brings us to newton's
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second law newton's second law says
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something accelerates or something
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changes speed
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if there's a force applied to it the
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larger the force
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the more quickly the speed changes
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newton's second law also says that the
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heavier something is
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the less quickly it accelerates so we
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have the picture here of the little boy
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pushing grammar
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small force um relatively large mass
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therefore
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not a very quick acceleration if you
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switch it around put the boy in the cart
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and grandma pushes then it'll accelerate
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quite quickly
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so more force more acceleration
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more mass less acceleration because in
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the equation here
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the force is divided by the mass the
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bigger the mass the less the
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acceleration
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nothing accelerates unless you apply a
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force
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okay excellent newton's second law
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so we looked at some examples of that um
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you know
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this example here is something is
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pushing something so you can imagine
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um you know the engine in your car
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turning the wheels and making the car
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speed up
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speeding up is a form of acceleration
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but remember also changing direction
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is a form of acceleration remember
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velocity
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is speed and direction combined together
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into one thing
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acceleration is change in velocity so a
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change
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in the speed or the change in direction
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or both
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which brought us to this little demo
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here where my beautiful wife spins
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uh a ball on a string over her head and
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the ball goes in a circle
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because the string is applying a force
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to the ball
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the string causes the ball to accelerate
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into a circle
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and so we see that here the string is
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applying a force to the ball but then
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when she lets go of the string the
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string no longer applying a force the
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ball just travels in a straight line
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into the trees
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kerfump okay so
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newton's second law
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a force causes acceleration the speed
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and the direction
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never change unless you apply a force if
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you apply a force then the speed or the
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direction can change with no force
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it'll travel in a straight line neither
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speeding up nor slowing down
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okay so newton's third law
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for every force there is always an equal
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equal an opposite
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reaction force so if you push on
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something it pushes back
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we talked about the astronaut out in
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space who pushes against her
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spacecraft she moves away from the
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spacecraft but at the same time the
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spacecraft moves away from her
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because she is lighter she moves faster
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because the spacecraft is heavier it
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moves slower
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but every time you push something on
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something it pushes back
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to every force there was always an equal
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and opposite
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reaction force newton's third law
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so we took these three laws
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and we tried to understand from them how
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we can understand the behavior of
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objects in the solar system so we looked
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at this um i had this little story here
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we have
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we launched a satellite at 33 000
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kilometers per second
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from 500 kilometers above the surface of
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the earth to see what happens and the
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answer is
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it goes out and it goes it follows
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an elliptical orbit the shape that it's
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following it turns out
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is an ellipse and it speeds up when it
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gets close to the earth
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and then slows down again as it gets
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further away
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the center of the earth is at one focus
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of the ellipse and there's another focus
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of the ellipse out here
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why is an ellipse that's a
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weird question let's let's first try to
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understand
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how i did the simulation what did i do
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to make the simulation work well what i
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did is i took
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first of all newton's law of gravitation
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a force equals the mass of the first
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object
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the earth times the mass of the second
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object my
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satellite divided by the distance
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squared
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times this little number g and then we
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say
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in this thing so f is the force
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m is the mass there's mass of the first
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object mass of the second object
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r is the distance between them between
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the center of the satellite and the
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center of the earth
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and a is acceleration the change in
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velocity and then so i take this law
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and i then add to it newton's second law
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of motion
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which says a the change in velocity
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is equal to the force divided by the
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mass the mass of the
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um satellite now something i want to
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yeah okay something i'll actually want
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to look at right now before we continue
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with this
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remember last class i dropped the hammer
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and it accelerated downwards and
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accelerated downwards at 10 meters per
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second
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per second and that i said that except
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for air resistance anything you drop
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will accelerate that quickly that's at
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first kind of a weird idea because you
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would say well look
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the heavier the hammer is the larger the
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force
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so a larger force should make a bigger
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acceleration
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yes but we're dividing it by the mass of
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the hammer
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so a bigger mass of the hammer makes a
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smaller acceleration and in fact
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the mass in the force exactly cancels
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the mass in the acceleration
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and so the acceleration does not depend
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on the mass of the object that's kind of
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cool
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that that's really actually that's
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actually really neat
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well there it is okay so the fact that
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everything falls at the same speed
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ignoring every spare friction
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is a natural consequence of the force of
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gravity
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and newton's second law okay anyway
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going back to our orbit
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we have the object which is a force
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being applied on the object that equals
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g the tiny number
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times the mass of the earth times the
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mass
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of the satellite divided by the distance
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between them
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between the centers squared okay
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i calculate that and then i say the
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speed will change
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by each time step the speed will change
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by
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the force sorry the velocity not the
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speed the velocity will change
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but the force divided by the mass so i
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can take my particle and i say okay it's
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going in this direction
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so each time step i'll move it forward
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by however however fast it's going
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and then i will change the speed by
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whatever the acceleration is
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and then go to the next time step and
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recalculate
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so we have the force from gravity
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pulling it this way we have the speed
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going that way i move it forward in time
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to the next place
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because it's going this direction i move
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it this direction and then i change the
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speed
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by by this equation change the velocity
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by this equation not to speed
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and then and then and then step on so
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let's see how this goes
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we go into the future later on we have
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the force now is in this direction
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again toward the center of the earth the
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speed is in this direction i know what
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to do and how to i know how to step it
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forward and how to change the speed
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the velocity i know how to change the
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acceleration and i keep stepping forward
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at this point you see that the the force
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has a component
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going this way to try and make it curve
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but also a component in this direction
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it's not pointing exactly sideways
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anymore it's a little bit back
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the force is also is is causing the
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satellite to change direction
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and to slow down if we go even later we
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go out here
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the force is pulling this way it's
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causing the satellite to slow down the
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force is pulling toward the earth
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and also causing it to change direction
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and because it's so much further away
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the force is much less so the further
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away you are
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the less the force the less the
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acceleration
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but to get out there gravity had to be
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slowing it down so when it gets out here
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it's going much slower because gravity's
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been slowing it down the whole way
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and now gravity will cause it to speed
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up again until it finally gets in
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close to the earth so this is how my
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little program
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works that uses newton's second law and
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newton's law of gravitation
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to make those orbits that i showed you
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and uh
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i mean it's a really really simple uh
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differential equation solver relatively
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speaking there's much much better ones
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but
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this worked a little python program um
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i mean i'd love to teach you
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differential calculus right now uh
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vector calculus rather but teaching
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vector calculus
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probably out of scope of um
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astral 101 but this kind of math i'm
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talking about newton had to invent it in
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order to do this kind of work so it's
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it's
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pretty pretty great um now that we know
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it it's like oh yeah that's kind of easy
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ish
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i don't know all right so orbits you
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take these two equations
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you apply them step by step by step and
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you can reproduce
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the orbit of a satellite around the
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earth
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you find that it is an ellipse you find
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that the earth is at the center is that
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one of the focuses and that the other
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focus is somewhere in space
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this nowhere here in this mass that goes
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into this orbit
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do we say anything about it being an
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ellipse nowhere in this mass
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do we say anything about where the
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focuses are it just
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that's just how
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it works so why isn't it an ellipse
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because it's a natural consequence of um
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acceleration being proportional to the
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square of the distance from the mass
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very it's very interesting uh it it's
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just that's just the way it works
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it's a natural consequence of these
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rules where did these rules come from
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well there they are
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they came from the mind of god
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okay instant review quiz when
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in the highly eccentric orbit of a comet
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is the speed of the comet
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the greatest the speed not the velocity
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the speed when is the speed
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the greatest four possibilities here a
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it's always the speed is always the same
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b
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when the comet is furthest from the sun
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c when the comet is approaching the sun
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coming in towards the sun
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d when the comet is closest to the sun
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or
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e when the comet is moving away from the
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sun
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when is the speed of the comet
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the greatest okay we can think back to
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this this is actually
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this is kepler's second law isn't it
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when is the speed the greatest do you
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remember
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d when the comet is closest to the sun
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that's when the speed is greatest
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okay next question
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when in the highly eccentric orbit of a
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comet is the angular momentum of the
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comet the greatest remember going back
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to last class the idea of
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angular momentum when is the angular
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momentum of the comet
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the greatest option a it's always the
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same
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because angular momentum is conserved or
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b when the comet is furthest from the
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sun
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when the comet is approaching the sun
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when the comet is closest to the sun
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or when the comet is moving away from
00:14:43
the sun well the answer is a
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right angle momentum is conserved it's
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always the same so a good that one's
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easy
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all right next question when in the
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highly eccentric orbit of a comet
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is the force due to gravity between the
00:14:59
comet and the sun
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the greatest when is the force due to
00:15:03
gravity
00:15:03
between the comet and the sun the
00:15:06
greatest
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well it's the universal law of
00:15:10
gravitation so the force is always the
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same
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or when the comet is furthest
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from the sun or when the comet is
00:15:19
approaching the sun
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or when the comet is moving away from
00:15:24
the sun
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or when the comet is closest to the sun
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what do you think
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when is the force of gravity between the
00:15:31
comet and the sun the greatest let's
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remember remind ourselves about the
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equation
00:15:35
force equals g then it's got the two
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masses multiplied
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divided by the distance squared
00:15:44
so the masses aren't changing in this in
00:15:46
this problem right the masses are always
00:15:48
the same and g is always the same but
00:15:49
the distance is changing
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because it's a highly eccentric orbit is
00:15:52
going from close to far
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you divide the force by the distance
00:15:57
squared
00:15:58
so a bigger distance is a smaller force
00:16:01
so a smaller distance is a larger force
00:16:02
the answer
00:16:04
the force must be greatest when the
00:16:06
comet is closest so it must be
00:16:08
d when the c so when the objects are
00:16:11
close together
00:16:12
there's a large force when they're
00:16:13
further apart it's a small force
00:16:16
so when the comet is closest to the sun
00:16:18
is when the force is greatest
00:16:22
which leads us to our last little
00:16:24
instant review quiz question
00:16:25
when in the highly eccentric orbit of a
00:16:27
comet is the comet's acceleration
00:16:30
the greatest i mean the same
00:16:33
things here furthest approaching closest
00:16:35
moving away
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or both b and d
00:16:41
so is it when it's furthest away when
00:16:44
it's coming toward it
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it's kind of falling in toward the
00:16:49
sun or when it's kind of scooting moving
00:16:51
out away from the sun maybe the
00:16:52
acceleration be like slowing down
00:16:54
the quickest or when it's closest
00:16:58
when it's spinning around with that's
00:16:59
crystalline as close as we know it's
00:17:00
moving the fastest
00:17:02
but where is the acceleration the
00:17:05
greatest
00:17:08
well there's a few ways we can think
00:17:09
about this one way is we can remember
00:17:13
the last question which said that the
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force
00:17:16
is the greatest when it's close and then
00:17:18
remember
00:17:20
newton's second law that says the
00:17:22
acceleration
00:17:23
depends on the force the bigger the
00:17:25
force the bigger acceleration
00:17:27
that would say that the biggest
00:17:29
acceleration
00:17:30
is when the force is the biggest and
00:17:32
that would say that it is when
00:17:34
the comet is closest to the sun
00:17:40
now it's interesting when the comet is
00:17:42
closest to the sun
00:17:44
that's when it's moving the fastest but
00:17:45
also it's kind of when the speed is
00:17:47
changing
00:17:48
the least the speed is not changing when
00:17:50
it's closest to the sun
00:17:53
but the direction is changing very
00:17:55
rapidly and remember acceleration
00:17:57
is a change in velocity in other words a
00:17:59
change in speed
00:18:00
or direction and so the force of gravity
00:18:03
is the strongest one is closest to the
00:18:05
sun
00:18:05
therefore the acceleration is largest
00:18:08
when it's closest to the sun
00:18:09
and what's happening there is the
00:18:10
direction is changing rapidly
00:18:12
when it's close to the sun so the answer
00:18:14
there is
00:18:15
c all right are we starting to
00:18:17
understand
00:18:18
how newton's laws cause orbits
00:18:23
you have the object moving you have the
00:18:25
force of gravity pulling on it changing
00:18:27
its direction
00:18:28
and it just moves along and as it moves
00:18:29
the force is continuously trying to
00:18:31
change the direction
00:18:32
and the faster the further away it is
00:18:36
the less the force the closer it is the
00:18:37
greater the force as it moves away
00:18:39
there's force pulling it back so it
00:18:41
slows down when it's
00:18:42
when it's coming toward it the force is
00:18:44
accelerating it forward and
00:18:46
continuing to cause it to curve so in
00:18:48
the end you end up
00:18:49
with an ellipse why is it an ellipse and
00:18:51
not some other shape
00:18:53
because the answer is an ellipse okay
00:18:57
there we go moving on
00:19:00
the next thing we talked about was free
00:19:02
fall remember this question
00:19:04
we have our astronaut floating in space
00:19:07
and we ask why is the astronaut floating
00:19:11
and not falling to the earth remember
00:19:14
there's still the force of gravity
00:19:15
acting on him
00:19:17
in fact he's only about five percent
00:19:20
lighter
00:19:21
than he would be on the surface a five
00:19:22
percent less force of gravity therefore
00:19:25
five percent less weight
00:19:26
not mass but wait
00:19:29
so why is he floating and not falling to
00:19:31
the earth
00:19:32
the answer is because he is
00:19:36
in orbit like his spacecraft the thing
00:19:39
we just talked about he is moving
00:19:40
forward gravity is pulling him toward
00:19:42
the earth
00:19:43
and so he's turning but he's going fast
00:19:46
enough that he never hits the earth he
00:19:48
just keeps
00:19:48
curving around it like the spacecraft in
00:19:50
our little calculation we did
00:19:52
so he is orbiting at the same speed of
00:19:55
his spacecraft
00:19:57
so he feels weightless he feels
00:20:00
that he's just responding to whatever
00:20:02
gravity he wants him to do
00:20:04
so he feels like he has no weight he is
00:20:06
an orbit like his spacecraft
00:20:08
he's traveling at around 26 000
00:20:10
kilometers per hour in this case
00:20:11
so the force required to make him go in
00:20:13
a circle is the same as the force of
00:20:16
gravity
00:20:18
pretty cool all right free fall
00:20:22
whenever the only thing acting on you is
00:20:24
the force of gravity
00:20:26
then we say you are in free fall it
00:20:28
feels like you're falling
00:20:30
even though he's not going toward the
00:20:31
center of the earth he
00:20:33
the only thing acting on him is gravity
00:20:35
therefore he feels weightless
00:20:40
i can explain this slightly and a
00:20:41
different way a bit if you've ever been
00:20:43
to the amusement park and gone those
00:20:44
spinny rides
00:20:45
and they push you back against the uh
00:20:48
the wall
00:20:49
that pushing back it feels just like
00:20:51
gravity
00:20:52
now imagine you're on a spinny thing but
00:20:55
you're spinning at just the right rate
00:20:57
so that the force of spinning of
00:21:01
being turned into a circle equals the
00:21:03
force of gravity and they exactly cancel
00:21:05
then you would feel weightless that's
00:21:07
what's happening to him
00:21:08
he's going around the earth at 26 000
00:21:11
kilometers per hour
00:21:13
the force of gravity pulling him down
00:21:16
exactly equals the force required to
00:21:19
make him go in a circle
00:21:20
and therefore he is weightless and he's
00:21:21
going in a circle that's pretty cool all
00:21:24
right
00:21:25
free fall
00:21:28
now on to our new topic for the day
00:21:31
we're going to take these same ideas
00:21:32
we've been talking about about force
00:21:34
and apply them to trying to understand
00:21:37
where the heck tides come from so let's
00:21:40
start here
00:21:40
here we have the earth looking down at
00:21:42
the north pole here we have the moon
00:21:44
looking down at the north pole of the
00:21:45
moon
00:21:46
we have the force of gravity force
00:21:49
equals
00:21:49
gm1 m2 over r squared m1 is the mass of
00:21:53
the earth
00:21:54
m2 the mass of the moon r
00:21:57
is the distance between the centers of
00:21:59
the
00:22:00
planets that's the force on the whole of
00:22:03
the earth acting on
00:22:05
the whole of the moon but what if i say
00:22:08
i don't want to talk about yeah
00:22:09
so the gravitational attraction between
00:22:11
the earth and the moon applies a force
00:22:13
okay but what if i don't want to talk
00:22:15
about just the force
00:22:17
of gravity on the center of the earth
00:22:20
let's imagine
00:22:21
i think about you know uh a bit of rock
00:22:24
here on the edge um
00:22:26
just on this side of the earth i'm just
00:22:27
going to imagine just a little mini
00:22:29
sphere
00:22:30
of rock right it's part of the earth but
00:22:33
i'm going to say what's the force
00:22:34
of gravity on that rock from the moon
00:22:38
well it's closer so a given chunk of
00:22:42
rock
00:22:44
will have a larger force than a chunk at
00:22:47
the same mass at the center of the earth
00:22:50
from the moon because it's closer so
00:22:51
here it's closer there's a larger force
00:22:53
applied to a chunk of rock here
00:22:55
than a chunk of rock there if the trunk
00:22:57
is rocking the same size
00:22:59
the fact that the rocks are all
00:23:00
connected together doesn't really matter
00:23:01
right we're saying what's the force of
00:23:02
gravity on this bit of the earth
00:23:04
force of gravity in this bit of the
00:23:05
earth is stronger than the force of
00:23:06
gravity on this bit of the earth
00:23:08
because it's closer to the moon the
00:23:10
force of gravity from the moon
00:23:12
on this chunk of rock is larger than the
00:23:14
force of gravity from this chunk of rock
00:23:16
which will cause that chunk of rock to
00:23:18
be pulled this way
00:23:19
compared to the center well how about
00:23:23
back here what about a chunk of rock out
00:23:26
here a long way
00:23:28
further from the moon well it's further
00:23:30
away
00:23:31
so there will be a smaller force applied
00:23:33
to a chunk of rock
00:23:35
further from the moon
00:23:39
so the force of gravity from the moon is
00:23:42
less here
00:23:43
than here and greater here than here
00:23:49
so what's that gonna do well this is
00:23:52
pulling away from here and this is
00:23:54
pulling away from here
00:23:55
so it's gonna take the entire earth and
00:23:58
stretch it
00:24:01
in the direction of the moon right this
00:24:03
is pulling
00:24:04
harder than here so this pulls away from
00:24:06
here so this this point stretches away
00:24:07
from this point
00:24:08
and then this point stretches away from
00:24:10
that point so this stretches away from
00:24:12
there
00:24:13
and this stretches away from there so
00:24:15
the whole earth gets
00:24:17
squished up now the earth is going to
00:24:19
move due to the average force on the
00:24:21
whole earth unless the earth breaks
00:24:23
but if the earth doesn't break then all
00:24:25
that's going to happen is the earth is
00:24:26
going to get
00:24:27
stretched and the same thing
00:24:32
will happen to the moon now this course
00:24:33
doesn't happen right away right
00:24:35
um it turns out that uh rock
00:24:38
and the earth's mantle this thing stuff
00:24:40
to make earth is made of doesn't bend
00:24:41
very quickly it kind of
00:24:43
you push a force and it goes okay
00:24:46
so this bending into a blob like this
00:24:50
doesn't happen right away it takes time
00:24:52
before it bends to its natural shape
00:24:56
so what do we do with this well the
00:24:58
earth is rotating
00:25:00
and it's rotating too quickly for the
00:25:03
rock and the mantle to really respond
00:25:04
much
00:25:05
so here's the earth spinning around it's
00:25:07
trying to squish out like this toward
00:25:09
the earth toward the moon
00:25:10
because of this differential force but
00:25:12
by the time it starts to move
00:25:14
the earth is rotated and it tries to
00:25:15
move different way and it's rotating to
00:25:16
try to move a different way
00:25:18
so you end up with the shape of the
00:25:19
earth barely changing
00:25:23
that's rock and the mantle but what if
00:25:26
instead the whole earth were covered in
00:25:29
a large ocean
00:25:32
well if the whole earth was covered in a
00:25:33
large ocean well the ocean
00:25:36
would move the ocean would stretch out
00:25:39
compared to the moon
00:25:42
they'd have time to ocean would have
00:25:43
time to flow they'd respond
00:25:46
so what we find is that in fact the
00:25:48
oceans on earth do respond to the tidal
00:25:50
forces from the moon
00:25:51
so the oceans do squeeze out and it gets
00:25:53
the oceans are thicker on this side
00:25:56
oceans are thicker toward the moon or
00:25:57
just oceans are thicker away from the
00:25:58
moon
00:25:59
and they're thinner um in this direction
00:26:03
because of the force from the moon now
00:26:04
something funny about this picture
00:26:05
you'll notice
00:26:06
i drew it i drew it tipped
00:26:11
that's because the earth is turning and
00:26:14
friction with rotating earth causes the
00:26:16
tidal bulge to lag behind
00:26:18
so it's not quite lined up with the moon
00:26:19
it's lagging behind a bit
00:26:21
just because of friction between the
00:26:23
earth
00:26:24
and the oceans so the earth is turning
00:26:27
the oceans are responding to the force
00:26:28
from the moon
00:26:29
but because it's turning it lags so you
00:26:31
get you get these tidal bulges
00:26:34
lagging behind um the direction pointing
00:26:36
at the moon
00:26:37
if you notice there's a there's a tidal
00:26:38
bulge back here and a tidal bulge up
00:26:40
here remember
00:26:42
this part is being pulled away from this
00:26:43
part this part is being pulled away from
00:26:45
this part
00:26:45
so the whole earth gets stretched you
00:26:47
don't just get a blob
00:26:48
on the side facing the moon you get a
00:26:50
bulge on the side
00:26:52
away from the moon because of this
00:26:54
differential force
00:26:55
where the back pulse not as hard as the
00:26:57
middle pull is not as hard
00:26:59
as the front so the whole thing gets
00:27:00
stretched out now i'm saying it with
00:27:02
words
00:27:04
you may think i don't really get that
00:27:06
that's okay the only way to really
00:27:08
understand it
00:27:08
i think is to do the proper math do the
00:27:11
proper
00:27:12
integrations which we're not going to do
00:27:14
because we're not doing math in this
00:27:15
class
00:27:16
so i kind of tried to explain to you how
00:27:20
this squeezing action works to really
00:27:23
understand it you have to do the math
00:27:25
so all you need to know all you need to
00:27:28
know
00:27:29
is that there's a bulge on both sides of
00:27:30
the earth because of the moon
00:27:32
on the side facing the earth moon and
00:27:34
the side away from the moon
00:27:35
and that the um
00:27:39
the bulge lags because of the spinning
00:27:41
of the earth those are things you need
00:27:42
to know
00:27:43
exactly why it is it comes from the
00:27:46
force of gravity it comes from newton's
00:27:47
laws it comes from
00:27:49
models of friction but um and inertia
00:27:52
and viscosity but uh
00:27:57
those are much more complicated topics
00:27:59
because you actually need to do the math
00:28:00
to really understand them
00:28:01
so just kind of get the basic idea you
00:28:03
can
00:28:04
think about it all right i kind of get
00:28:07
it
00:28:07
that's that's good enough okay that's i
00:28:10
guess that's good enough
00:28:13
so this leg applies a force
00:28:16
on the earth causing its rotation to
00:28:19
slow down there's a there's a force
00:28:20
being applied
00:28:21
because the thing is turning the moon is
00:28:25
pulling on it and then it's kind of
00:28:27
dragging against it so that dragging
00:28:30
forms a force that actually is trying to
00:28:33
slow the earth's rotation
00:28:36
down i mean it's a huge effect
00:28:39
in fact when the earth was first formed
00:28:41
the rotation period was only 14 hours a
00:28:43
day was
00:28:44
14 hours long when the earth was first
00:28:46
formed
00:28:47
but now billions of years later because
00:28:48
of this force from the moon continuously
00:28:50
applying a force on the rotation of the
00:28:52
earth
00:28:52
the earth has slowed down to the point
00:28:54
where a day is now 24 hours
00:28:58
that's cool what that means
00:29:02
is that the rotation of the earth is
00:29:03
getting slower and will continue to get
00:29:05
slower and slower and slower
00:29:07
and if the sun wasn't going to blow the
00:29:10
earth up
00:29:10
in a few billion years in billions of
00:29:13
years the earth's rotation would finally
00:29:15
stop and the earth would always be
00:29:18
the same side of the earth would always
00:29:20
be facing the moon in the same way
00:29:22
that the same side of the moon is always
00:29:24
facing the earth in
00:29:26
fact that's what happened to the moon
00:29:28
now the earth
00:29:29
is much more massive than the moon the
00:29:31
force of gravity
00:29:32
the tidal forces on the moon are much
00:29:35
larger than the tidal forces
00:29:37
um on the earth from the moon the title
00:29:40
forces from the
00:29:41
earth on the moon are much larger than
00:29:43
tidal forces of the moon
00:29:44
on the earth and the moon is much
00:29:47
smaller much lighter much easier to
00:29:48
speed up and slow down
00:29:50
consequently the rotation of the moon
00:29:53
has stopped relative to the earth it is
00:29:56
now
00:29:56
tidally locked so the faint same side of
00:29:59
the
00:30:00
earth always faces same side of the moon
00:30:02
always faces the earth
00:30:03
it does it no longer spins relative to
00:30:07
the
00:30:07
earth that's because of this tidal
00:30:09
effect the force
00:30:11
the tidal forces causing the moon to be
00:30:13
elongated
00:30:14
for it to turn would require that rock
00:30:16
to being continuously being squeezed and
00:30:18
unsqueezed and that takes energy
00:30:20
that produces friction and it would it
00:30:22
slowed down
00:30:23
the rotation of the moon until finally
00:30:26
the same side of the moon
00:30:27
always faces the earth tidal locking
00:30:30
so that wow there was this mystery we
00:30:33
had
00:30:34
why is the rotation of the moon exactly
00:30:36
right so the same size of the moon
00:30:37
faces the earth it's because of this
00:30:40
tidal force
00:30:41
the same effect that's that made the
00:30:43
earth do that
00:30:44
is making uh made the moon do that is
00:30:47
slowly making the earth do that
00:30:49
oh that's oh that's cool well there it
00:30:52
is
00:30:53
now we know same side of the moon always
00:30:55
faces the earth because of
00:30:57
tidal forces
00:31:00
cool all right review instant review
00:31:03
quiz
00:31:04
in this model that i showed you how many
00:31:07
tides are there
00:31:08
in a day is there one tide
00:31:12
when you're facing the moon or is there
00:31:15
one tide
00:31:16
one high tide a little after you're
00:31:19
facing the moon because of that leg
00:31:21
or is there two one when you're facing
00:31:24
the moon and one
00:31:25
on the opposite side because there's two
00:31:27
bulges
00:31:28
or is it d2 a little after you're facing
00:31:32
the moon because the leg and then around
00:31:35
12 hours later
00:31:36
well it's d right there's there's two
00:31:40
tides there's two high tides there's the
00:31:42
one
00:31:44
sort of facing the moon and the one sort
00:31:46
of facing opposite the moon
00:31:47
but they are um lagged from each other
00:31:50
because of
00:31:51
um that friction effect the same effect
00:31:55
that's slowing down the earth so it
00:31:57
it the day gets longer and longer and
00:32:00
which cause the moon to stop uh rotating
00:32:04
relative to the earth all right there we
00:32:06
go it's the review quiz complete
00:32:10
okay so the idea called tidal locking
00:32:13
friction with rotating earth causes the
00:32:14
tidal bulge
00:32:15
to lag behind this leg applies a force
00:32:18
on the earth causing its rotation to
00:32:19
slow down
00:32:20
rotation periods of 14 hour okay we
00:32:22
already did all this it's weird
00:32:26
now
00:32:35
okay well it turns out you might be
00:32:37
asking yourself well doesn't the sun
00:32:39
also provide a gravitational force on
00:32:41
the earth after all
00:32:42
the earth is orbiting around the sun
00:32:45
surely
00:32:46
the sun must provide a gravitational
00:32:49
force on the earth and therefore
00:32:51
the sun presumably would cause
00:32:54
tides on the earth and the answer is yes
00:32:57
it does
00:32:58
the sun also causes tidal forces on the
00:33:00
earth
00:33:01
the sun is much more massive so you'd
00:33:03
think well maybe it's going to provide
00:33:05
larger tidal forces but it's much
00:33:07
further away
00:33:08
so maybe you'd conclude that it provides
00:33:10
much smaller title forces
00:33:11
it turns out that um the further away
00:33:16
component overwhelms the larger
00:33:19
mass of the sun component so it ends up
00:33:22
that the
00:33:23
tides from the sun are smaller than the
00:33:26
tides from the moon
00:33:27
but in the same kind of order when
00:33:31
the earth when the moon the earth
00:33:35
and the sun in that direction are all
00:33:36
lined up in other words when you're on a
00:33:38
full moon
00:33:38
or a new moon because it can be over
00:33:40
here or over there
00:33:42
when you're all lined up in a full moon
00:33:44
or a new moon
00:33:45
the tidal forces from the moon and the
00:33:48
tidal forces from the i should say sun
00:33:50
tide emerges from the moon and from the
00:33:51
sun add together
00:33:54
this is called a spring tide
00:33:59
on a full moon and a new moon the tidal
00:34:01
forces from the moon
00:34:02
and the earth add together you get a
00:34:05
spring tide
00:34:10
when the on a quarter moon when the sun
00:34:13
is down here
00:34:14
down below looking up this way and a
00:34:17
quarter moon
00:34:18
the tidal forces from the sun partially
00:34:20
cancel
00:34:21
the tidal forces from the moon this is
00:34:23
called a neap tide it's a smaller tide
00:34:27
so the sun is trying to make tidal
00:34:30
bulges
00:34:30
aligned this way but lagged because of
00:34:32
the rotation of the earth
00:34:34
the moon is trying to make tidal bulges
00:34:36
aligned this way
00:34:38
the moon beats the sun but the sun makes
00:34:40
the tides smaller
00:34:42
so you get small tides during a quarter
00:34:45
moon
00:34:46
and you get large tides during a full
00:34:49
moon
00:34:50
that's the theory anyway let's see what
00:34:53
you
00:34:53
actually get here we have tide tables
00:34:57
for tofino british columbia so this is
00:34:59
on the
00:35:01
west coast of vancouver island so you're
00:35:03
just right on the edge of the pacific
00:35:04
ocean
00:35:05
and what you find is that near a
00:35:09
new full moon or near a new moon you get
00:35:11
large tides
00:35:13
during the quarter moon you get smaller
00:35:15
tides
00:35:16
you also see you get two tides per day
00:35:19
one so you get one high tide in the
00:35:21
daytime here and one high tide at night
00:35:23
day night day night all along that's
00:35:27
pretty cool um just like we said it
00:35:30
should be
00:35:31
so this really does appear to be the
00:35:33
explanation for tides
00:35:35
now there's some weird things going on
00:35:37
slightly
00:35:38
it turns out that this model we just
00:35:41
gave gave gives the tidal levels for the
00:35:44
kind of the whole earth but when you
00:35:45
have water flowing up and down channels
00:35:47
and up and down
00:35:48
inlets and and things that
00:35:51
flow kind of messes up this easy
00:35:53
calculation because it get even more lag
00:35:55
and more weird delay so if you look at a
00:35:57
tide table for somewhere
00:35:58
that's more inland maybe up a inlet or
00:36:00
something you won't get this nice double
00:36:02
bumps like this it'll look a little bit
00:36:04
different that's just because the water
00:36:06
takes time to flow and it kind of
00:36:07
bounces around a bit
00:36:08
it's much more complicated to calculate
00:36:10
but this this
00:36:11
this story really does apply to the
00:36:14
rising and lowering of the
00:36:15
ocean as a whole when you have a
00:36:19
full moon or a new moon you get large
00:36:21
tides when you have a quarter moon
00:36:23
you get smaller tides that's because the
00:36:25
tides from the
00:36:28
sun cancel out the tides from the uh
00:36:31
moon to some level
00:36:32
all right so we're almost done here
00:36:35
finally
00:36:36
we can go ahead and look at this plot we
00:36:37
this the simulation we saw
00:36:39
last class now remember this last class
00:36:41
we were looking at how
00:36:42
um charon
00:36:46
is orbiting around pluto but not around
00:36:49
the center of pluto's
00:36:50
orbiting around a spot kind of in
00:36:52
between pluto and charon
00:36:54
because the mass of cheron is kind of
00:36:58
almost large compared to the mass of
00:36:59
pluto so it actually orbits around this
00:37:01
spot right there
00:37:03
we also noticed that the same side of
00:37:06
charon
00:37:06
always all the same side of pluto always
00:37:08
faces charon
00:37:09
and the same side of charon always
00:37:11
spaces pluto before we didn't really
00:37:13
understand why that is but now we do
00:37:15
it's this tidal locking if charon were
00:37:18
to be rotating compared to
00:37:19
pluto that squeezing of the shape of
00:37:22
charon
00:37:23
due to pluto would be significant and it
00:37:25
would they would you're trying to make
00:37:27
this oblong shape and as it turned
00:37:29
it would be like break the rock and bend
00:37:31
it and that would take energy
00:37:33
that presumably was happening at one
00:37:35
point in the in the life of pluto and
00:37:36
charon
00:37:37
but that rotating gradually slowed down
00:37:41
charon's rotation until finally the same
00:37:43
side always faces pluto
00:37:44
and exactly the same thing pluto the
00:37:46
charon trying to bend pluto
00:37:49
pluto originally was probably rotating
00:37:51
compared to charon
00:37:52
but then finally because of millions and
00:37:55
billions of years of this rotation
00:37:57
it just dissipated the energy until
00:37:59
finally it rolled to a stop
00:38:00
so the same side of charon always faces
00:38:03
same side of pluto always faces cheer on
00:38:04
the same side of cheron always faces
00:38:07
pluto
00:38:09
so in the last two classes we've looked
00:38:11
at how newton's laws
00:38:12
can be used to describe the behavior of
00:38:15
many many things in the universe
00:38:17
from falling haber hammers to the orbit
00:38:20
of charon around pluto
00:38:21
we can use it to understand um tides we
00:38:24
can understand
00:38:25
use it to understand why the same face
00:38:27
of this moon is always facing the earth
00:38:30
and this was the start of a huge
00:38:33
revolution in science
00:38:35
where people began to believe that
00:38:38
we could really understand the behavior
00:38:40
of anything
00:38:41
in the universe and newton's laws of
00:38:44
motion
00:38:44
and later physics from them had became
00:38:47
incredibly successful
00:38:49
in understanding a huge wide range of
00:38:51
phenomena and by the 19th century
00:38:53
electromagnetism the laws of
00:38:55
electromagnetic magnetism came along the
00:38:57
laws of understanding how light behaved
00:38:59
and we kind of came to a point
00:39:02
where the assumption was that we really
00:39:04
understand the behavior of
00:39:06
everything now there's a limit to this
00:39:09
right we don't know
00:39:10
why f equals m a we don't know why the
00:39:13
acceleration is proportion of the force
00:39:15
divided by the mass we don't know why
00:39:17
the acceleration of a particle is
00:39:19
inversely proportional to the distance
00:39:21
um from a massive object i mean we can
00:39:24
say things but
00:39:25
why is it that way instead of some other
00:39:27
way we don't really know but
00:39:29
we know that if that is how the universe
00:39:32
behaves and it does
00:39:33
then we can predict the behavior of a
00:39:35
great many many things now
00:39:38
by the end of the 19th century there
00:39:41
were very few
00:39:42
things missing very few
00:39:45
experiments didn't quite match the data
00:39:47
one of them
00:39:48
was that the orbit of mercury
00:39:51
disagreed with newton's laws that is to
00:39:55
say
00:39:56
mercury's orbit was off just by this
00:39:59
tiny little bit
00:40:02
he's like what's small it is small
00:40:06
but there's no particular reason why
00:40:08
newton's laws shouldn't be
00:40:09
perfect lots of explanations maybe
00:40:11
there's another planet maybe the sun
00:40:13
isn't perfectly spherical
00:40:14
but none of these could be made to fit
00:40:16
the data
00:40:18
until finally in the early 20th century
00:40:21
another
00:40:22
extraordinarily famous physicist albert
00:40:24
einstein
00:40:26
proposed his theory of general
00:40:28
relativity which
00:40:30
supplants newton's laws of motion
00:40:34
and newton's sorry einstein's
00:40:38
view of the universe is very different
00:40:41
than
00:40:41
the view of the universe described in
00:40:44
newtonian
00:40:45
mechanics space-time is actually
00:40:49
bent by mass it's not a force it's a
00:40:52
warping of space-time
00:40:53
and so he would say the reason that the
00:40:56
orbit of mercury was off is because in
00:40:58
fact space near the sun is bent
00:40:59
and the distance is a little bit larger
00:41:01
than you thought it was
00:41:03
crazy weird ideas but if you take
00:41:07
einstein's description of what the way
00:41:09
the universe works
00:41:11
all of a sudden all these errors go away
00:41:13
and then it predicted other things it
00:41:14
predicted
00:41:15
gravitational waves being emitted by
00:41:18
spinning objects it predicted the
00:41:19
existence of black holes
00:41:21
places where gravity is so strong that
00:41:24
light can't even get out and in fact as
00:41:26
you get close to the black hole time
00:41:27
itself slows down
00:41:29
these crazy crazy objects objects which
00:41:32
have been
00:41:32
confirmed predictions that have been
00:41:35
shown to be true
00:41:36
so we now would say
00:41:41
newton's laws of motion well they're not
00:41:45
they're not right they're they're
00:41:48
wrong
00:41:52
they're wrong in that they don't always
00:41:54
predict
00:41:55
the behavior the universe will will
00:41:57
experience
00:41:58
they usually do except for in really
00:42:00
weird places where the gravitational
00:42:02
forces are enormous
00:42:03
like near the sun or near a black hole
00:42:07
will we then go and say that newton was
00:42:09
wrong or that his theories were of no
00:42:11
value no
00:42:12
no they're still very very useful if you
00:42:14
want to calculate what happens when you
00:42:15
kick a football newton's laws are great
00:42:17
you do not want to mess around with
00:42:19
the einstein equations because they are
00:42:21
so unbelievably complicated to use
00:42:24
but we also would say that it's an
00:42:26
incomplete theory
00:42:28
this is how things work in in physics
00:42:32
we come up with a description of the
00:42:34
behavior of the universe we do
00:42:35
experiments to test the description
00:42:37
until we find a discrepancy and then we
00:42:40
look for
00:42:42
a modification to the theory or a whole
00:42:44
new way of looking at it
00:42:45
that will explain this discrepancy and
00:42:48
so that we can
00:42:49
again say we have a model that fits all
00:42:51
the observations
00:42:52
we are now back into a place like we
00:42:54
were in the 19th century
00:42:55
where to a pretty impressive level
00:42:59
there isn't an experiment we can think
00:43:00
of where we could not at least in
00:43:02
principle calculate
00:43:04
what the outcome of the experiment would
00:43:06
be there's a small number of pla of
00:43:08
exceptions we don't know how to describe
00:43:10
the extremely extremely early universe
00:43:13
the first tiny fraction of a second when
00:43:15
the temperatures and densities were high
00:43:17
enough
00:43:17
we don't think we know how to calculate
00:43:19
what happens there there's this
00:43:21
mysterious thing in the universe we call
00:43:23
dark energy which causes causing the
00:43:25
universe's
00:43:25
expansion to speed up we don't really
00:43:28
know what causes that where it's from
00:43:29
what it's doing
00:43:32
but they're very very few
00:43:35
areas we just don't know how to
00:43:37
calculate them it's we're hopeful
00:43:39
that it is in searching out those
00:43:42
unexplained
00:43:43
areas that hopefully we can come up to a
00:43:46
new understanding how the universe works
00:43:47
science continues um we've been able to
00:43:50
accomplish a lot
00:43:52
but we we aren't done
00:43:55
looking forward to the next class when
00:43:56
we'll start looking at the sun and at
00:43:58
light
00:43:58
thank you very much
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