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Momentum: Ice skater throws a ball | Impacts and linear momentum | Physics | Khan Academy

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    Welcome back.
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    I'll now do a couple of more
    momentum problems.
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    So this first problem, I have
    this ice skater and she's on
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    an ice skating rink.
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    And what she's doing is
    she's holding a ball.
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    And this ball-- let me draw
    the ball-- this is a 0.15
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    kilogram ball.
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    And she throws it.
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    Let's just say she throws it
    directly straight forward in
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    front of her, although
    she's staring at us.
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    She's actually forward
    for her body.
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    So she throws it exactly
    straight forward.
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    And I understand it is hard to
    throw something straight
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    forward, but let's assume
    that she can.
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    So she throws it exactly
    straight forward with a
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    speed-- or since we're going to
    give the direction as well,
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    it's a velocity, right, cause
    speed is just a magnitude
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    while a velocity is a magnitude
    and a direction-- so
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    she throws the ball at 35 meters
    per second, and this
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    ball is 0.15 kilograms.
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    Now, what the problem says is
    that their combined mass, her
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    plus the ball, is 50 kilograms.
    So they're both
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    stationary before she does
    anything, and then she throws
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    this ball, and the question is,
    after throwing this ball,
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    what is her recoil velocity?
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    Or essentially, well how much,
    by throwing the ball, does she
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    push herself backwards?
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    So what is her velocity in
    the backward direction?
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    And if you're not familiar with
    the term recoil, it's
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    often applied to when someone,
    I guess, not that we want to
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    think about violent things, but
    if you shoot a gun, your
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    shoulder recoils back,
    because once
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    again momentum is conserved.
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    So there's a certain amount of
    momentum going into that
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    bullet, which is very light
    and fast going forward.
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    But since momentum is conserved,
    your shoulder has
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    velocity backwards.
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    But we'll do another
    problem with that.
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    So let's get back
    to this problem.
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    So like I just said, momentum
    is conserved.
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    So what's the momentum at the
    start of the problem, the
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    initial momentum?
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    Let me do a different color.
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    So this is the initial
    momentum.
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    Initially, the mass is 50
    kilograms, right, cause her
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    and the ball combined are 50
    kilograms, times the velocity.
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    Well the velocity is 0.
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    So initially, there is 0
    velocity in the system.
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    So the momentum is 0.
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    The P initial is equal to 0.
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    And since we start with a net 0
    momentum, we have to finish
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    with a net 0 momentum.
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    So what's momentum later?
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    Well we have a ball moving at
    35 meters per second and the
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    ball has a mass of 0.15
    kilograms. I'll ignore the
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    units for now just
    to save space.
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    Times the velocity
    of the ball.
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    Times 35 meters per second.
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    So this is the momentum of the
    ball plus the new momentum of
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    the figure skater.
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    So what's her mass?
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    Well her mass is going
    to be 50 minus this.
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    It actually won't matter a ton,
    but let's say it's 49--
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    what is that-- 49.85 kilograms,
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    times her new velocity.
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    Times velocity.
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    Let's call that the velocity
    of the skater.
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    So let me get my trusty
    calculator out.
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    OK, so let's see.
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    0.15 times 35 is
    equal to 5.25.
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    So that equals 5.25.
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    plus 49.85 times the skater's
    velocity, the final velocity.
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    And of course, this equals
    0 because the initial
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    velocity was 0.
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    So let's, I don't know, subtract
    5.25 from both sides
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    and then the equation becomes
    minus 5.25 is equal to 49.85
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    times the velocity
    of the skater.
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    So we're essentially saying that
    the momentum of just the
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    ball is 5.25.
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    And since the combined system
    has to have 0 net momentum,
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    we're saying that the momentum
    of the skater has to be 5.25
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    in the other direction, going
    backwards, or has a momentum
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    of minus 5.25.
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    And to figure out the velocity,
    we just divide her
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    momentum by her mass.
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    And so divide both sides by
    49.85 and you get the velocity
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    of the skater.
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    So let's see.
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    Let's make this a negative
    number divided by 49.85 equals
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    minus 0.105.
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    So minus 0.105 meters
    per second.
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    So that's interesting.
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    When she throws this ball out at
    35 meters per second, which
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    is pretty fast, she will
    recoil back at about 10
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    centimeters, yeah, roughly 10
    centimeters per second.
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    So she will recoil a lot
    slower, although
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    she will move back.
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    And if you think about it, this
    is a form of propulsion.
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    This is how rockets work.
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    They eject something that maybe
    has less mass, but super
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    fast. And that, since we have a
    conservation of momentum, it
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    makes the rocket move in
    the other direction.
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    Well anyway, let's see if we
    could fit another problem in.
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    Actually, it's probably better
    to leave this problem done and
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    then I'll have more time for the
    next problem, which will
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    be slightly more difficult.
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    See you soon.
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Title:
Momentum: Ice skater throws a ball | Impacts and linear momentum | Physics | Khan Academy
Description:
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Video Language:
English
Team:
Khan Academy
Duration:
06:01

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