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Newton's 3 Laws, with a bicycle - Joshua Manley

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    Have you ever noticed that it's harder to start pedaling your bicycle
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    than it is to ride at a constant speed?
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    Or wondered what causes your bicycle to move?
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    Or thought about why it goes forward instead of backwards or sideways?
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    Perhaps not, and you wouldn't be alone.
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    It wasn't until the 17th century
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    that Isaac Newton described the fundamental laws of motion
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    and we understood the answer to these three questions.
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    What Newton recognized was that things tend to keep on doing
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    what they are already doing. So when your bicycle is stopped,
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    it stays stopped, and when it is going,
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    it stays going.
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    Objects in motion tend to stay in motion
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    and objects at rest tend to stay at rest.
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    That's Newton's First Law.
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    Physicists call it the Law of Inertia, which is a fancy way of saying
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    that moving objects don't spontaneously speed up, slow down, or change direction.
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    It is this inertia that you must overcome to get your bicycle moving.
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    Now you know that you have to overcome inertia to get your bicycle moving,
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    but what is it that allows you to overcome it?
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    Well, the answer is explained by Newton's Second Law.
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    In mathematical terms, Newton's Second Law says
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    that force is the product of mass and acceleration.
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    To cause an object to accelerate, or speed up,
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    a force must be applied.
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    The more force you apply,
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    the quicker you accelerate. And the more mass your bicycle has,
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    and the more mass you have too,
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    the more force you have to use to accelerate at the same rate.
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    This is why it would be really difficult to pedal a 10,000 pound bicycle.
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    And it is this force, which is applied by your legs pushing down on the pedals,
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    that allows you to overcome Newton's Law of Inertia.
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    The harder you push down on the pedals, the bigger the force
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    and the quicker you accelerate.
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    Now on to the final question:
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    When you do get your bike moving,
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    why does it go forward?
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    According to Newton's Third Law, for every action,
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    there is an equal and opposite reaction.
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    To understand this, think about what happens when you drop a bouncy ball.
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    As the bouncy ball hits the floor,
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    it causes a downward force on the floor.
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    This is the action.
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    The floor reacts by pushing on the ball with the same force,
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    but in the opposite direction - upward -
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    causing it to bounce back up to you.
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    Together, the floor and the ball form what's called
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    the action/ reaction pair. When it comes to your bicycle,
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    it is a little more complicated. As your bicycle wheels spin
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    clockwise, the parts of each tire touching the ground
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    push backwards against the earth -
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    the actions. The ground pushes forward with the same force
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    against each of your tires - the reactions.
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    Since you have two bicycle tires, each one forms an action/ reaction pair
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    with the ground. And since the Earth is really really really big,
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    compared to your bicycle, it barely moves
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    from the forced caused by your bicycle tires pushing backwards -
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    but you are propelled forward.
Title:
Newton's 3 Laws, with a bicycle - Joshua Manley
Description:

Watch full lesson here: http://ed.ted.com/lessons/joshua-manley-newton-s-3-laws-with-a-bicycle

Why would it be hard to pedal a 10,000 pound bicycle? This simple explanation shows how Newton's 3 laws of motion might help you ride your bike.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
03:33
Jessica Ruby edited English subtitles for Newton's 3 Laws, with a bicycle - Joshua Manley
Maggie S (Amara staff) edited English subtitles for Newton's 3 Laws, with a bicycle - Joshua Manley
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