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Physics: Newton's Third Law: Actions and Reactions 33 Views


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Newton's Third Law states that every action has an equal and opposite reaction. Something to keep in mind when trolling online.

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Transcript

00:03

Newton's third law actions and reactions....

00:46

Right now, you're being pushed around oh sure you might think you're just [Woman martial artist appears]

00:50

sitting there but oh no someone is giving you a shove every step you take

00:54

you're getting pushed back well I for one have had just about enough of this

00:59

who's the big bully? anyway it's our own planet actually

01:03

Earth and it's time to give it what it deserves that was a real mistake so how [Woman performs karate chop]

01:12

exactly does our planet get away with pushing us around it's all because of

01:17

Newton's third law of motion which states that every action has an equal

01:20

and opposite reaction it sounds all deep and philosophical and if it wasn't about

01:26

physics you'd probably see it on Instagram or something some

01:29

black-and-white picture of the ocean with that quote superimposed but as [Instagram post appears on mobile phone]

01:35

we've seen over and over even though it seems like a simple statement actually

01:40

understanding what it means can be a little tricky if you've been following

01:44

along so far then you'll definitely recognize this thing if you haven't been

01:49

following along this is a free body diagram it lets us visualize all the [Free body diagram appears]

01:53

forces that are acting on an object this particular object is a box stuffed full

01:58

of karate trophies and it's being pushed down the sidewalk to our friend Gary's [Man pushing box of trophies]

02:03

house because Gary doesn't believe that a certain someone really is an awesome

02:07

karate master see that applied force there F sub a

02:11

that's an anonymous person who's doing the pushing normally we wouldn't worry

02:17

about the source of that applied force but when we're dealing with the third

02:21

law we recognize that the box is pushing back just as hard as the applied force

02:26

is pushing forward so how is the box moving then and why isn't the person

02:32

pushing going backwards the answer there is another object involved in the

02:36

scenario and it's a big one when we think about Newton's third law we see

02:42

that it pairs things up we can restate the third law and like this if object a

02:48

exerts force on object B then object B will simultaneously exert an equal force

02:53

on object a in the opposite direction that might help make things a little

02:57

clearer and this set up is what we call third law pairs objects A and B are a [Object A and B appear]

03:03

pair because they're both exerting forces on each other

03:06

the third law is all about how objects or masses interact with each other

03:10

so to understand motion we can look at one third law pair at a time so let's go

03:15

back to the box with the trophy's that they only give out to the best martial [Woman pushing box of trophies]

03:18

artists and I'm just going to admit that yes I'm the one pushing the box because

03:24

it's important for Gary to recognize greatness we have one third law pair

03:28

right there the box and me pushing the box but while my arms push against the

03:33

box my feet are pushing against the ground [Arrows pointing at feet]

03:35

and the ground well that's the whole planet just like the boxes pushing back

03:40

on me as hard as I'm pushing on the box the earth is pushing back up on my feet

03:46

just as hard as my feet are pushing down I'm able to generate more force with my

03:51

feet than the box is able to generate back at me which means that the box

03:55

moves forward the ground and my feet are another third law pair and really the

04:02

box and the ground are yet another pair we may think that since we have forces [Woman with box and forces appear]

04:07

that are equal and opposite they should cancel each other out and there

04:10

shouldn't be any motion but they don't cancel each other out because they're

04:14

not being applied to the same object if the box is at rest and I apply a force

04:19

of 50 Newtons to the trophy box that's enough to overcome it and

04:23

initial inertia and friction so it starts moving when the box is applying

04:28

50 Newton's of force back on me that's not enough force to overcome my own

04:32

inertia and friction so the forces are equal and opposite but they're working

04:36

on different objects which is why the motion resulting from those forces is [Woman discussing forces]

04:40

not the same we can express this law in a formula this equation says that the

04:46

force object A exerts on object B is equal to the negative of the force

04:52

object B exerts on object A since force is a vector one direction is positive

04:58

and the other is negative you might also see it written like this it's the same [Force equations appear]

05:04

thing so if you're pushing a lawn mower across your yard and you exert 75

05:09

newtons of force on the garden implement then it's exerting negative 75 Newtons

05:14

on to you and since we have force that means we can invite mass and

05:18

acceleration to the party per the second law of motion that's the thing about

05:22

Newton's laws well they each address separate concepts we can use them in

05:27

conjunction with each other to understand all kinds of motion one other [Newton appears]

05:31

thing to keep in mind as we think about third law pairs is that the forces

05:35

between the two objects will always be of the same type that means we're not

05:40

going to use contact force on that lawnmower and have it turn around and [Man pushing lawnmower]

05:44

use magnetic force on us, for one thing we're not made of metal so that wouldn't

05:48

even work but for another the third law is big on that whole equal and opposite

05:53

thing there is no way for contact force and magnetism to be equal now I'm going

05:59

to make a guess that you're sitting down right now okay sure you might be [Boy laying down looking at screen]

06:02

watching this in bed or while you're standing on the bus or you're being from

06:06

another planet and the rays of our yellow Sun have allowed you to fly but

06:10

we're still banking that your butt is on your seat and we've seen enough force

06:14

diagrams to know that we've got gravity pulling us down and normal force pulling [Woman watching shmoop video while sitting down]

06:20

us up totally in line with the third law right well actually no remember a third

06:25

law pair isn't two different forces it's two different objects that are exerting

06:30

force on each other we can't have one single object be it's own

06:34

third law partner that's against the law against Newton's law at least let's say

06:39

we've got a hunk of cheese on a table why cheese because we're hungry that's [Martial Artist standing in kitchen with wedge of cheese on a plate]

06:43

why here's our free body diagram for it nothing too complicated here

06:48

but FBD's are showing the forces acting on one single object this is our object

06:54

A basically what's our object B let's think about gravity first gravity is

06:59

acting on our cheese as it always does pulling it towards the centre of the

07:03

earth which means that the cheese and the earth are a third law pair here's

07:07

the diagram for this pair an object always creates gravity so just like [Diagram for third law pair appears]

07:13

Earth is pulling on the cheese the cheese is pulling on the earth too... To put

07:17

this in terms of our equation the downward force on the cheese F sub EC

07:22

equals the negative of the upward force on the earth F sub CE but that doesn't

07:29

explain the pairing of the normal force time to get diagramming again our third [Diagram appears]

07:34

law pairing for the normal force is the chunk of cheddar on the table the table

07:38

is pushing up with F sub TC and the cheese is pushing down F sub CT like we

07:45

just said the types of forces have to be the same in a third law pair since F sub

07:50

TC is the normal force from the chair F sub CT has to be the normal force from

07:56

the cheese yep that's right the downward force in this diagram isn't the force of [Downward force diagram of cheese]

08:01

gravity it's the normal force boy physics can make even a piece of cheese

08:05

sitting on furniture into a complicated situation let's look at another scenario

08:09

here at our dojo our sensei has us chop wood as part of our training it's [Man chopping wood]

08:14

probably just a coincidence that he has a fire pit in his backyard that he uses

08:18

every night what third law pairs are involved in this whole wood chopping

08:22

thing we can start with the most obvious that's the ax hitting the log those two

08:27

things are definitely exerting force on one another we'll call the force from [Man holding ax]

08:31

the ax to the log F sub AL and the force in the other direction from the

08:36

log to the axe F sub L A...but we're not done with the ax just yet

08:42

after all something is making it swing since our friend Darryl here is the one

08:47

making the ax move we'll call the force he exerts on the

08:50

axe F sub DA and the force the ax exerts on Darryl will be F sub AD now we

08:57

could keep going we could pair up the normal force of the stump holding up the

09:02

log and the log pushing down on the stump and we could include gravity [Man with ax and another man holding logs]

09:05

pulling on Darryl and Darryl pulling right back on the earth really we could

09:09

find a dozen different pairs in this scenario but the main action we have

09:13

here is Darryl swinging the ax which then hits the log so we'll stop with our

09:17

two pairs another part of our training our sensei likes us to do is where we're [Martial artists pulling a carriage]

09:21

basically services sled dogs it's meant to build up our core strength and to

09:25

teach us humility it's also meant to just get him around town you know this

09:30

sense they might just be a real jerk in any case what are the forces we have in

09:34

play here well we got students pulling the cart actually though we're not [Students pulling the sensei in a cart]

09:39

pulling directly onto the cart we're pulling on this metal shaft which

09:43

is attached to the cart so the shaft exerts a force on the cart and the cart

09:47

exerts a force on the shaft giving us F sub SC equaling the negative of F sub CS

09:57

when we've got the students exerting a force on the metal shaft and it's

09:59

exerting force right back on us since we're already using S for shafts

10:04

we'll use K for karate students to be consistent with our positive and

10:09

negative vectors since the shaft pulling on the cart was

10:12

a positive in the last equation the students pulling on the middle shaft [Students pulling middle shaft with positive symbol]

10:15

will also be positive here so F sub KS equals F sub SK there's one last thing

10:23

though our feet interacting with the ground to make this motion possible in

10:28

the first place again we could get very specific and detailed if we want to

10:33

going into friction and normal force and gravity but for now we're just going to

10:38

consider this a basic contact force between our feet and the ground we'll

10:42

make it into this formula F sub FG for feet to ground equals the negative of F

10:48

sub GF after chopping wood and pulling our

10:52

master around the last part of our training takes place on the tennis court [Students playing tennis]

10:55

basically our sensei slam tennis balls at us as hard as you can and we use our

11:00

skills to try and dodge them I think it's time for me to find a new dojo

11:04

this guy's a lunatic but we can figure out the physics before we leave our

11:09

sensei has a mass of 60 kilograms the racket is 1 kilo and the tennis ball is [Sensei with a racket and tennis ball]

11:15

0.1 kilograms the tennis ball exerts a force of 130 Newton's on the racket how

11:21

fast does the ball accelerate if we don't worry about gravity...Wait,

11:25

acceleration this is looking like a second law problem but actually it's a [Woman dodges tennis ball]

11:30

bit of both we'll go in numerical order in fact the second law tells us that

11:35

force equals mass times acceleration we know the mass of the ball and we know a

11:41

force but is it the right force yes and no we know the force that the ball

11:47

exerts on the racquet but we need the force the racket exerts on the tennis

11:51

ball ah but with the power of third law magic we can just flip this around F sub

11:59

BR equals negative of F sub RB since we were given our force from ball to racket

12:05

as a positive value the opposite force will be negative so the force the racket

12:10

exerts on the ball is negative 130 Newtons now we can just plug in our [Force equation appears]

12:15

numbers and get the solution negative 130 Newtons equals 0.1 kilograms times

12:21

acceleration divide both sides by 0.1 kilograms to solve for acceleration and

12:26

we get an answer of negative 1,300 meters per second squared

12:31

holy cow sensei what are you doing teaching karate you should be playing at [Sensei strikes tennis ball at student]

12:35

Wimbledon now that acceleration is pretty huge but

12:38

it's only going to last a fraction of a second once the ball is no longer in

12:43

contact with the racket the acceleration ends because there's no more force being

12:47

applied oh and that the negative sign there is just telling us that the

12:51

direction of motion is in the opposite direction of the force the ball exerted

12:55

on the racket so it turns out there's no way to avoid getting pushed around by [Woman martial artists performs a kick]

13:00

six no matter what we do we can't fight it because it'll fight us back just as

13:05

hard and as much as we'd like to kick that crap out of physics sometimes we

13:09

know that it's better to learn physics than to fight it just kidding!

13:13

sneak attack [Woman kicks physics book]

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