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Physics: The Many Forms of Energy 23 Views


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Description:

There are many forms of energy. And not just coal, wind, and solar. We'll cover the types, how energy is converted, and the difference between kinetic and potential energy.

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English Language
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Transcript

00:00

The many forms of and a couple of equations for energy energy can't be

00:37

Energy, pretty important right you might not think too much about energy at least not [Woman appears in room]

00:43

until you eat a big bowl of chili for lunch and an hour later you're nearly [Woman eating chili]

00:47

comatose that's when you realize how much energy it takes just to get through

00:52

the day and that's also when you realize that you should probably start eating [Woman sleeping]

00:56

more salads where did that post lunch energy go did it just dissolve away nope

01:02

in fact that's not possible energy can't be destroyed and it can't be created it

01:07

can move from one place to another but it always has to be conserved like this

01:13

espresso machine it's plugged into the wall drying electrical power and the [Woman points to espresso machine]

01:17

machine converts out electricity into mechanical energy pumping water through

01:21

the machine it also converts electricity into heat even if you want an iced latte

01:26

it always starts off nice and hot and of course espresso machines generates down [Woman making iced latte]

01:31

lots of sounds this home that haunts my dreams at night an energy conversion is

01:37

also how solar panels work they're able to take light from the Sun and make it [Solar panels on a rooftop]

01:42

into electricity and your body is able to take energy from caffeine and turn

01:47

that into an eyelid that just will not stop twitching that's just an [Woman takes sip of coffee]

01:51

occupational hazard in my line of work maybe I can just have another macchiato

01:55

or three and never blink again problem solved there are lots of types of energy

02:00

we've already talked about light heat electricity and sound oh and mechanical [Types of energy appear]

02:04

energy along with kinetic it's easy to mix up mechanical energy and kinetic

02:09

energy they both involve things moving after all kinetic energy is about motion

02:13

in a direction forward or backward left or right up or down

02:17

if it's moving then it's using kinetic energy mechanical energy is the ability

02:22

for something to do work so it combines kinetic energy and potential energy

02:27

there's also gravitational potential energy we also have nuclear energy which [Nuclear power plant appears]

02:32

is really cool and really dangerous a little nuclear energy can go a long way

02:37

an explosion this big can be created with only two pounds of uranium that's a [Explosion occurs]

02:42

huge release of energy but energy can be released on a much smaller scale to ever

02:48

pulled on a rubberband until it broke and snapped your hand [Girl pulls on rubber band]

02:50

ouch pulling on the rubber band creates elastic potential energy and when it's

02:55

released it converts into kinetic energy and maybe a welt on your finger too if

03:00

you have a fridge at home you're probably familiar with magnetic energy [Pictures hanging on fridge]

03:04

maybe mama still has one of your artistic masterpieces up there radiant

03:08

energy is a property of electromagnetic waves including light that's how

03:13

microwaves work you put your lunch in there and zap it the microwaves transfer [Girl places lunch into microwave]

03:18

energy to the water molecules in your food and they get all excited and starts

03:23

spinning around super fast like politicians but don't put them in a

03:26

microwave that's ready to melt the skin off the inside of your mouth delicious [Girl eating lunch]

03:31

energy is measured in joules and since it's always conserved any energy that

03:36

goes into something has to equal the energy that comes out like we see in the

03:41

espresso machine one type of energy can be converted into multiple different

03:45

forms like on a roller coaster at the top of the highest hill all the energy [Woman sitting on a rollercoaster]

03:50

is gravitational potential energy once the roller coaster starts heading down

03:54

the hill picking up speed some of that potential energy gets converted to

03:58

kinetic energy and when the coaster goes up into a loop some of that kinetic [Rollercoaster in a loop]

04:03

energy turns back into potential energy one way we can keep track of all that is

04:08

with a pie chart here's the chart for the coaster at the top all blue because

04:13

it's all potential at the bottom of the hill it's all red and kinetic

04:17

when we're upside down screaming our lungs out the chart is split whoa [Rollercoaster upside down]

04:22

the pie chart isn't meant to be precise but it can help us think about how

04:26

energy is changing in a system conservation of energy also lets us do

04:31

some handy math stuff we know that everything we start with has to equal

04:36

everything we end up with when energy is entirely converted from one form to

04:41

another we can set the equations for each form of energy equal to each other

04:45

say your I don't know bored out of your skull at work or school so you make a [Girl cleaning]

04:51

paperclip spring and you make that spring sprawling all over the place

04:54

because again BORED when you're dealing with a spring you're dealing [Spring jumps into the air]

05:00

with potential energy but the energy for spring potential energy is different

05:04

than the one for gravitational potential energy gravitational potential energy

05:09

equals mass times gravity times height spring potential energy equals one-half

05:14

K times x squared K is the spring constant which represents how stiff or

05:19

stretchy the spring or elastic or whatever actually is in other words it's [Spring elongates]

05:24

the springiness of the spring X is the symbol for the extension or compression

05:29

of the spring which is measured in meters since X is for extension or

05:34

compression we can think of it as displacement or how much you're moving [Spring compresses]

05:38

one end of the spring from its original resting position and when the spring

05:43

releases that potential energy its converted into kinetic energy and it [Girl holding sore eye]

05:47

might also be converted into eye damage physics is risky folks the equation for

05:53

kinetic energy looks like the spring potential energy equation kinetic energy

05:57

equals one-half mass times velocity squared and because all the energy stays

06:02

the same the potential energy prease broening equals the kinetic energy posts

06:06

prong setting these equations equal to each other will come in pretty handy

06:10

when we're trying to find a value for a variable while we're talking about

06:15

elastic potential energy we should also point out how it relates to force in

06:19

fact we get to look at a whole new force equation yes [New force equation appears]

06:22

whoo-hoo sorry I should probably switch to decaf [Girl takes sip of coffee]

06:26

the force applied to a spring equals the spring constant K times X which is the

06:32

extension or a displacement of the spring we might also see this written

06:35

with K as a negative that would just be the force the spring is applying as it [Springe recoils]

06:40

tries to return to its regular state in other words the spring just wants to

06:45

chill out and it starts getting forceful when we mess with it hold on is my [Man pushing spring in to a wall]

06:49

spirit animal of spring whoa after my shifts done I hop on my bike and hope [Girl riding her bike home]

06:54

the fresh air blows some of the coffee stink off me what kind of energy

06:58

transfers happen on my trusty Schwinn and how are they different than the

07:02

energy transfers in a car now bikes are pretty complicated

07:05

you've got your pedals the chain the gears the brakes you might think you [Girl pedalling]

07:10

just get on and start pumping your legs but there's more going on than that but

07:14

we don't need to look at every little transformation of energy in this whole

07:17

contraption we're looking big picture here but your legs are definitely

07:20

involved so let's investigate them first what makes your legs move this is a [Anatomy of legs appear]

07:25

biology class but I'm guessing you know what muscles are what's the source of

07:29

energy that lets your muscles move and get the pedals turning now would be a

07:33

burrito or soup or a hot pocket that's as hot as a surface as a Sun in other

07:37

words food food has chemical energy in the form of calories our bodies use [Foods chemical energy amounts appear]

07:43

those calories to fuel our muscles in a process known as magic

07:48

like I said this is in biology class so we've got chemical energy in our legs

07:52

and we apply that to the pedals the turning of the pedals makes all the

07:56

mechanics of the bike work hey turning that definitely sounds rotational and [Girl pedaling her bike]

08:01

sure enough we've got spinning and turning all over the place on this bike

08:05

as a result of that energy the bike moves forward which now means we've got

08:10

energy number three kinetic the bike moving forward is a classic case of [Girl riding bike down the road]

08:14

kinetic energy and action so really if we think of the bike as one independent

08:19

system mechanical energy is converted to kinetic energy and if we consider the

08:24

rider part of the system our chemical energy is converted to rotational energy

08:29

first now how about this gas go next to me this is in the Flintstone so [Car drives by girl riding bike]

08:34

no muscle power is making the Beast move forward but it still wouldn't be going

08:38

anywhere without chemical energy inside the motor gasoline is being burned which

08:42

is a chemical reaction you can smell in the air but it's not constantly burned [Man with flame torch appears at gas station]

08:46

like a bonfire we don't want to scare you but if you're driving a gas powered

08:51

car there are hundreds of explosions going on under the hood every minute

08:55

yeah riding a bike sounds even better now doesn't it the spark plugs in your

08:59

engine fire off a spark that makes the gasoline explode it's a little tiny

09:04

explosion but still boom that equation is what makes the Pistons on the energy [Engine in motion]

09:09

move and the Pistons get everything in the energy spinning so we've got

09:13

rotational energy all over again and of course the engine is connected to

09:18

the drive shaft and the leg bones connected to the hip bone and the next [Car driving by]

09:21

thing you know we've got kinetic energy to after all a car wouldn't be very

09:24

useful if it didn't move a car also converts chemical energy into heat and

09:30

sound as you know if you've ever said and your car gets hot enough that you [Man driving car down the road]

09:36

can actually cook on it so yeah there's some thermal energy going on this [Chef cooking on car bonnet]

09:41

happens with a bike too but to a much lesser extent try cooking something on

09:45

your bike gears and you're just gonna end up with a cold mess so both systems [Girl riding alongside car]

09:49

the bike and the car convert rotational energy into kinetic energy of course the

09:54

bike riders provide the initial chemical energy which is why a twenty mile bike

09:57

ride is way more tiring than a twenty mile car ride but cars are less [Man takes sip of soda while driving]

10:01

efficient because more of their chemical energy is converted to heat and sound

10:05

which don't actually help the car move that's a win for people power let's look

10:10

at another scenario see we've got a ball that rolls down a ramp and comes to a [Ball rolls down a ramp into a spring]

10:15

rest on a spring what equation represents the energy transfer and what

10:19

would a pie-chart of the total energy look like okay so

10:22

this isn't an everyday situation unless you happen to have a ramp with a spring

10:26

at the bottom lying around but that's fine we can let our imagination lead us [Girl holding ball]

10:30

down this ramp at the start when we're just holding the ball on the ramp all

10:34

the energy involved is gravitational potential energy

10:37

we'll make that yellow on our pie chart and the equation for gravitational

10:42

potential energy is mass times gravity times height

10:45

as the ball rolls down that potential energy gets converted to kinetic energy [Ball rolls down the ramp]

10:50

how about we make kinetic energy a nice lavender on our chart halfway down the

10:56

ramp and our pie chart is split right down the middle at the bottom of the

11:00

ramp all that potential energy has converted to kinetic energy which equals

11:05

one-half mass times velocity squared but when the ball comes to rest on the [Potential energy to kinetic energy equation appears]

11:10

spring there's no more kinetic energy either in the end all the energy is now

11:15

elastic potential energy which calls for let's say aquamarine

11:20

so now our final energy equation shows the elastic potential energy equal to

11:26

1/2 the spring constant times the displacement of the spring squared and

11:31

that equals the gravitational potential energy that we started out with because

11:36

all the energy has to be conserved there are different equations for different [Equations appear for forms of energy]

11:40

forms of energy and we're not going to worry about those right now

11:43

so long as we know that the general principle is the same you get out what

11:48

you put in although I do want to mention the most famous energy equation of them [Einstein writes equation on board]

11:53

all e equals MC squared yep Einstein's little miracle here is definitely in the

11:59

top five best energy equations of all time and it means that we all have a

12:04

huge amount of energy stored in the molecules and atoms that make up the goo

12:08

that is the human body but after that bike ride and the caffeine wearing off [Girl takes seat on couch]

12:12

I'm definitely not feeling like I'm storing any of that energy in me I think

12:16

it's time to recharge the batteries with a nap energy is great to talk about in

12:21

theory but when you have a post espresso crash that hole you can destroy energy [Girl drooling and sleeping on sofa]

12:26

thing feels like a huge lie

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