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Physics: The Second Law of Thermodynamics: Why Making a Mess is Just Part of Physics 8 Views


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Description:

Time to learn about the second law of thermodynamics. But be efficient about it...our narrator has places to go, and places to clean.

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English Language
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Transcript

00:02

The second law of thermodynamics why making a mess is just part of

00:07

physics entropy........[mumbling]

01:11

sure everything is in its place if you spend most of your waking life making [Woman walks around bedroom]

01:17

sure things are organized and properly stored the rest of your life will be so

01:21

much happier ensure you can take this advice too far theoretically but we have

01:26

to do everything we can to fight disorder because the universe is [Girl cleaning bedroom with duster]

01:29

fighting back against us stupid messy universe what does a clean

01:33

bedroom have to do with physics to answer that question let's talk about

01:36

thermodynamics the first law of thermodynamics says that energy can't be

01:41

destroyed or created all the energy in the universe already exists it's not [Man with new energy t-shirt appears]

01:45

going anywhere and no new energy is going to walk through the front door

01:50

the second law of thermodynamics actually has a few different definitions

01:53

or different ways we can understand it have you ever dropped a few ice cubes in [Woman places ice cubes in to glass]

01:57

a glass of soda and then forgotten it on the counter

01:59

I haven't when you come back it's a gross watered-down disaster what

02:03

happened heat transfer habit that's what heat [Woman sad at ice melting]

02:06

moves from the warmer soda into the colder ice cubes making them melt so why

02:11

didn't it work the other way around why didn't we he'd go from the ice cubes

02:15

to the soda sure the ice cubes are super cold but they still have internal energy

02:20

but it would be pretty freaky if you put ice in a soda and the ice somehow got

02:24

Colder yeah it turns out that never happens it's actually impossible it [Woman discussing heat transfer]

02:29

would break the second law of thermodynamics one way to explain the

02:33

second law is to say that heat always flows from a higher temperature system

02:36

to a lower temperature system and it never ever goes the other way around

02:41

that just makes sense it's one of those things that's so obvious you wonder why [Scientist appears in a lab]

02:45

they even had to write it down I'm not judging but it turns out that the second

02:48

law is a little more complicated than that because the second law of

02:51

thermodynamics is really about entropy which is a fancy science word for

02:55

disorder or chaos the best definition of the second law of thermodynamics is as

03:00

follows in all natural processes the total entropy of a system and its [Definition of second law appears]

03:05

surrounding environment either stays the same or increases entropy never

03:10

decreases to put that in normal person speak things always become more

03:15

disorderly if we consider both the system and the environment around it

03:19

let's say it's a wonderful day for fun and we get to spend eight hours [Woman enters messy bedroom]

03:23

organizing the house it doesn't get any better than that does it just a full day [Woman cleaning bedroom]

03:29

of organizing and tidying by the time you're done it's almost as if you can't

03:34

detect any sign of human life at all it's perfect it's wonderful it's what

03:40

was I saying oh right entropy so we just showed that

03:44

there can be less disorder in the universe at least here in our little

03:48

pocket of it right sorry but no, first of all anytime you have that much fun

03:52

you're going to work up a sweat that means heat came off of you and went into [Heat molecules coming off woman's head]

03:56

the air and when you heat molecules up they move around and vibrate and don't

04:00

get all worked up which means they get more chaotic and as you scurry around

04:05

putting things away that also disturbs molecules in the air opening and closing

04:10

dresser drawers putting things on hangers the joyful act of throwing junk [Woman emptying bin]

04:13

away all of that involves friction which means heat which means chaos there is no

04:18

escaping it it's enough to drive you crazy if we don't get crazy because

04:22

crazy is chaos chaos is the enemy keep calm and clean [Woman walking away after emptying trash]

04:26

on another example of this happens when we have a bouncy ball we've all played

04:31

with one of these super balls that bounce like crazy right if you drop a [Man picks up black ball]

04:34

super ball without adding any extra energy to it it'll bounce back up pretty

04:38

high but it won't bounce all the way back up to where it started

04:42

part of that is due to gravity part of that is also due to entropy right before [Boy holding super ball]

04:48

the ball hits the ground it's got a lot of kinetic energy as it hits the ball [Boy drops super ball]

04:52

deforms a little creating elastic potential energy then it snaps back into

04:57

its original shape which is why it bounces back up into the air the ground [Ball bouncing back up into air]

05:02

also deforms a little bit too this deformation makes the molecules all

05:07

jumping so some of the kinetic energy as a ball is transferred into internal

05:11

energy of the ball and the ground internal energy means a higher

05:15

temperature and in fact if you had some thermometer keeping track of the super

05:19

ball you'd see it tick up just a little bit like one or two tenths of a degrees [Boy drops ball]

05:23

maybe the ground temperature would go up a teeny bit too since some of the

05:27

kinetic energy is converted into internal energy the ball loses some [Ball bouncing on the ground]

05:31

oomph on the bounce and you guessed it more chaos is created there's just no way around it

05:37

okay circling back how is entropy related to our first explanation of this

05:42

thermodynamics law remember we said that heat flows from the warmer system to the

05:47

cooler system think of it like this which is more orderly a block of ice or [Bowl of water and ice cubes appear]

05:52

a bowl of water it's the ice without a question molecules and a solid are

05:56

tightly aligned there's no molecular slipping and [Molecules vibrating rapidly]

05:59

sliding like you have in a liquid and in general a colder system has less chaos

06:04

than a warmer one the molecules are moving more slowly they're vibrating

06:08

less their little molecular shoes are neatly stacked up a hot system means [Molecules appear by hot and cold systems]

06:13

chaos galore molecules banging into each other electrons flying around

06:17

willy-nilly shoes never being put away uh-huh it makes me itch just thinking

06:22

about it entropy will always increase or stay the

06:24

same if heat flow out of the cooler system and into a [Ice cube appears in glass of soda]

06:28

warmer system that would mean the colder system would become more orderly that's

06:33

never going to happen another way to think about the second law of [Mustang car appears and girl opens the hood]

06:36

thermodynamics is to pop the hood on your car assuming you don't have an

06:39

all-electric car then your engine has piston which means it depends on heat [Pistons in engine turning]

06:43

which makes it well a heated and an internal combustion engine just like the

06:48

one in this car has Pistons a piston basically hangs out in a hollow cylinder [Piston diagram appears]

06:53

at the top of the cylinder the piston is like a plunger that creates a tight seal

06:57

to keep all the air inside so we've got gas inside the piston just hanging out [Gas molecules inside a piston]

07:02

doing a gas thing when suddenly a heat source appears this makes the molecules

07:07

in the gas get excited and less dense which creates pressure in the piston

07:10

which pushes the piston up which makes the gears of the engine turn which makes

07:14

the wheels turn and what do you know you're driving on the highway and a [Car driving on the highway]

07:18

sensible speed of course five miles under the speed limit is best okay so

07:21

the gas expands great job gas but if this process happens only once that's

07:26

not going to get you very far things have to cool down so the piston can sink

07:29

back down and the whole process can repeat it in a car [Combustion engine appears]

07:32

this happens hundreds of times a minute where does that heat go bingo out of the [Gas appears from out of tail pipe]

07:37

tailpipe any kind of heat engine has to be able to dump heat into what's called

07:41

a reservoir in this case reservoir doesn't need a big lake full of drinking [A giant reservoir appears]

07:46

water it means something big enough to be able to absorb all the heat that the

07:49

engine needs to get rid of in the case of a car that means the heat goes [Car engine starts and gas appears from tail pipe]

07:52

through the tailpipe and out into the atmosphere the atmosphere is big enough

07:56

that heat from a car doesn't have much effect on the overall temperature of

08:00

course when you have a bunch of cars with a bunch of pollution and greenhouse

08:03

gases well that's a topic for another much more depressing video with the [Gas appears from lots of cars on the highway]

08:08

Pistons going up and down we know that force is being applied and things are

08:12

moving which means work is being done but since

08:15

all the heat that's generated is dumped into the exhaust system this process [Piston moving up and down]

08:18

isn't 100% efficient and that brings us up to our third and final way of looking

08:23

at the second law of thermodynamics it's impossible for a heat engine to convert

08:28

heat completely into work without any other

08:31

effect in fact there's a nice and clean equation to go along with this idea the [Efficiency of heat engine equation appears]

08:35

efficiency of a heat engine that's what the epsilon stands for equals the work

08:40

done W divided by the heat that's input that's the Q sub H because heat can't be

08:47

totally converted into work, work will always be less than the heat input and

08:52

efficiency will always be less than one not everything in life is about cars you

08:56

know no matter what your one uncle who's obsessed with hot rods might say here's [Uncle stood beside smart car]

09:00

a basic diagram of how another type of heat engine works we've got a high

09:04

temperature reservoir on the one end that feeds into the engine which

09:07

partially converts the heat to work and it sends the excess heat that wasn't

09:11

converted down the line to the low temperature reservoir let's say this

09:14

engine does five thousand joules of work while producing nine thousand joules of

09:18

heat what's the efficiency of this bad boy we [Woman appears in room discussing heat efficiency]

09:21

just went over the equation for heat engine efficiency but let's make sure we

09:25

know how to actually use it there has to be a difference in temperature from the

09:28

heat source to the cold reservoir otherwise heat wouldn't flow and that

09:32

would leave us with an engine that did a whole lot of nothing

09:35

or maybe something worse than nothing kind of defeats the whole purpose of an

09:38

engine and according to our thermodynamic lawyer the engine doesn't [Lawyer points to second law of thermodynamics]

09:42

convert all of the heat into work so what's left over has to exit the system

09:46

so we've basically got two different kinds of heat here we've got the heat

09:50

that enters the system we call that Q sub H then we've got the heat that

09:54

leaves the system we'll make that Q sub L so what do we know in this situation [Woman discussing two different heats]

09:58

for one thing we know that the heat engine produces 9,000 joules of heat is

10:03

that the heat coming into the engine or leaving the engine that would be our new [Woman appears in room with a vacuum]

10:07

friend Q sub L since the engine is producing it and not taking it in this

10:12

9,000 joules is what the engine is dumping into the reservoir and then

10:16

we've got our five thousand joules of work of course our efficiency equation [Efficiency equation appears]

10:20

tells us that a heat engines efficiency equals the work produced over the heat

10:24

entering the engine we still don't know how much heat is coming in but it's not

10:29

too tricky to figure out after all we know that an engine is going to produce

10:32

two things work that's been converted from heat and heat not converted to work

10:36

so if we add these together we've got our starting heat which means that we can

10:41

rewrite our efficiency equation by swapping at the heat coming into the

10:45

engine for the heat leaving the engine plus the work done now we just have to [Equation appears with numbers]

10:49

pop in our numbers and we're all good five thousand joules divided by fourteen

10:53

thousand joules gives us an efficiency of thirty five point seven percent which

10:57

isn't great I certainly hold myself to a higher [Woman walks up to car with the hood popped]

11:00

standard than that but that's the way it goes with heat engines they're just not

11:04

that great with the whole efficiency thing now let's say we've got an engine

11:08

that takes in sixty four thousand five hundred joules of heat and gives up [Steam engine going by the road]

11:12

fifty three thousand nine hundred joules in exhaust

11:14

what's our efficiency here hmm our equation uses work and the heat input to

11:18

figure this out but we don't have work here that's okay though we can tackle

11:22

this in two different ways first we can find the work by subtracting the heat [Vehicle driving slowly down the road]

11:26

leaving from the heat entering that tells us how much heat was converted

11:30

into work in this case that comes to ten thousand six hundred joules divided that

11:35

by good old Q sub H and we've got an efficiency of 16.4% I mean impressive

11:42

the other way to figure this out is to start with one if an engine was 100

11:47

percent efficient the work would equal the heat coming in so this ratio would

11:51

equal one from that we can subtract the result of the heat leaving the system

11:54

divided by the heat coming in so one minus fifty two thousand nine hundred

11:58

joules over sixty four thousand five hundred joules gives us sixteen point

12:02

four percent efficiency see like the old saying goes there is more than one way [Woman uses flamethrower on stove]

12:06

to clean a stove and of course we always need to remember

12:09

that as a result of all this inefficiency and heat dumping more [Molecules coming out of tail pipe]

12:13

entropy is introduced into the universe there's no getting away from that which

12:17

is why I hate this stupid second law why can't we just make things more orderly

12:22

wouldn't that make the universe a better place no one actually likes chaos do they? [Woman cleaning room]

12:26

everything moving around going crazy no one important many rules people just

12:31

doing whatever they want leaving whatever they want not caring

12:34

about anything joggers in the street there are toilets to be [Woman walks into toilets]

12:38

cleaned young man sometimes I swear I'm the only one who cares about order in

12:42

the universe

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