Physics for Future Presidents: Lec 01- Atoms and Heat
Summary
TLDRThe video covers the fundamentals of kinetic energy, illustrating its concepts with examples like meteors and everyday physics. It explains how kinetic energy, or the energy of motion, influences various phenomena—such as the explosive entry of a meteor into Earth's atmosphere, where its high kinetic energy is transformed into heat through interaction with air, causing it to explode. The presentation touches upon the relationship of kinetic energy to potential and food energy, illustrating conservation of energy with practical examples. It discusses the physics behind sound speed, energy conversion in re-entering spacecraft, and the understanding of temperature in terms of particles' kinetic energy. Shows like thunder-related sound delay and air pressure effects are explored, offering insights into heat and energy transfer processes and their implications in natural and technological contexts.
Takeaways
- 🌠 A meteor's high-speed entry into Earth can cause explosive release of energy.
- ⚛️ Kinetic energy is intrinsic to any moving object.
- 🔊 Speed of sound is about 330 meters per second in air.
- 🔥 Heating increases particle motion, affecting states of matter.
- 💫 Zero-velocity at absolute zero; molecules stop moving.
- 🚀 Space Shuttle uses tiles to manage reentry heat.
- 🍎 Energy is transferable among different forms like potential and kinetic.
- 🌡️ Temperature correlates with kinetic energy of particles.
- 🔌 Electron motion contributes to background noise in electronic devices.
- 🌡️ Room temperature is approximately 300 Kelvin.
- 💨 Air pressure and motion create convection currents.
- 🔭 Quantum effects prohibit temperature from dropping below absolute zero.
Timeline
- 00:00:00 - 00:05:00
The video opens with a clip of a car advertisement depicting a meteor shower, illustrating the immense energy of meteors. The narrator explains that the meteor in the ad is fictional and is used to demonstrate the car's durability. The narrator uses this ad to explain kinetic energy and its effects, particularly in the context of meteors hitting the Earth, emphasizing the energy contained in moving objects compared to equivalent masses of TNT.
- 00:05:00 - 00:10:00
The narrator describes the process of calculating kinetic energy using a mathematical formula, highlighting the average speed of meteors entering Earth's atmosphere. They explain this speed in relatable terms, such as how quickly a meteor could travel from San Francisco to another city. The narrative briefly transitions to making announcements about course logistics, like GSI changes and procedural advice for changing sections or submitting homework, aiming to manage classroom administrative tasks efficiently.
- 00:10:00 - 00:15:00
The video transitions back to scientific discussions, comparing kinetic energy principles to everyday scenarios like driving, indicating how a vehicle's speed exponentially increases energy during crashes. The concept is reinforced with mathematical equations and physical demonstrations. The speaker suggests caution in travels citing the dangers associated with kinetic energy increase with speed, explaining that energy is passed to objects or people during a crash.
- 00:15:00 - 00:20:00
A discussion is presented on the speed of sound, using relatable analogies such as counting the seconds between lightning and thunder to measure distance, demonstrating ancient methods of understanding sound speed. There's a theatrical touch to explaining how movies inaccurately depict sound speeds, contrasting with reality where delays exist between visual and auditory phenomena. Illustratively, various examples, from sporting events to ship battles, emphasize how perception is altered by sound travel.
- 00:20:00 - 00:25:00
The speaker conducts a demonstration showcasing conservation of energy using a pendulum, hinting at Newton's laws without explicitly mentioning them. They underscore the equivalence of gravitational potential energy conversion to kinetic energy as the pendulum swings, reinforcing that despite energy loss to air resistance, the system regains height. The demonstration implies energy remains in a closed system, though external factors like air resistance make it less apparent.
- 00:25:00 - 00:30:00
Heat and temperature concepts are touched upon, noting how different materials feel different to the touch due to their heat conduction properties rather than differing temperatures. The foundational zeroth law of thermodynamics is introduced, hinting at equilibrium states. Historical struggles to understand temperature are briefly alluded, showcasing the eventual comprehension of hidden kinetic energy as temperature, laying a groundwork for understanding thermodynamics.
- 00:30:00 - 00:35:00
Through a simple demonstration, the speaker conveys that atoms and molecules exhibit kinetic energy in random motion, classifying this energy as heat. They explain that temperature is merely a measure of this hidden kinetic energy. The video provides historical context, capturing the late scientific realization of this concept in the early 20th century. This understanding redefined temperature as a state of kinetic energy among molecules.
- 00:35:00 - 00:40:00
The lecture continues into atomic theory, explaining the basic structure of atoms, using hydrogen as a primary example. Atoms are shown as consisting of protons, neutrons, and electrons, with an emphasis on their relative sizes and masses. The video delves into how atoms combine to form molecules, introducing elements on the periodic table. The discussion includes molecular mass's effect on speed, using examples from terrestrial to cosmic scales to explain atmospheric compositions.
- 00:40:00 - 00:45:00
The explanation expands to demonstrate how kinetic energy is shared but not velocity in a gas, leading to temperature equality regardless of molecular mass, delineating why light gases like hydrogen escape into space when they achieve escape velocity. Various illustrative examples highlight how different planetary bodies retain gases due to their gravity, with additional references to helium's presence on Earth through radioactive decay processes.
- 00:45:00 - 00:50:00
The lecturer explains absolute temperature, introducing Kelvin and Celsius scales, emphasizing zero Kelvin as the theoretical stop point of all molecular motion. There's mention about converting temperatures between scales and the quirks of Fahrenheit based on historical contexts. The teacher emphasizes the usability of these scales in scientific equations but also acknowledges practical everyday knowledge of temperature trends essential for students' grasp.
- 00:50:00 - 00:55:00
Demonstrations of temperature and pressure relationships are conducted through visual experiments, like the behavior of balloons in cold and hot environments. The video illustrates liquid nitrogen properties to reinforce points about molecular movement and heat transfer. There’s a blend of practical experiments and theoretical explanations to engage students in understanding the physical properties of gases when subjected to heat changes.
- 00:55:00 - 01:00:00
The relationship between kinetic energy and temperature is reiterated with practical insights into how these principles apply to real-world phenomena, like how the space shuttle manages re-entry heat. They explain using concepts like escape velocity and energy transfer with terrestrial analogies, merging scientific methodology with real-world applications, safeguarding misconceptions about kinetic energy's role in technological achievements.
- 01:00:00 - 01:05:00
Expanding on conservation principles, the video explores thermodynamic processes influencing energy transfer in fluids, invoking concepts of convection currents, often naturally observed in atmospheric and oceanic circulations. The lecturer connects these scientific principles with everyday phenomena such as air currents created by heaters or natural wind patterns, representing a fundamental overview of thermodynamic applications.
- 01:05:00 - 01:14:00
The session concludes with an exploration into sound wave propagation, emphasizing molecular motion's role in sound transmission and the unique behavior of sound in different mediums. The session provides tangible examples to help students visualize how energy and matter interact in scientific contexts. Closing with a reflection on historical scientific discoveries, the speaker aims to inspire further inquiry into the dynamic behaviors of matter and energy.
Mind Map
Video Q&A
What is kinetic energy?
Kinetic energy is the energy of motion, meaning energy that an object possesses due to its movement.
How does kinetic energy relate to meteors?
A meteor entering Earth's atmosphere has tremendous kinetic energy due to its high velocity, which can cause it to explode.
Why does a meteor explode upon entering Earth’s atmosphere?
It explodes because of its high kinetic energy gaining heat due to its high velocity and interacting with the atmosphere.
What is the speed of sound in air?
The speed of sound in air is approximately 330 meters per second or about 1,000 feet per second.
What causes the noise in radios when no signal is detected?
The noise is caused by the random motion of electrons, known as thermal noise or Johnson–Nyquist noise.
Why is the zero law of thermodynamics important?
The zeroth law of thermodynamics states that systems in thermal contact reach the same temperature, explaining thermal equilibrium.
Why doesn't Earth retain hydrogen in its atmosphere?
Hydrogen escapes into space due to its high velocity at given energy, exceeding Earth’s escape velocity.
How does the space shuttle survive re-entry temperatures?
The shuttle uses heat-resistant tiles that reduce heat conduction into the craft, dissipating energy into the atmosphere.
What is absolute zero?
Absolute zero is the theoretical temperature at which the motion of particles and kinetic energy become minimal.
What role does temperature play in the kinetic theory?
Temperature is a measure of the average kinetic energy of particles in a substance.
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- 00:00:11maybe you've seen this if you watch
- 00:00:13football you've probably seen it you
- 00:00:15don't watch football you probably
- 00:00:16haven't I like this
- 00:00:20view okay let's go to uh let's stop
- 00:00:26this okay let me go to
- 00:00:33view um full screen is what I'd
- 00:00:38like
- 00:00:40okay let's
- 00:00:45see let's go back
- 00:00:48here let's see how this
- 00:00:51plays a say Jeep which a car going
- 00:00:56through what's that in the sky look at
- 00:00:57that whoa
- 00:01:06gives you some idea what a meteor is
- 00:01:07like um that
- 00:01:10meteor by the way the movie is not
- 00:01:14real It's actually an ad for
- 00:01:17Toyota it's their their car is meteor
- 00:01:20proof right and what I like about it is
- 00:01:23it gives you some sense this meteor is
- 00:01:25probably no bigger than
- 00:01:33this meteor
- 00:01:35whoops shouldn't put the meteor in the
- 00:01:37same pocket as my
- 00:01:39iPod okay here's a little meteor this
- 00:01:42meteor is probably about the same
- 00:01:44size okay but imagine this thing except
- 00:01:48made out of
- 00:01:50TNT now a meteor coming in at full speed
- 00:01:53un not slow down by the atmosphere
- 00:01:55will'll have something like 100 150
- 00:01:58times as much energy as if this were
- 00:02:00made out of
- 00:02:04TNT okay so imagine explosive like this
- 00:02:08and what it would do now this meteor
- 00:02:10would have a lot more energy than that
- 00:02:11so maybe the meteor was smaller than
- 00:02:13this but let's watch it again coming in
- 00:02:15it's just sort of a neat movie
- 00:02:18view uh full
- 00:02:21screen there it come there's the truck
- 00:02:24this is the ad for the truck ad for that
- 00:02:26truck anyway what's that coming in oh
- 00:02:28look at that
- 00:02:30woo okay so why did it explode explode
- 00:02:34because it had so much kinetic energy
- 00:02:35energy of motion what is kinetic energy
- 00:02:38well energy is energy but but sometimes
- 00:02:40you compress a spring and it has that
- 00:02:43energy in it energy of the
- 00:02:47force force between the
- 00:02:50particles um that energy can be released
- 00:02:54from the spring I get energy when I eat
- 00:02:57food sometimes it's called food energy
- 00:02:59you know they give different names to it
- 00:03:00food energy kinetic energy potential
- 00:03:02energy those names it's all energy it's
- 00:03:05all in calories or if you li Jewels
- 00:03:08there 4,200 Jew per calorie a jewel is a
- 00:03:10scientific unit but energy is energy and
- 00:03:14if I wish to jump up I take some of the
- 00:03:17k i i put there's energy in my muscles
- 00:03:20then I release it and it comes kinetic
- 00:03:22energy now the kinetic energy goes to
- 00:03:25stretch the spring between me and the
- 00:03:27Earth we call that the gravitational
- 00:03:29basically
- 00:03:30the gravitational binding of me to the
- 00:03:33Earth that's energy if I lift this up it
- 00:03:37takes energy to lift it up why because
- 00:03:41the Earth is trying to pull it down the
- 00:03:43modern way of looking at this is that in
- 00:03:46between the Earth and the meteor there
- 00:03:48is a spring you can't see it you can't
- 00:03:51feel it the spring actually according to
- 00:03:53to Quantum Theory consists of a large
- 00:03:55number of particles zipping back and
- 00:03:57forth here so it's it's like a rubber
- 00:03:59band these particles are called
- 00:04:02gravitons and we'll be talking more
- 00:04:03about Quantum Theory as the entire
- 00:04:06semester goes but in understanding the
- 00:04:08gravitational energy just think that
- 00:04:11you're stretching that band of
- 00:04:13gravitons and it's trying to pull it
- 00:04:15back and I won't do it quite so high it
- 00:04:18does when it pulls it back the energy
- 00:04:21that was in those gravitons goes into
- 00:04:23speeding this thing up giving it kinetic
- 00:04:27energy uh the kinetic energy is also
- 00:04:31measured in calories or in Jewels if you
- 00:04:33if you use the physics
- 00:04:35formula you say the energy is equal to
- 00:04:3812 mv^ 2 and you measure this in
- 00:04:41kilograms a kilogram is about 2
- 00:04:45lbs okay and you measure the Velocity in
- 00:04:47meters per
- 00:04:48second so there's a meter you know and
- 00:04:51there's a second so if you go one meter
- 00:04:52in 1 second that's how faster going you
- 00:04:54don't I'm not going to ask you to ever
- 00:04:55plug into this equation that's not what
- 00:04:57this class is about but some of you want
- 00:05:00to go want want to do a little bit more
- 00:05:02than what this class is about and so I'm
- 00:05:04I'm giving you this range of things but
- 00:05:05I'll tell you when it's not required so
- 00:05:08you plug into this equation and you put
- 00:05:09in a meteor put in a you know a meteor
- 00:05:11this a kilogram meteor I don't know half
- 00:05:13a kilogram something like that and you
- 00:05:15have it going at at the typical speed
- 00:05:19now what's the typical speed for a
- 00:05:20meteor it's about
- 00:05:2230,000 about 30 kilm per second 30 kilom
- 00:05:26per second that seems awfully fast a
- 00:05:28kilometer that's that's that's less than
- 00:05:31a mile so it's about 20 miles per second
- 00:05:3620 mil per second that's like San
- 00:05:38Francisco to here in about two-thirds of
- 00:05:39a
- 00:05:41second that's pretty fast that's how
- 00:05:43fast this meteor was coming in I don't
- 00:05:45know if they did it right but you know
- 00:05:48this gives this what I like about this
- 00:05:49movie is it really gives you the
- 00:05:50impression that thing's coming in fast
- 00:05:53which it
- 00:05:54is by the way I showed that I was in the
- 00:05:57midst of trying to make some
- 00:05:59announcements here
- 00:06:00and I decided to jump ahead so now let
- 00:06:02me make my announcements by unplugging
- 00:06:06this and
- 00:06:08seeing if I
- 00:06:10can plug into here this is a very modern
- 00:06:14setup we have here but they still didn't
- 00:06:16anticipate the fact that
- 00:06:19someday we might actually
- 00:06:23use personal computers to supplement the
- 00:06:27class is that going in there
- 00:06:30little side on the downside no that's a
- 00:06:32male male I guess I have to plug it
- 00:06:36in um you just just turn it on okay this
- 00:06:41here main M and that toggles it between
- 00:06:44the computer oh excellent so they did
- 00:06:46anticipate it so I was wrong so there
- 00:06:48there so there have been two GSI changes
- 00:06:51this has to do with the fact that some
- 00:06:53sections are Fuller than others so the
- 00:06:55Monday section that you went to
- 00:06:57yesterday that was taught by Jenny is
- 00:06:58now taught by Paul and the one 109 that
- 00:07:01was taught by Paul is taught by
- 00:07:04Jenny
- 00:07:06um the one that Jenny is teaching is in
- 00:07:09Valley live Sciences building some of
- 00:07:11you will find that more convenient and
- 00:07:12some of you may just want to stick with
- 00:07:13Jenny because you just thought she was
- 00:07:16great Paul's switching too if you wish
- 00:07:19to switch sections let me tell you how
- 00:07:21we're going to do
- 00:07:22it t bears as you know is virtually
- 00:07:25impossible to get anything done so let's
- 00:07:28ignore tar
- 00:07:31the section you're in is really the GSI
- 00:07:34you're associated with so if you want to
- 00:07:36switch sections send an email to sha our
- 00:07:40head GSI you all got email saying this
- 00:07:43send an email to Shawn our head GSI
- 00:07:46saying what section you'd like to leave
- 00:07:48what section you'd like to go to he's
- 00:07:50going to collect these so he's going to
- 00:07:52be the market place and then he's going
- 00:07:54to try to make adjustments so you get
- 00:07:56into the section you want me happen
- 00:07:59right
- 00:08:01away so if you want to make a change but
- 00:08:04right now these are your sections send
- 00:08:05your homework tonight to the right GSI
- 00:08:07by the way uh many of you have not quite
- 00:08:09figured out this procedure of putting in
- 00:08:12the right
- 00:08:13header you may not know what a header
- 00:08:16is okay sometimes it's called the
- 00:08:18subject of the GSI what we do with 450
- 00:08:22students and not enough gsis what we do
- 00:08:24is we have automatic sorting of the mail
- 00:08:27so you go to the website and you the
- 00:08:29right subject the sub if you're doing
- 00:08:31homework it it has a certain certain
- 00:08:33layout that we want in fact what we want
- 00:08:35you to have is your last name your first
- 00:08:37name the date homework is due and send
- 00:08:40that to your
- 00:08:41GSI if you if you have to miss lecture
- 00:08:44and you're afraid you might miss a quiz
- 00:08:46then send email to me but please use the
- 00:08:49right header it's a different header
- 00:08:50than
- 00:08:51this okay so look on the website and try
- 00:08:53to get those things straight because
- 00:08:54it's the only way we under stats as we
- 00:08:56are thanks to the explosive growth of
- 00:08:58this class uh can uh can can handle all
- 00:09:01this so we're talking about kinetic
- 00:09:03energy and I want you to think of K of
- 00:09:05energy is
- 00:09:07energy
- 00:09:09um this V squared means if you're going
- 00:09:13twice as fast in your automobile you
- 00:09:15have four times the
- 00:09:18energy you go 50 m hour instead of 25
- 00:09:22you have four times the energy that
- 00:09:26means when you crash that energy all has
- 00:09:28to go into ripping apart bones and flesh
- 00:09:31and crushing automobiles four times the
- 00:09:33energy that you have to get rid of
- 00:09:35because you're no longer moving where
- 00:09:36does it go it goes into you know nice
- 00:09:41things like crushing bones so think of
- 00:09:43that as you drive faster it's four times
- 00:09:45the energy that's the V squ it's
- 00:09:47supposed to go really fast supposed to
- 00:09:49go 100 times faster then it's 100 times
- 00:09:53100 that's 10,000 times the energy now
- 00:09:56we're getting really really big
- 00:10:01um suppose you're going the speed of
- 00:10:06sound the of sound is well what is it
- 00:10:10it's
- 00:10:11about maybe when you were kids and you
- 00:10:14afraid of
- 00:10:15thunder and
- 00:10:17lightning your parents said to you oh
- 00:10:21Thunder that's just a noise and the
- 00:10:23lightning you want to know how far away
- 00:10:24that is just count
- 00:10:26seconds go a th1 you see the flash of
- 00:10:29lightning it turns out the flash of
- 00:10:31lightning took some time to get to you
- 00:10:33you'll see the answer is it takes
- 00:10:35several millionths of a second so that's
- 00:10:38you don't notice
- 00:10:39that okay then comes the sound the sound
- 00:10:43goes slowly if you've ever been to a
- 00:10:45ballpark and you watch the batter and he
- 00:10:47swings the batter and he hits the ball
- 00:10:49and the ball goes flying and then you
- 00:10:51hear
- 00:10:52crack CU it took a while for the sound
- 00:10:54to get to you you measure that time
- 00:10:57delay from when you saw it hit you can
- 00:10:59measure the speed of sound speed of
- 00:11:01sound is one of the favorite things
- 00:11:02ancient scientists love to measure it
- 00:11:05was you know it's slow enough the number
- 00:11:07that I was taught by my parents is that
- 00:11:10uh for every 5
- 00:11:12Seconds the lightning was a mile
- 00:11:16away okay so I still do this I mean I
- 00:11:19see a flash of lightning and I I
- 00:11:21automatically start going th1 th2 13 1,4
- 00:11:261,5 boom
- 00:11:29okay so it was a mile away you know you
- 00:11:32see the flash boom you know it was right
- 00:11:34on top of
- 00:11:35you
- 00:11:38um so a mile per 5 seconds I want you to
- 00:11:41know that number many of you knew it
- 00:11:44already because you had parents who
- 00:11:45taught it to you when you were three you
- 00:11:48didn't know what a mile was but when
- 00:11:49you're three a mile seems like forever
- 00:11:52these days many of you run a mile and
- 00:11:55some of you in under four minutes so
- 00:11:56it's not such a big thing but anyway
- 00:11:59mile for a little kid is really big so
- 00:12:01velocity of sound is one
- 00:12:05mile per 5 Seconds now mile is about
- 00:12:085,000 ft 5,280 so it's about 1,000 ft
- 00:12:11per
- 00:12:15second okay a football field well this
- 00:12:18is 330
- 00:12:19m per second that's how fast sound
- 00:12:24goes um that's like three football
- 00:12:28fields in one second that's why if you
- 00:12:30if you see the baseball bat swing it it
- 00:12:32hasn't it it's only about a third of a
- 00:12:34second if your one football field away
- 00:12:37uh that you will hear the sound delayed
- 00:12:38it's really noticeable another place you
- 00:12:39might do it is you're out you're
- 00:12:41watching someone chop wood out in the
- 00:12:42woods and you see the axe come down
- 00:12:45ch ch the one place where this is
- 00:12:49completely violated of course is in the
- 00:12:54movies and to me movies would be so much
- 00:12:57more realistic if they put in this delay
- 00:13:00in movies the lightning and thunder
- 00:13:01always occur at the same
- 00:13:04time that you know it's it makes it
- 00:13:07loses some sense of reality in me
- 00:13:09because I'm so used to the thunder
- 00:13:11coming late you see a Flash and then you
- 00:13:12have this period of anxiety how soon as
- 00:13:14it coming not too soon please you know
- 00:13:17um or or you see a battle scene and
- 00:13:20there off in the distance are the ships
- 00:13:23going boom as they fire their cannons
- 00:13:26you hear the boom right away
- 00:13:29reality it's not that
- 00:13:31way uh now we talked about gravity and
- 00:13:34different kinds of GRA this is a demo
- 00:13:35that always makes me a little bit
- 00:13:37nervous
- 00:13:40uh not quite sure in fact was supposed
- 00:13:43to give me some instructions on how to
- 00:13:44set this up and we
- 00:13:49left
- 00:13:52uh doesn't even seem to
- 00:13:56fit the idea here
- 00:14:01is is I'm supposed to when I release
- 00:14:05this ball what happens is it's a little
- 00:14:07bit further from the earth so as I
- 00:14:08release it it's getting closer to the
- 00:14:13Earth anyway watch me directly it's more
- 00:14:16fun it gets closer to the Earth so it's
- 00:14:19the gravitons are compressing it's
- 00:14:21picking up kinetic energy interesting
- 00:14:23thing at the bottom of its swing it's
- 00:14:25moving exactly the same speed that it
- 00:14:27would fall that it would if it fell
- 00:14:29that
- 00:14:30far you see because the energy is going
- 00:14:33from gravitational sometimes it's called
- 00:14:35potential energy these are just names
- 00:14:36it's going from the gravitation of the
- 00:14:38gravitons if it fills straight down
- 00:14:40would pick up exactly the same speed
- 00:14:42except the speed is it's going that way
- 00:14:44and not that way then as it swings over
- 00:14:46to the other side if it doesn't hit
- 00:14:48anything it will lose its kinetic energy
- 00:14:53it's Mo motion energy it'll slow down
- 00:14:55and over here it should come to exactly
- 00:14:57the same height
- 00:14:59that's that's one example of
- 00:15:01conservation of energy and then as it
- 00:15:05slows down now the gravity accelerates
- 00:15:07it back and it comes down pick should
- 00:15:09pick about the same speed when it's here
- 00:15:11then it should come back to the same
- 00:15:13place now there's some energy being lost
- 00:15:15because it's pushing air out of the way
- 00:15:17but just imagine the weight of the air
- 00:15:19compared to the weight of this this has
- 00:15:20so much energy that even though it loses
- 00:15:22a little bit of energy if were feather
- 00:15:24wouldn't make it across the room so the
- 00:15:26feather weighs not much more than the
- 00:15:28air but this thing because it weighs
- 00:15:32more so it should come back and just to
- 00:15:36the same place we'll see I'm supposed to
- 00:15:39stand here and if I'm really sure of
- 00:15:42myself that this thing sort of settle
- 00:15:44down it goes like that and it should
- 00:15:48comes right back this bar will protect
- 00:15:49me
- 00:15:52right that's not much of a swing next
- 00:15:55time we'll have to do it from a ladder
- 00:15:56is not very impressive
- 00:16:00I can't see it now bars in the
- 00:16:03way whoa okay anyway conservation of
- 00:16:07energy whoa It's a bowling ball you tell
- 00:16:11that has some holes in
- 00:16:13it
- 00:16:17okay
- 00:16:20uh
- 00:16:22so homework tonight talk to sha email
- 00:16:25Sean we're setting up office hours for
- 00:16:27the gsis
- 00:16:29uh we're talking about speeds and the
- 00:16:31speed of sound is 330 m/s now this is
- 00:16:34the amount of
- 00:16:35energy okay now we can calculate the
- 00:16:38number of jewels when something's moving
- 00:16:39we can compare that to
- 00:16:41Dynamite and on this old chart that we
- 00:16:44were looking at I've done
- 00:16:49that here we
- 00:16:51have here we have uh an asteroid or
- 00:16:54meteor moving at 30 km/s has 165 times
- 00:16:58as much energy is the same weight of
- 00:17:00TNT and about 15 times more energy than
- 00:17:03an equal amount of
- 00:17:06gasoline now what happens when the
- 00:17:09energy is lost and here we have
- 00:17:13energy where did it
- 00:17:16go turns out that where it went is this
- 00:17:19thing in the table got a little bit
- 00:17:21hotter just a tiny little bit what do I
- 00:17:25mean by hotter
- 00:17:28hotter and what it means is actually one
- 00:17:31of the oldest mysteries of physics that
- 00:17:34was finally solved and really
- 00:17:37understood in the late 1800s early 1900s
- 00:17:40in fact Einstein played a major role in
- 00:17:43the understanding of what it means to be
- 00:17:46hotter if you think about it it's really
- 00:17:48mysterious we think about what is
- 00:17:50temperature we all know what temperature
- 00:17:52is right or at least we think we do but
- 00:17:55but what is it really what does it mean
- 00:17:57when you're hot or cold well you're hot
- 00:18:00uh try to turn that into a physical into
- 00:18:03physical sense people struggled with
- 00:18:05that when you're hot do you have
- 00:18:07something more in
- 00:18:09you it turns out the answer is yes the
- 00:18:12answer is what you have in you is more
- 00:18:16energy heat it turns out is energy well
- 00:18:19what kind of energy it's kinetic energy
- 00:18:21it's moving energy that's what heat is
- 00:18:23it's moving
- 00:18:24energy let let me give a a demonstration
- 00:18:31um let's see can you lower that screen
- 00:18:33down here just enough to see
- 00:18:36this does that screen come down I forgot
- 00:18:38I lower this one
- 00:18:40myself
- 00:18:47okay think of these things as atoms now
- 00:18:50what is an atom an atom is well there
- 00:18:54are approximately 92 different atoms the
- 00:18:57reason I say approximately is that some
- 00:18:59of the atoms that are listed up there
- 00:19:02basically don't exist unless you make
- 00:19:04them uh they're naturally radioactive if
- 00:19:07you if I can find my pointer hidden in
- 00:19:10my secret pocket deep in
- 00:19:13my hidden cargo
- 00:19:16pants you see technici it's in funny
- 00:19:20letters it's because you really don't
- 00:19:21find it in
- 00:19:23nature uh it's radioactive and it's all
- 00:19:26disappeared so when I say they're about
- 00:19:2892 elements uh there's actually
- 00:19:31plutonium which is uh it all fits into
- 00:19:35this one square called the actinides are
- 00:19:36all these elements there and that's
- 00:19:40plutonium and you think you don't find
- 00:19:41it in nature but it turns out you do
- 00:19:43find it in nature because there's a
- 00:19:44little bit made from from from natural
- 00:19:48processes it's very very small amounts
- 00:19:51so there are approximately 92 of these
- 00:19:52things each one consists of a
- 00:19:56nucleus and electrons going around that
- 00:19:59nucleus
- 00:20:02so for example a hydrogen atom has a
- 00:20:06heavy particle called a proton and a
- 00:20:08light particle called an electron that's
- 00:20:10in orbit around it just which kind of
- 00:20:12orbit is something that we didn't
- 00:20:14understand until
- 00:20:16oh
- 00:20:181925 or
- 00:20:20so uh just how that electron orbits and
- 00:20:23that's really the subject of quantum
- 00:20:24mechanics but most of the weight more
- 00:20:26than 99.9% of the weight is in this
- 00:20:29proton the electron takes up most of the
- 00:20:31space so this thing here is typically
- 00:20:34several angstroms in size
- 00:20:39angstrom I'm not even asking you to know
- 00:20:41the word angstrom it's about 10 the
- 00:20:44minus 10th M and this atom may be 2 or 3
- 00:20:47* 10us 10th Metter in size that seems
- 00:20:50pretty
- 00:20:52small if you look at a
- 00:20:56microscope you can magnify things but in
- 00:20:58ordinary microscope can't let you see an
- 00:21:00atom atoms are too small a microscope
- 00:21:02the smallest thing you can see and this
- 00:21:04I do want you to know the smallest thing
- 00:21:06you can see is called one
- 00:21:10micron you can see why it's called a
- 00:21:13microscope micro meaning small one
- 00:21:17micron one micron is a millionth of a
- 00:21:19meter 10- 6
- 00:21:22meters millionth of a meter sounds
- 00:21:24pretty small except a red blood cell
- 00:21:27you've seen pictures of red blood cells
- 00:21:28many of you have seen them under a
- 00:21:29microscope that's about eight
- 00:21:33microns so little bacteria some of them
- 00:21:37are less than a micron some are larger
- 00:21:38than a micron a micron is getting down
- 00:21:40to a realm which is really interesting
- 00:21:42in biology these days you look at a
- 00:21:44micron you look at the nucleus of a cell
- 00:21:46you look at things that are going down
- 00:21:48inside of the cell and you find there
- 00:21:50are structures on the size of a micron
- 00:21:52but to understand the molecular
- 00:21:55structure you have to get down to the
- 00:21:57atoms and you can see there are about
- 00:21:59about 10 - 6 versus 10us 10 so that's 10
- 00:22:034 that's 10,000 times smaller so think
- 00:22:06of a red blood cell and there only
- 00:22:0810,000 atoms across it seems like a lot
- 00:22:12I think 10,000 isn't that big a
- 00:22:14number I mean a
- 00:22:17centimeter 100
- 00:22:19cm is a is is a is 100 c i mean a meter
- 00:22:23is 100 cm 100 m is 10 4 cenm
- 00:22:29so 10 4th isn't that big a number it's
- 00:22:31number of centimeters in a football
- 00:22:32field yeah it's a big number but hey you
- 00:22:35know you could you could actually
- 00:22:36imagine counting them when you were a
- 00:22:38kid you might have wanted to count up to
- 00:22:39a thousand some kids count up to 10,000
- 00:22:41you could do
- 00:22:42it um so when we're talking about a red
- 00:22:46blood
- 00:22:48cell or something a little bit small
- 00:22:51we're talking about that many things
- 00:22:53across it so it's not really tiny
- 00:22:55infantes it's just too small to see with
- 00:22:57a light microscope we can see atoms with
- 00:22:59more advanced kinds of microscopes which
- 00:23:01we'll be talking about in this course
- 00:23:03electron microscope you can actually see
- 00:23:05individual atoms so that's what the
- 00:23:07atoms are when the atoms combine
- 00:23:08together they form molecules so water
- 00:23:11for
- 00:23:11example it's called H2O consists of two
- 00:23:15atoms of hydrogen and one atom of oxygen
- 00:23:19oxygen is up there in the upper right
- 00:23:20it's colored red on this plot and I
- 00:23:23misplaced my laser
- 00:23:25again so I can't point to it
- 00:23:30ah there comes my liquid
- 00:23:33nitrogen okay uh somewhere here I have
- 00:23:36my
- 00:23:38laser I will find
- 00:23:40it now I want you to imagine that these
- 00:23:44little balls here that we're using some
- 00:23:46sort of advanced microscope and we have
- 00:23:48those those oh here's my laser so there
- 00:23:51is oxygen right there only 92 of these
- 00:23:55things chemists and some physicists get
- 00:23:57to know these things it's sort of like
- 00:23:58getting to know I don't know your team
- 00:24:01or something you know you spend some
- 00:24:02time with them and pretty soon it
- 00:24:03doesn't seem like such a big number or
- 00:24:05maybe your fraternity so each one begins
- 00:24:07to have a personality I I my my friend
- 00:24:12Frank assaro who's a chemist has a has a
- 00:24:15deep experience with idium and osmium
- 00:24:17and renum and tungsten and tanum he
- 00:24:19knows these things you know better than
- 00:24:23I think he knows me um I I know some I
- 00:24:26know hydrogen pretty well carbon is
- 00:24:28really important I you know neon helium
- 00:24:30I know some of these things but it's
- 00:24:32more of a casual relationship anyway
- 00:24:34there aren't that many of them and I
- 00:24:35don't expect you to learn them all but
- 00:24:37it's good to know that there aren't that
- 00:24:38many of them and therefore if you wanted
- 00:24:40to really study this stuff pretty soon
- 00:24:42you'd know them all and then you start
- 00:24:44wondering about what's inside of them
- 00:24:45and you learn there's not much inside
- 00:24:46they're all made out of protons neutrons
- 00:24:48and electrons so there's something more
- 00:24:51simple more Elementary than the atoms
- 00:24:53there 92 atoms but hey there only three
- 00:24:55of these things well it turns out there
- 00:24:57are some other little things in here but
- 00:25:00it's not too complicated basically all
- 00:25:02these things are made out of protons
- 00:25:03neutrons and
- 00:25:05electrons each one here this one has one
- 00:25:08proton in the middle this has two
- 00:25:10protons in the middle this has three
- 00:25:12four five 6 7 8 9 10 11 12 you catch the
- 00:25:16pattern that little number up there
- 00:25:18called the atomic number is the number
- 00:25:19of protons in the center in fact because
- 00:25:22the protons attract
- 00:25:24electrons there's the same number of
- 00:25:26electrons in each atom 1 2 2 3 4 5 6 7 8
- 00:25:319 10 so so the atoms are relatively
- 00:25:33simple but when they form together they
- 00:25:35create molecules and in the air the kind
- 00:25:39of molecules we have about 80% of them
- 00:25:41are two nitrogen molecules two nitrogen
- 00:25:44atoms forming a molecule there's
- 00:25:47nitrogen about 19 20% is O2 about 1%
- 00:25:52neon I'm sorry uh
- 00:25:56argon that's the atmosphere
- 00:25:58little bit of water
- 00:26:00vapor the little bit of water vapor is
- 00:26:03what we call
- 00:26:05humidity so there's a little bit of
- 00:26:07water vapor mixed in but it's much less
- 00:26:08than these are and when that when you
- 00:26:10cool things out the water vapor tends to
- 00:26:12form droplets we call that rain so here
- 00:26:14we have these things this uh the the
- 00:26:18these atoms and molecules in this case
- 00:26:20they would be mostly molecules molecule
- 00:26:22simply means more than one atom so
- 00:26:23nitrogen is a molecule oxygen is a this
- 00:26:25is an atom and it's also the molecule of
- 00:26:27argon just one atom but that's not the
- 00:26:31way they really are not in the air
- 00:26:35they're
- 00:26:36moving this is turns out to be the key
- 00:26:39to understanding temperature and heat
- 00:26:42it's that these things are in motion and
- 00:26:43the rules turn out to be far simpler
- 00:26:46than anybody imagined they had all sorts
- 00:26:47of complicated ways of trying to
- 00:26:49understand what is temperature they
- 00:26:50thought maybe it's a liquid it's a
- 00:26:52hidden mysterious liquid that gets into
- 00:26:54things when this thing gets in it's hot
- 00:26:56when the thing go they call it head
- 00:26:57names for it they listan and things like
- 00:27:00this they made up all sorts of bad
- 00:27:01theories keep that in mind today as you
- 00:27:03read about new
- 00:27:04theories that the theory of temperature
- 00:27:06took a long time to work out and most of
- 00:27:08the theories published were wrong when
- 00:27:11you read about some new Theory that's
- 00:27:12being published odds are 90% it's going
- 00:27:15to turn out to be wrong the way science
- 00:27:18goes we do experiments that can prove
- 00:27:21some theories right and some theories
- 00:27:23wrong the theory of heat was one of the
- 00:27:25great mysteries for a long time there
- 00:27:28are all sorts of strange things about
- 00:27:29heat I don't know if you've ever picked
- 00:27:31up a glass of water and you pick it up
- 00:27:34and say wait that's not glass that's
- 00:27:38plastic you know as soon as you touch
- 00:27:41it so how do you know if you start
- 00:27:45thinking about it you learn by
- 00:27:46experience learn the the thing this
- 00:27:49thing oh that's plastic doesn't break
- 00:27:51boom that's glass it does break yeah
- 00:27:54okay so these things how do you tell the
- 00:27:56way you the way I tell
- 00:27:59is by how it feels in temperature a
- 00:28:01glass feels cooler try this find a
- 00:28:05window somewhere the Blackboard is a
- 00:28:07good example you feel that it's
- 00:28:10cool and then you feel the
- 00:28:14wall that's cool too the wood no that's
- 00:28:19not
- 00:28:20cool odd so is everything at different
- 00:28:24temperature
- 00:28:26huh zero flaw of
- 00:28:31thermodynamics states and but this
- 00:28:33doesn't mean that I have explained why
- 00:28:35it works the fact
- 00:28:38is there are more mysteries about this
- 00:28:40than most physics classes would let on
- 00:28:43but the zero flow of thermodynamics is
- 00:28:45that you put things in a room together
- 00:28:46and you have no energy coming in and no
- 00:28:48going out they just sort of sitting
- 00:28:49together and you just wait and if you do
- 00:28:52that everything reaches the same
- 00:28:55temperature that's called The zeroth Law
- 00:28:57of ther now it's rather mysterious I
- 00:28:59haven't even told you what temperature
- 00:29:01is yet for a long time nobody knew
- 00:29:03temperature was what you measured with
- 00:29:05thermometers you know you put a little
- 00:29:06bit of liquid in the glass tube and when
- 00:29:08it gets warm it expands and by seeing
- 00:29:11how much it expands you can measure
- 00:29:13something they call temperature but they
- 00:29:14didn't know what it was is it why why
- 00:29:18why does the stuff expand when it gets
- 00:29:21warm what is warm mean and the zero flaw
- 00:29:24was really hard to discover because this
- 00:29:26table is cooler than this than this they
- 00:29:29don't seem to be the same temperature
- 00:29:31they hold a plastic glass and it seems
- 00:29:34warmer than a glass
- 00:29:36glass what's going on
- 00:29:38here let me just tell you the answer on
- 00:29:40the glass class and the temperature
- 00:29:41glass see we're not all at the same
- 00:29:43temperature in this room the room is
- 00:29:46somewhere around
- 00:29:4865° 68° C uh
- 00:29:52Fahrenheit and I am closer to
- 00:29:5598.6 so you see I'm not at the same same
- 00:29:58temperature of this room I am warmer if
- 00:30:00I were 65° I'd be
- 00:30:03dead so I'm warmer so when I feel a
- 00:30:07piece of glass or a piece of metal o
- 00:30:09this feels cold liquid nitrogen okay
- 00:30:12when I feel the Blackboard what I'm
- 00:30:15sensing is my body which is warm losing
- 00:30:19heat it's traveling into the
- 00:30:22Blackboard so it feels cool to me
- 00:30:24because my skin is cooling off because
- 00:30:26it's losing Heat into the Blackboard so
- 00:30:29I don't really sense temperature that's
- 00:30:32why it's so confusing I don't feel the
- 00:30:34temperature of that what I feel is that
- 00:30:36I am warmer than it is and therefore I
- 00:30:37start to cool my skin when I touch it
- 00:30:40with wood it turns out wood is the same
- 00:30:42temperature as the room the same
- 00:30:43temperature as the Blackboard but heat
- 00:30:45doesn't flow very easily into wood and
- 00:30:47therefore it doesn't cool my hand so
- 00:30:49what I'm really sensing is the flow of
- 00:30:52heat which is called
- 00:30:56conduction okay now I still haven't told
- 00:30:59you what temperature is talking about
- 00:31:01these things I hope to give you a little
- 00:31:02bit sense of the mystery of this thing
- 00:31:04so that you'll appreciate the amazingly
- 00:31:06simple answer when it finally when I
- 00:31:08finally tell you I might as well finally
- 00:31:09tell
- 00:31:12you it turns out that temperature is the
- 00:31:16hidden kinetic energy of the atoms you
- 00:31:19take a solid and they're usually not
- 00:31:22sitting here like
- 00:31:23this they're not sitting there old
- 00:31:25stationary they're j joggling a little
- 00:31:27bit let's see I can make him jog a
- 00:31:28little
- 00:31:31bit maybe have to turn this thing
- 00:31:36on
- 00:31:37there see all joggling a little bit it
- 00:31:41turns out that what we call
- 00:31:44temperature is that this has energy it's
- 00:31:48hidden because you don't see it it's
- 00:31:49hidden because the molecules aren't
- 00:31:50moving the molecules in this wood are
- 00:31:52juggling but they don't go
- 00:31:54anywhere they stay in that place and so
- 00:31:57they're shaking if I cool it down
- 00:31:59they're shaking less put it in the
- 00:32:00refrigerator and the shaking goes
- 00:32:03down so that's the secret to what heat
- 00:32:06is and what is temperature what's the
- 00:32:08difference between heat and
- 00:32:10temperature
- 00:32:11well let me add more kinetic
- 00:32:15energy you're going to see this thing
- 00:32:17turn into a
- 00:32:19gas so let me add some more kinetic
- 00:32:21energy
- 00:32:29that's sort of like a
- 00:32:42liquid kind of noisy isn't
- 00:32:44it okay so when the Jon gets so big that
- 00:32:49the particles can slip past each other
- 00:32:52we call it a
- 00:32:55liquid if you cool it down so they
- 00:32:57adjust less then you no longer have a
- 00:33:01liquid you have a solid that's called
- 00:33:05freezing now I still haven't told you
- 00:33:07what temperature is but when you get
- 00:33:09below when you get to let's say 0° C 32
- 00:33:14fahit that's called the freezing point
- 00:33:16of water it's also the melting point of
- 00:33:18water when you take liquid water and
- 00:33:20cool it to that point the molecules can
- 00:33:22no longer slip past each other and we
- 00:33:24get a solid if you get it above that
- 00:33:26point it doesn't matter whether you're
- 00:33:28melting it or freezing it the
- 00:33:31temperature is the
- 00:33:32same now what happens as you as you uh
- 00:33:37begin to melt the
- 00:33:41ice uh what you have is some of the
- 00:33:43things on the surface turn into a liquid
- 00:33:45and then the rest of the ice begins to
- 00:33:48warm up eventually it all turns into a
- 00:33:50liquid but as it it takes time to do
- 00:33:53that so it takes a while for ice to melt
- 00:33:55you put some ice cubes in a glass of
- 00:33:56water it may take you know 20 minutes
- 00:33:58for all the ice cubes to melt in the
- 00:34:00meantime the temperature stays at The
- 00:34:02Melting Point the freezing point which
- 00:34:04is 32 Fahrenheit 0 celsi it stays at
- 00:34:08that temperature because any energy that
- 00:34:10goes in goes into melting the ice so
- 00:34:12it's a nice way to keep the temperature
- 00:34:13constant that's why we use ice to keep
- 00:34:15the temperature
- 00:34:17constant uh and this but this is what
- 00:34:19melting is melting is when they slip
- 00:34:21when they finally get so fast that they
- 00:34:23can overcome gravity and go off into a g
- 00:34:26into into space we call that a gas so
- 00:34:28right now the molecules in this room are
- 00:34:30bouncing
- 00:34:32around uh they are actually well I
- 00:34:35haven't said what temperature is yet
- 00:34:36here's the answer to what temperature is
- 00:34:39this is one of the great discoveries in
- 00:34:40physics and it's it's it's amazingly
- 00:34:43simple
- 00:34:45um we Define the Kelvin temperature the
- 00:34:48absolute
- 00:34:55temperature and I never remember the
- 00:34:57number
- 00:34:59so I don't want you to either well you
- 00:35:02can but then you can say you know
- 00:35:03something I don't
- 00:35:11know okay here it is the kinetic energy
- 00:35:15of the
- 00:35:18molecule is equal to a constant which is
- 00:35:212 10-
- 00:35:2323rd that's a number I don't remember
- 00:35:25times the absolute temperature
- 00:35:28temperature is just the energy per
- 00:35:30molecule that's all it is the molecules
- 00:35:33are
- 00:35:34moving each one has a typical average
- 00:35:38kinetic energy from its
- 00:35:41motion if you know that kinetic energy
- 00:35:43you know the temperature this is the
- 00:35:45relationship between the kinetic energy
- 00:35:46and the temperature this is the equation
- 00:35:48you don't even have to write down I do
- 00:35:50want you to know that temperature
- 00:35:53represents the hidden kinetic energy the
- 00:35:55kinetic energy that's hidden because the
- 00:35:57thing that goes very far it just bounces
- 00:35:59back and
- 00:36:01forth how fast does it move this is a
- 00:36:05really interesting and critical number
- 00:36:08how fast are the molecules here shaking
- 00:36:10well they not well they're not going
- 00:36:11anywhere yeah but they're going back and
- 00:36:12forth so they're instantaneous velocity
- 00:36:15well some of them will stop for a moment
- 00:36:16and get going you look at these things
- 00:36:17some of them are moving faster than ever
- 00:36:19others I'm talking about the average
- 00:36:22velocity the average speed of these
- 00:36:24molecules what is it in the air for
- 00:36:27example how fast are these molecules
- 00:36:43moving guess I lost
- 00:36:46it look at that it's low
- 00:36:50anyway the speed of molecules in the air
- 00:36:53not by coincidence
- 00:36:58is about a mile every 5
- 00:37:01Seconds that's the number I mentioned
- 00:37:03earlier that's the speed of
- 00:37:05sound that's how fast they're moving I
- 00:37:07want you to always remember that the
- 00:37:09typical velocity at room temperature is
- 00:37:12about the speed of sound and that is not
- 00:37:14a coincidence when we talk to waves
- 00:37:16we'll talk more about this but when you
- 00:37:18when you make a sound wave what you're
- 00:37:20doing is you're compressing it a little
- 00:37:21bit you can press a little bit of air
- 00:37:24and then it pushes on the air next to it
- 00:37:27but but it doesn't push on it until that
- 00:37:28air molecule gets over there it's moving
- 00:37:31at about this about a certain
- 00:37:34speed that is these molecules are not
- 00:37:37going to put a force on the next one
- 00:37:38until they reach it and so the speed at
- 00:37:41which sound goes is about the same as
- 00:37:43the speed at which the molecules
- 00:37:45go so I want you to always remember a
- 00:37:47typical speed of a molecule is equal to
- 00:37:50the speed of sound which is 5 miles
- 00:37:53every second because that's what your
- 00:37:54parents told you about not being afraid
- 00:37:55of lightning that's about 1,000 ft per
- 00:37:59second because they 5,000 ft in a mile
- 00:38:01it's about 330
- 00:38:03m/s that's about 1 meter every 330th of
- 00:38:08a
- 00:38:10second about 3
- 00:38:12milliseconds not going to ask you to do
- 00:38:14all these numbers but I want you to I
- 00:38:15want you to basically know that the
- 00:38:16speed of sound is about a mile every 5
- 00:38:19Seconds th000 ft per second and that's
- 00:38:21the speed of the molecules of the air
- 00:38:24and it's not a coincidence we talk more
- 00:38:26about waves we'll talk more about
- 00:38:28exactly how that works but for right now
- 00:38:31the sound can't go any faster than the
- 00:38:33speed at which the molecules move now
- 00:38:35that's not true in a solid in a solid
- 00:38:37the molecules are already touching each
- 00:38:38other and you push on this one it pushes
- 00:38:40on the other one immediately it doesn't
- 00:38:41have to move over there to touch it so
- 00:38:44for a solid the speed of of a
- 00:38:46compression can go a lot faster and it
- 00:38:48does speed of sound in steel in Granite
- 00:38:51in the earth is faster than in the air
- 00:38:54but in the air it's set by that speed
- 00:38:56now here's the here's here's the really
- 00:38:58surprising thing about this if you look
- 00:39:00in this thing I'll make this noise again
- 00:39:02you'll see there are two different Siz
- 00:39:03walls some big ones and some small
- 00:39:10ones some of the it's kind of hard to
- 00:39:12tell there not a big difference maybe I
- 00:39:14should put in some even bigger ones
- 00:39:21[Applause]
- 00:39:30[Applause]
- 00:39:40what you might be able to sense if you
- 00:39:41watch this for you know few hours that
- 00:39:44can actually be
- 00:39:45mesmerizing is that the Big Balls aren't
- 00:39:47moving as fast on average sometimes they
- 00:39:49get a big kick and they go flying but on
- 00:39:51average they're kind of slow and the
- 00:39:53little ones are moving faster keeping
- 00:39:55that in mind watch it again
- 00:40:09the reason is they're all at the same
- 00:40:12temperature and that means they have the
- 00:40:15same kinetic
- 00:40:16energy but kinetic energy is 1 12 mv^
- 00:40:25squ if they all have the same kinetic
- 00:40:27energy then things that have big M must
- 00:40:29have small
- 00:40:31V's so a big thing moving slowly has the
- 00:40:34same kinetic energy as a small thing
- 00:40:35moving fast so this is a a key
- 00:40:39thing this definition of
- 00:40:43temperature
- 00:40:45is based on the physics fact that you
- 00:40:47put things in a box and they all start
- 00:40:50sharing
- 00:40:51energy they don't share velocities they
- 00:40:53don't all have the same velocities they
- 00:40:55all get the same average energies the
- 00:40:58same energies of motion when they're in
- 00:41:00the room if if this thing is hotter than
- 00:41:02the air then these molecules are moving
- 00:41:04faster when they move faster and the air
- 00:41:06mudes bang into them they tend to give
- 00:41:08up some of their energy to the air and
- 00:41:10so they'll keep on giving up energy
- 00:41:12until they're moving at about the same
- 00:41:14turns out not the same velocity it's the
- 00:41:16same kinetic energy why is that well if
- 00:41:18you have a big massive thing and it's
- 00:41:20something that's light the light thing
- 00:41:21will bounce off faster than will a heavy
- 00:41:24thing if this is an obvious think of a
- 00:41:26baseball bat the baseball goes faster
- 00:41:28than the backat you hit it with the
- 00:41:31whole weight of your body well that's
- 00:41:33the way ta cob used to hit it you hit it
- 00:41:35with the whole weight of your body get
- 00:41:37that behind it and the ball will get
- 00:41:39more energy something bouncing off a
- 00:41:41massive object will pick up more
- 00:41:43velocity and something that's light but
- 00:41:46the amazing thing is they tend to have
- 00:41:48the same kinetic energy now if you think
- 00:41:51about some of the this has all all sorts
- 00:41:54of interesting
- 00:41:56implications um
- 00:41:58Let me Give an example when when when
- 00:42:00the universe was made we believe the
- 00:42:03Earth like
- 00:42:06Jupiter had a large amount of
- 00:42:08hydrogen uh hydrogen in the
- 00:42:11atmosphere the big planets have lots of
- 00:42:13hydrogen in the atmosphere we have
- 00:42:16essentially none this is important for
- 00:42:18the hydrogen economy we don't have
- 00:42:19hydrogen the only hydrogen we have is
- 00:42:21the hydrogen that combined with oxygen
- 00:42:23and with other Rock other minerals like
- 00:42:25Silicon to make water silicon dioxides
- 00:42:28rocks and stones and so on we don't have
- 00:42:30free hydrogen why not well it's because
- 00:42:33hydrogen is the lightest of the
- 00:42:37elements up
- 00:42:40there there's
- 00:42:42oxygen H2
- 00:42:45is 16 times lighter than O2 16 times
- 00:42:49lighter in the atmosphere it will have
- 00:42:53about the same kinetic energy but
- 00:42:54because it's lighter it has to have a
- 00:42:56higher vol
- 00:42:58velocity so if you put hydrogen into
- 00:43:00this room and just let that gas float
- 00:43:02around the room it will reach the same
- 00:43:04temperature that means the same kinetic
- 00:43:06energy as the oxygen same kinetic energy
- 00:43:09as a small molecule must be moving fast
- 00:43:11it doesn't get the same speed it's
- 00:43:13faster so it turns out that hydrogen in
- 00:43:16the Earth's atmosphere picks up enough
- 00:43:18speed that actually gets escape velocity
- 00:43:22it get it launches itself into space
- 00:43:25that's why we don't have hydrogen
- 00:43:28why does Jupiter have hydrogen it has a
- 00:43:30much higher escape velocity we haven't
- 00:43:31talked about escape velocity yet we will
- 00:43:33next week but if you want to leave the
- 00:43:36gravity if you want to break away what
- 00:43:38you have to do is to give an object more
- 00:43:41kinetic energy than the energy of the
- 00:43:43gravitons that are holding it in if you
- 00:43:45give it more than that it will go to
- 00:43:47Infinity it will get off it will escape
- 00:43:49that's called Escape velosophy that's
- 00:43:50what we do when we're sending people to
- 00:43:52the Moon we give them escape
- 00:43:54velocity so the hydrogen because it's
- 00:43:57light but has the same kinetic energy as
- 00:44:01the heavier things must be moving faster
- 00:44:03it gets escape velocity at leaves so we
- 00:44:06have no hydrogen in our
- 00:44:07atmosphere rather simple same thing
- 00:44:10turns out to be true for
- 00:44:12helium the sun is 10% helium by weight
- 00:44:1710
- 00:44:1910% and yet
- 00:44:21um I maybe it's 10% by number actually
- 00:44:24no I think it's 10% by weight
- 00:44:27uh and and yet it doesn't lose it
- 00:44:29because the gravity is so strong but
- 00:44:31here on the earth we don't have helium
- 00:44:33in the atmosphere the only helium that
- 00:44:35we get is helium that comes from the
- 00:44:37ground and as we'll learn in a couple of
- 00:44:39weeks the helium in your helium
- 00:44:41balloons all comes from radioactive
- 00:44:45decay of uranium and Thorium in the
- 00:44:47ground we'll we'll cover this uh as the
- 00:44:51thorium and uranium emit helium when
- 00:44:54they undergo a radioactive explosion and
- 00:44:57and this stuff accumulates under the
- 00:44:58ground until we pull it out of the oil
- 00:45:01wells and put it in our toy balloons
- 00:45:04we'll we'll be coming to that but when
- 00:45:06it gets into the atmosphere it soon
- 00:45:09escapes because it's light enough that
- 00:45:11eventually it'll have escape velocity
- 00:45:13and it will get
- 00:45:15out
- 00:45:20um let let me let me let me give you
- 00:45:22some of the numbers
- 00:45:24here uh this this this I call the
- 00:45:27absolute
- 00:45:28temperature and it's the one that
- 00:45:30scientists like to use there's another
- 00:45:32temperature we call
- 00:45:34Celsius Celsius is equal the absolute
- 00:45:37temperature uh minus
- 00:45:42273 see it's the same
- 00:45:45scale except for Celsius they decided
- 00:45:48zero would be when water freezes or
- 00:45:52melts whereas zero for for for the the
- 00:45:57Kelvin scale this is called
- 00:45:59Kelvin or
- 00:46:03absolute Kelvin reaches the Kelvin
- 00:46:06temperature reaches zero when the
- 00:46:07molecules stop
- 00:46:10moving so it turns out that in terms of
- 00:46:13equations and so on the Kelvin scale
- 00:46:15works much better when we talk about
- 00:46:17absolute zero we don't mean zero Celsius
- 00:46:20or0 Centigrade 0 Celsius or 0 centigrade
- 00:46:23is where water freezes we mean 0o Kelvin
- 00:46:27which is uh C = 0 - 273 that's - 273
- 00:46:34cenr this is called absolute
- 00:46:37zero absolute zero is when the molecules
- 00:46:40are no longer
- 00:46:44moving sometimes you'll hear people
- 00:46:47speculate about getting to a lower
- 00:46:49temperature than absolute
- 00:46:51zero that means the molecules are moving
- 00:46:55slower than zero
- 00:46:58velocity so what does that mean it's
- 00:47:03nonsense someone will say how do you
- 00:47:05know you can't get below absolute zero
- 00:47:09oh well how do you move slower than
- 00:47:12stationary that's your
- 00:47:15answer by the way since there is no
- 00:47:17possibility of getting temperatures
- 00:47:19below absolute zero some stist decide
- 00:47:21let's use negative temperatures in a
- 00:47:24different way and so they come up with a
- 00:47:26new
- 00:47:27interpretation and they will say from
- 00:47:29now on by temperature I'm not going to
- 00:47:31mean the kinetic energy of the molecules
- 00:47:33when it's negative what I'm going to
- 00:47:35mean is the distribution of molecules in
- 00:47:36different energy levels no you don't
- 00:47:37have to know this the reason I'm telling
- 00:47:39you this is every now and then you will
- 00:47:41see some stist say I got to a
- 00:47:43temperature of below absolute zero and
- 00:47:46every physicist knows what they're
- 00:47:48referring to they're referring to a
- 00:47:49different definition of temperature that
- 00:47:50is useful only when you get to negative
- 00:47:53temperatures and in lasers they'll talk
- 00:47:55about negative temperatures but it you
- 00:47:57know a physicist just can't let a whole
- 00:48:01realm of numbers be
- 00:48:03unused but the standard definition of
- 00:48:06temperature is that it is the kinetic
- 00:48:08energy per molecule and if you want it
- 00:48:11in Celsius you got to subtract
- 00:48:15273 I'm sorry add if you want if you
- 00:48:18want Celsius you subtract
- 00:48:21273 and that'll give you the Celsius
- 00:48:23Fahrenheit is is very similar uh
- 00:48:27Fahrenheit the scale in Fahrenheit was a
- 00:48:29great inventor of
- 00:48:31thermometers and so he created this
- 00:48:33thing he had to put a scale on it so he
- 00:48:35decided that the uh coldest that he
- 00:48:37could
- 00:48:39get was when he mixed ice and salt and
- 00:48:43he called that
- 00:48:44zero okay we we now that's zero
- 00:48:47fahrenheit 32 degrees or 32 degrees
- 00:48:50below freezing the warmest he he could
- 00:48:52get was so hot it wasn't useable so he
- 00:48:54took the human body temperature and said
- 00:48:56that's going to be 100 actually the
- 00:48:58amusing thing is he did the other way
- 00:48:59around uh he he had zero as being the
- 00:49:02human body temperature and and he had a
- 00:49:06100 as being the temperature that you
- 00:49:07could get with ice and so it was an
- 00:49:09upside down temperature scale compared
- 00:49:10to Modern standards you know it doesn't
- 00:49:12really matter it's just a thing on a
- 00:49:14Fahrenheit thermometer that you could
- 00:49:15read it eventually got changed and and
- 00:49:19now you know we in the United States use
- 00:49:22Fahrenheit everybody else uses Celsius
- 00:49:25uh if you want the Fahrenheit
- 00:49:26temperature you take the Celsius
- 00:49:28temperature and you multiply it by
- 00:49:3195s so you get bigger degrees and then
- 00:49:34you subtract
- 00:49:3632 you let's see you add 32 if I want
- 00:49:39zero then it's 32 so so this is the
- 00:49:43equation um it just it's also based on
- 00:49:47on 100 I mean one
- 00:49:50isn't one isn't metric and the other
- 00:49:52unmetric it's just that when Napoleon
- 00:49:55was deciding he wanted to change the
- 00:49:57world number system so everybody could
- 00:49:59be French uh he they came up with the
- 00:50:02Celsius system which is 100 degrees
- 00:50:05between water freezing and water boiling
- 00:50:08whereas Fahrenheit had 100° between ice
- 00:50:11between ice and ice and salt and the
- 00:50:14human body they're both 100 degrees just
- 00:50:16different definitions anyway we're stuck
- 00:50:18with these two things and I still know
- 00:50:21Fahrenheit much better than I know
- 00:50:23Celsius used to be called
- 00:50:25Centigrade Cent grade because was based
- 00:50:27on 100 say 100° of course Fahrenheit was
- 00:50:30also based on 100° but nobody remembered
- 00:50:32that and then again the scientists doing
- 00:50:35this felt that it's terrible to have a
- 00:50:39number that's not honoring someone in
- 00:50:41their field so they named this after Mr
- 00:50:43Celsius as near as I could tell has no
- 00:50:46scientific achievements
- 00:50:48whatsoever but he got his name honored
- 00:50:50in quite a
- 00:50:53Way Glen seaborg got his name he was a
- 00:50:55professor here died a few years ago one
- 00:50:58of these elements here is called
- 00:51:00seaborgium uh it's over here somewhere
- 00:51:03oh seaborgium let's say it would be
- 00:51:06there it is seaborgium
- 00:51:08106
- 00:51:11uh by the way you may wonder about some
- 00:51:14of these things Glenn seaborg actually
- 00:51:17discovered plutonium plutonium is here
- 00:51:19he also discovered neptunium he was
- 00:51:21naming them Uranus Neptune Pluto he
- 00:51:23named them sort of after the planets
- 00:51:24that were then then around then after
- 00:51:26that they started discovering more and
- 00:51:28more and more and it all being
- 00:51:30discovered here here at Berkeley that's
- 00:51:32why the next one was called
- 00:51:35californium and what's this one berkum
- 00:51:39or burum or whatever berkum named after
- 00:51:43here okay and uh or maybe that's how
- 00:51:45wait a minute which is now I'm confused
- 00:51:48CM curium they named it after cury and
- 00:51:51then this one is
- 00:51:52californium and then fermium mendelevium
- 00:51:55nobilium lorenci and lawen I'm named
- 00:51:58after Lawrence professor in this
- 00:51:59department boy how many people do we
- 00:52:01have we have Lawrence we have we have
- 00:52:05seeborg
- 00:52:06um okay named
- 00:52:09after I can predict with confidence
- 00:52:12there will never be a
- 00:52:14malium okay I'm not in that business of
- 00:52:16finding new elements and nobody would
- 00:52:18think of honoring me in that
- 00:52:20way okay so this is the temperature
- 00:52:22scale and converting between temperature
- 00:52:23scales is the pain in the neck but I you
- 00:52:25should know that freezing is 0
- 00:52:28Celsius and 32 fahit you should know
- 00:52:31that it's just a matter of of of
- 00:52:33educated knowledge boiling of water is
- 00:52:37212 in in the Fahrenheit scale and
- 00:52:40except when you're in high mountains
- 00:52:41we'll talk about that
- 00:52:43soon and it's 100 on the Celsius scale
- 00:52:46and that absolute zero means when the
- 00:52:49motion completely comes to a stop turns
- 00:52:51out it doesn't actually come to a
- 00:52:52complete stop it because of quantum
- 00:52:53mechanics there's always a little bit of
- 00:52:55residual motion
- 00:52:57but uh at least classically it would
- 00:52:59come to actual to to absolute zero
- 00:53:02absolute Zer is in the motion stops
- 00:53:04you're not going to get below absolute
- 00:53:05zero for that reason now take a look at
- 00:53:08this
- 00:53:11again okay so let me turn this
- 00:53:15on let me heat it up a little bit
- 00:53:30[Applause]
- 00:53:32ah notice how it pushes against that
- 00:53:35surface that's what pressure
- 00:53:38is pressure is you are standing here and
- 00:53:41molecules are bouncing against you and
- 00:53:43they push on you now this hand has no
- 00:53:45pressure on it it actually has pressure
- 00:53:47on both sides molecules are hitting it
- 00:53:48here and they're hitting it here hit it
- 00:53:50on both sides so it doesn't move well
- 00:53:53sometimes they going to be more hitting
- 00:53:54it on this side than that side right so
- 00:53:56actually it will move a little bit but
- 00:53:58such a tiny amount that you don't notice
- 00:54:00it unless you're looking at pretty small
- 00:54:01particles we may do that next time I may
- 00:54:03set up something where you can actually
- 00:54:05see the thing
- 00:54:06Jitter this little Jitter is
- 00:54:09characteristic of things that are at
- 00:54:11room temperature everything shakes a
- 00:54:13little bit this little bit of shaking is
- 00:54:14responsible for all sorts of things in a
- 00:54:17wire there's a little bit of the
- 00:54:19electron shaking because of that you get
- 00:54:21an electron signal even when you're not
- 00:54:23Ted to a radio station if you ever
- 00:54:25listen to a radio and you hear something
- 00:54:27that sounds like
- 00:54:29this you're hearing the electrons Shake
- 00:54:33you're hearing the electrons move in and
- 00:54:35off the wire just because of the fact
- 00:54:37that they have some kinetic
- 00:54:39energy old TVs you don't get this so
- 00:54:42much on the new ones but the old TVs if
- 00:54:44you were in between channels you see a
- 00:54:46whole bunch of
- 00:54:47dots and those dots were when you have
- 00:54:49no signal so why are there dots why are
- 00:54:51they changing the reason is these little
- 00:54:53maybe we should get a demo of that these
- 00:54:54little electrons sometimes jump off the
- 00:54:56wire and they give you a false picture
- 00:54:58of just
- 00:55:00noise it's one of the challenges in
- 00:55:03electronic engineering is overcoming
- 00:55:05this kind of a noise just the fact that
- 00:55:07the electrons in a wire are moving means
- 00:55:09sometimes they move when there's no
- 00:55:10signal and you don't know you think
- 00:55:12that's a signal it gives the hiss of the
- 00:55:14radio it gives a signal on wires that
- 00:55:18that becomes a fundamental limitation on
- 00:55:20how much information you could send over
- 00:55:21wires sometimes to get rid of this noise
- 00:55:24what they do is they cool the
- 00:55:27wires now you understand why you're not
- 00:55:31asleep are you
- 00:55:35hello
- 00:55:36respond you give him a
- 00:55:39tap yeah wake up respond you just missed
- 00:55:44something I'll repeat it this is
- 00:55:47important that even the electrons in a
- 00:55:50wire are shaking around this gives you a
- 00:55:53signal because signals are moving
- 00:55:54electrons even when you haven't any
- 00:55:56signal on the wire and because of that
- 00:55:59you will hear a a hiss noise and if you
- 00:56:03want to reduce the hiss one of the ways
- 00:56:05of doing it is cooling the wire and you
- 00:56:07can see why you want to bring those
- 00:56:08electrons so that they're not shaking
- 00:56:10they move only when you want them to
- 00:56:12move they're not shaking like that
- 00:56:14that's that's that's that's a kind of
- 00:56:16noise the molecules in a room are moving
- 00:56:19around and then they bounce off
- 00:56:21something like that they produce a
- 00:56:22pressure let's say I think here this is
- 00:56:24something I can do right now this thing
- 00:56:27is a can you can see it's we
- 00:56:31don't kind of an old beaten up can but
- 00:56:34anyway it has molecules bouncing out
- 00:56:37about this why don't they crush it it
- 00:56:40turns out that these bouncing molecules
- 00:56:42put a force on if you want to keep
- 00:56:44something from moving you notice when
- 00:56:45these bounce it it pushes this piston
- 00:56:47out now I can hold it in whoops I can
- 00:56:51hold it
- 00:56:52[Applause]
- 00:56:54in but to hold it act put a force on it
- 00:56:58suppose we had the molecules in this
- 00:57:00room and we had they were pushing
- 00:57:03against this can and Suppose there were
- 00:57:05no air molecules in the
- 00:57:08can then they would crush the
- 00:57:11can if we want to hold it out it takes
- 00:57:14about 15 pounds for every square inch
- 00:57:16that's we call out the pressure of the
- 00:57:19air it's the force you need to keep it
- 00:57:21from collapsing if I had a pump I could
- 00:57:24pump out the air in this and you see
- 00:57:25what would
- 00:57:28oh I have a pump
- 00:57:30good let's pump the air pump the air out
- 00:57:33and see what
- 00:57:36happens this must turn on somehow I bet
- 00:57:38there's a switch on
- 00:57:43it I'm sure there's a switch on it
- 00:57:57okay the air pushed it in why does the
- 00:58:00air if the air is moving why doesn't it
- 00:58:02just escape the answer is the weight of
- 00:58:04the air above
- 00:58:05it if I heat up the air then the
- 00:58:08pressure increases and the air spreads
- 00:58:11out when the air spreads out it doesn't
- 00:58:13weigh as
- 00:58:15much what happens when something doesn't
- 00:58:17weigh as much let me heat up some
- 00:58:20air call the hot air
- 00:58:24effect let me see if I can
- 00:58:35get some guess on this thing this goes
- 00:58:36here here here
- 00:58:44okay there so I'm I'm making it hot why
- 00:58:47is it blue we're going to be talking
- 00:58:48about that it's blue because it's hot
- 00:58:50because it's hot the electrons are
- 00:58:52shaking because the electrons are
- 00:58:53shaking it turns out they emit
- 00:58:55electromagnetic waves that's why it's
- 00:58:57blue we'll be talking a lot more about
- 00:58:59that as we come to light and waves and
- 00:59:01shaking but heat when you heat up a
- 00:59:04tungen filament the reason it glows so
- 00:59:06bright is the electrons are shaking
- 00:59:08faster when they're shaking faster a
- 00:59:10shaking electron emits an
- 00:59:11electromagnetic wave we'll talk more
- 00:59:13about that when we get to waves here I'm
- 00:59:15heating up this gas and I'm going to put
- 00:59:17this thing right on top of it and now
- 00:59:20I'm heating up the air now the air
- 00:59:21inside of this is getting warm because
- 00:59:23the air inside of this is getting warm
- 00:59:25it's expanding because this expanding it
- 00:59:26doesn't weigh as much as the air out
- 00:59:28here so this air weighs a certain amount
- 00:59:32it's not very heavy it over here the air
- 00:59:35is heavy they come together down here
- 00:59:37this heavy air has greater pressure than
- 00:59:39this light air so result this heavy air
- 00:59:42pushes the lighter air up this
- 00:59:45way do that here well here let's see
- 00:59:48here say liquid what I'm going to do is
- 00:59:50heat up the liquid when I heat up the
- 00:59:51liquid it will
- 00:59:53expand when it expands it will way
- 00:59:57less and
- 00:59:59uh let me get this let me get this going
- 01:00:02I'll turn this one on over
- 01:00:07here turn it down a little
- 01:00:12bit okay that's going to heat up this
- 01:00:14liquid so what's going to happen with
- 01:00:15this liquid this liquid is getting hot
- 01:00:17the molecules are bouncing faster
- 01:00:18because they're bouncing faster they get
- 01:00:20pushed apart it expands when it gets hot
- 01:00:22essentially almost everything expands
- 01:00:24there are a few exceptions but almost
- 01:00:26everything expands when it gets hot how
- 01:00:28much does it expand well for every
- 01:00:29degree it's about a part in a thousand
- 01:00:32some things are a part in 10,000 some
- 01:00:33things are apart in 100 some things are
- 01:00:35apart in 100,00 they're about a part in
- 01:00:37a thousand or a part in 10,000 it's
- 01:00:39expanding a little bit so this is
- 01:00:42expanding that means this tube weighs
- 01:00:45less than this
- 01:00:47tube here the weight of this is pushing
- 01:00:50against this the weight of this is
- 01:00:52pushing this one's pushing
- 01:00:54harder because it weighs more the same
- 01:00:57amount of tube but this thing is hot
- 01:00:59over here and it's still cool over here
- 01:01:01it's getting warm over there it's
- 01:01:03getting cool over here and as a result
- 01:01:06this weighs more and so because it
- 01:01:08weighs more it pushes this out of the
- 01:01:09way I think we can see that if we throw
- 01:01:11a little bit of of of color in here
- 01:01:14we'll see what
- 01:01:16happens and you see which way the
- 01:01:18water's
- 01:01:20flowing okay so the water is now flowing
- 01:01:23in a circle because we're heating one
- 01:01:25side side of it and making it
- 01:01:28lighter in some sense what we're doing
- 01:01:30is turning heat into motion this is a
- 01:01:32kind of a motor a very primitive motor
- 01:01:35but it is a motor that's what a motor is
- 01:01:37a motor is when you get some sort of
- 01:01:38energy typically in the form of heat in
- 01:01:41a gasoline engine which we'll talk about
- 01:01:42next week or Thursday rather with a
- 01:01:44gasoline engine you create an explosion
- 01:01:47you have now have this hot gas you want
- 01:01:49to turn that into the Turning of the
- 01:01:50wheel of your automobile this is a very
- 01:01:52simple one well how about this thing
- 01:01:54here we've been heating up
- 01:01:57it's it's pretty hot in there I cannot
- 01:01:59keep my hand there so this air is rising
- 01:02:02now because it's being pushed down by
- 01:02:03the cool air over here so this is a
- 01:02:05circulation pattern this kind of
- 01:02:07circulation is extremely important the
- 01:02:09same thing occurs in a
- 01:02:10thunderstorm in a thunderstorm sunlight
- 01:02:13comes down Heats one patch of land more
- 01:02:15than others because of their clouds so
- 01:02:17this part gets hot when it gets hot the
- 01:02:19air above it gets hot when the air above
- 01:02:20it gets hot it doesn't weigh as much as
- 01:02:22the air over here so it tends to go up
- 01:02:24gets pushed down by the heavier air this
- 01:02:26heavier air tends they they come
- 01:02:28together at the bottom like this they
- 01:02:29come together at the bottom but this
- 01:02:31side weighs less than that side so this
- 01:02:33side pushes more because pressure is
- 01:02:35just the weight of the stuff above it
- 01:02:37pressure of the air is just the weight
- 01:02:39of the air above
- 01:02:40us so let's see I think with a piece of
- 01:02:44plastic I might be able to demonstrate
- 01:02:45that this air is Flowing out of
- 01:02:49here so let's see if it'll make this
- 01:02:51plastic
- 01:02:56fill up with warm
- 01:03:03air okay so the plastic is now is
- 01:03:05filling up with warm
- 01:03:09air oh until it keep it from the heat so
- 01:03:13it fills up with warm air the air inside
- 01:03:15of it this is what a high air balloon
- 01:03:19is why you use hot air the hot air is
- 01:03:24weighs less and therefore at the very
- 01:03:28bottom there's less of a force from its
- 01:03:32weight than from the surrounding air so
- 01:03:34the surrounding air tends to move in
- 01:03:36underneath it until the now the air is
- 01:03:37still going up can you see it there is
- 01:03:38the air is still going no you can't see
- 01:03:40it but the air is still going up it just
- 01:03:41that this thing turned over that's how H
- 01:03:44air balloon works it works on the
- 01:03:48fact let's see
- 01:04:00am I turny to off the wrong one
- 01:04:03here there we go so a hot air balloon
- 01:04:06works on the fact
- 01:04:09that the faster it is which means the
- 01:04:12hotter the greater is the
- 01:04:15pressure when the pressure is well the
- 01:04:18pressure comes from two things it comes
- 01:04:19from the weight here the pressure is
- 01:04:21greater so it tends to
- 01:04:23expand and because it expands at weight
- 01:04:25weighs less because it weighs less it
- 01:04:28gets pushed out of the way from here
- 01:04:30what happens in the air is is the air
- 01:04:33pressure okay let me let me I think I
- 01:04:36think I may have confused you a little
- 01:04:37bit with the pressure but let me just
- 01:04:39say that the the air becomes less dense
- 01:04:41in here the water becomes less dense in
- 01:04:43here and as a result we get this flow
- 01:04:46this flow is called it has a name it's
- 01:04:48called
- 01:04:50convection and it it turns out
- 01:04:52convection is not only creates
- 01:04:53thunderstorms this is like a
- 01:04:55thunderstorm
- 01:04:56this is what causes the thunderheads to
- 01:04:58rise it's the heating of the air below
- 01:05:01it um that's a thunderstorm we also use
- 01:05:05in our rooms if you have a heater in the
- 01:05:06room on one side of the room what you'll
- 01:05:09find is the heat will tend to rise that
- 01:05:12is what happens is the heat heats up the
- 01:05:14local Air the local air expands it
- 01:05:16weighs less so it tends to rise like a
- 01:05:18hot hot air balloon and then it'll stay
- 01:05:20up in the ceiling and if you ever get up
- 01:05:21on a ladder or a chair you say boy it's
- 01:05:23warm up here that's because the hot air
- 01:05:25has risen now if it keeps on going then
- 01:05:28you may get a flow around in a circle
- 01:05:30and some of that warm air will come down
- 01:05:33but if you want a heater you don't put
- 01:05:34it up at the ceiling because it'll just
- 01:05:35keep it'll all the hot air will stay up
- 01:05:37there you need it near the bottom you
- 01:05:38want to get some convection going so the
- 01:05:41hot air eventually comes down again but
- 01:05:43it's all based on that uh I we can do
- 01:05:46the opposite here we can we can take a a
- 01:05:49a a liquid this is this is liquid air
- 01:05:51it's actually look n
- 01:05:54nitrogen this is wonderful stuff I love
- 01:05:56this stuff it's liquid it's uh well
- 01:05:59below zero
- 01:06:01Celsius and it's cold and you can it can
- 01:06:05really hurt you if you stick your finger
- 01:06:08in it uh and there it
- 01:06:12is so this is nice it's cold it's
- 01:06:15boiling it's boiling at room
- 01:06:18temperature it turns out I can put my
- 01:06:20finger in as well as I do just for a
- 01:06:21second okay and the reason is when my
- 01:06:24finger goes in there immediately boils
- 01:06:26against my finger makes a layer of
- 01:06:29gas that layer of gas doesn't con
- 01:06:33doesn't con doesn't conduct heat very
- 01:06:35well so if I just do it for an instant I
- 01:06:38can even pour this on my S as long as I
- 01:06:41don't do it for very long you'll notice
- 01:06:43when it's on the tabletop here an
- 01:06:45interesting thing happens it forms a
- 01:06:47little look at that shoot across see it
- 01:06:48shoot across there okay what's happening
- 01:06:51is the little bit of the liquid hits the
- 01:06:53table warms up makes a layer of gas and
- 01:06:56then it floats on that layer of gas some
- 01:06:59people think that this is how firew
- 01:07:01Walkers walk on hot coals I've never
- 01:07:04tried it myself but they say if you're a
- 01:07:06little bit sweaty and you walk on the
- 01:07:08hot coals what happens is the the the
- 01:07:11sweat turns to Gas makes a thin layer of
- 01:07:14gas and G and gas doesn't conduct heat
- 01:07:16very much why because it's a thousand
- 01:07:18times fewer molecules per cubic
- 01:07:20centimeter this is a number I want you
- 01:07:22to know it could be on the quiz on
- 01:07:24Thursday if there is is a quiz on
- 01:07:26Thursday could be on the midterm if you
- 01:07:28look on Old midterms you'll find it
- 01:07:29there gas is typically a thousand times
- 01:07:31more spread out a thousand times less
- 01:07:34dense let's let's put some of this
- 01:07:36liquid nitrogen in
- 01:07:39here and use it to cool
- 01:07:43off this
- 01:07:45balloon and let's see what happens is
- 01:07:47the air in this balloon begins to
- 01:07:50decrease the air is Cooling and because
- 01:07:53it's cooling the the pressure is going
- 01:07:55down because the pressure is going down
- 01:07:58it's being compressed by the force of
- 01:08:00the air on the outside so you may notice
- 01:08:01it's actually getting a little bit
- 01:08:03smaller as the air inside
- 01:08:06cools eventually the air inside may turn
- 01:08:09into a liquid in that case it'll be a th
- 01:08:11times less dense and that balloon is
- 01:08:13getting pretty pretty small so just as
- 01:08:16we can heat up air and make it expand
- 01:08:18and then it tends to rise we can use
- 01:08:20this to make the pressure go down inside
- 01:08:24and eventually lose the volume I want
- 01:08:25you to know that factor of a th000
- 01:08:27because it's really important in many
- 01:08:28many many things that factor of a th
- 01:08:32when Dynamite explodes what you're doing
- 01:08:34is turning the energy that's in the
- 01:08:36molecules you're breaking up the
- 01:08:38molecules and turning it into a very hot
- 01:08:41gas so you release a lot of energy a hot
- 01:08:43compressed gas has a very high pressure
- 01:08:46that very high pressure pushes things
- 01:08:49away it makes an explosion so there's
- 01:08:52our balloon made nice and small let the
- 01:08:56air inside warm
- 01:09:01up oh here's here's something we could
- 01:09:03do um let's
- 01:09:06see let
- 01:09:09us how do I do this
- 01:09:13without what I want to do is to pour
- 01:09:16some of this in this cannon
- 01:09:28so the gas there is expanding I put a
- 01:09:30cork on this the air is coming out there
- 01:09:33now if I close
- 01:09:37that of course I mean this is right you
- 01:09:40the liquid nitrogen hey you can do the
- 01:09:42same thing with a Coca-Cola bottle right
- 01:09:44just shake it a lot and as the gas comes
- 01:09:46out of the liquid from being dissolved
- 01:09:48in the liquid you you make you make a
- 01:09:50little Cannon it's great stuff it I I I
- 01:09:53I sometimes use it to remove warts cuz
- 01:09:55you put Q-tip you can you can remove a
- 01:09:57wart that way now let's talk about what
- 01:10:02happens suppose I have an object that's
- 01:10:04moving at the speed of
- 01:10:07sound then it has as much energy in it
- 01:10:10in motion as it has in the random hidden
- 01:10:14energy it's only twice as much that's
- 01:10:16when a bullet you can shoot a bullet at
- 01:10:17the speed of sound with a really
- 01:10:19moderate rifle and when you do that
- 01:10:22you're putting as much energy into this
- 01:10:23as at the speed of sound what happens if
- 01:10:25that that bullet stops suddenly and all
- 01:10:27that energy turns into heat well I say
- 01:10:30that room temperature about
- 01:10:3220
- 01:10:333° centigrade is equal to 300 Kelvin I
- 01:10:38want you to know this number that's room
- 01:10:40temperature and absolute
- 01:10:45scale and this formula gives it to you
- 01:10:48right there you just add 273 okay and
- 01:10:50maybe it's 27 27 centigrade
- 01:10:56okay so room temperature is about 300
- 01:10:57Kelvin something a bullet will have as
- 01:11:00much energy in its overall motion as in
- 01:11:03its random motion they're roughly equal
- 01:11:05when it's going the speed of sound
- 01:11:07because the speed of sound means every
- 01:11:08molecule is moving at the speed of sound
- 01:11:10but now the whole thing is moving
- 01:11:11together at the speed of sound if that
- 01:11:13thing stops all the energy goes into
- 01:11:15random motion and now you've doubled the
- 01:11:17energy that means you'll double the
- 01:11:18temperature so if you stop a bullet you
- 01:11:20expect it and all the energy goes into
- 01:11:21the bullet you expect it to heat up from
- 01:11:23300 Kelvin to
- 01:11:25600 Kelvin that's 300
- 01:11:29Centigrade imagine you're the space
- 01:11:31shuttle
- 01:11:33now you are going 18.3 times the speed
- 01:11:37of sound
- 01:11:3918.3 times the velocity of
- 01:11:43sound your kinetic energy is 18.3 *
- 01:11:48squared times the energy of your object
- 01:11:52itself the space shuttle when it's
- 01:11:54moving at this speed has much much more
- 01:11:57energy in its motion than it has in its
- 01:12:01temperature when it comes to the Earth
- 01:12:03it has to stop so it has to get rid of
- 01:12:05that energy so how does it get rid of
- 01:12:07that energy well by running into the
- 01:12:11air it runs into the air isn't the space
- 01:12:13shuttle going to heat up well you don't
- 01:12:16want that or it'll be let's say 20 * 20
- 01:12:19that's that's 400 times hotter than room
- 01:12:23temperature 400 times hotter than 300 K
- 01:12:26300 K *
- 01:12:28400 is 1
- 01:12:3112 that's 12,000 Dees the sun is only
- 01:12:376,000 so if all the energy of the space
- 01:12:40shuttle goes into heating the space
- 01:12:41shuttle you get something that's hot
- 01:12:43that's that that's hotter than the
- 01:12:44surface of the Sun 20 times hotter than
- 01:12:46the surface of the Sun obviously you
- 01:12:48don't want to do that so they designed
- 01:12:49the space shuttle it has to lose its
- 01:12:51energy could use retro Rockets yeah if
- 01:12:54you want to make the space shuttle
- 01:12:55thousand times bigger you can carry the
- 01:12:57fuel to slow it down you have to carry
- 01:12:58as much fuel as you use to speed it
- 01:13:01up so what they do instead is they have
- 01:13:03a special design so when it hits the air
- 01:13:06the energy goes into the air not into
- 01:13:08the space shuttle these tiles are
- 01:13:10designed to have very low
- 01:13:13conduction because you don't want the
- 01:13:15space shuttle to heat up to to to
- 01:13:18120,000 de so the tiles are designed
- 01:13:22have very low conduction the energy goes
- 01:13:24into the air instead and that slows the
- 01:13:27thing down while they well the tiles
- 01:13:28glow red hot but the energy doesn't get
- 01:13:30inside unless there's a broken tile and
- 01:13:34then the energy is so enormous that you
- 01:13:38understand what happened with the
- 01:13:39Columbia tragedy
- kinetic energy
- meteor
- gravitational energy
- thermodynamics
- temperature
- speed of sound
- energy conservation
- heat transfer
- space shuttle
- physics concepts