The ABSURDITY of Quantum Mechanics at LARGE SCALES!

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REFERENCES
Quantum tunneling: • Is Quantum Tunneling t...
Superconductivity: • How do Superconductors...
Quantum entanglement: • Quantum Entanglement E...
Quantum mechanics explained: • What is Quantum Mechan...
Frustrated Total Internal Reflection: tinyurl.com/2myks7ow
CHAPTERS
0:00 Magic is not real, I guess
1:33 My inspiration
2:40 Superposition
4:20 Quantum tunneling
5:37 Heisenberg Uncertainty principle
7:54 Double slit experiment
9:40 Why don't we see quantum behavior at macro scales?
10:45 What is Decoherence
11:20 Real examples of Macro scale quantum physics
SUMMARY
What If our everyday life was based on quantum mechanics? What if macro objects behaved like quantum objects?
If you are in a classroom with 4 chairs, you would appear to a second student, to be sitting on all the seats at once. But as soon as he touches one of the chairs, you appear in one of the seats sitting by yourself. And he is then able to take a seat. You were in a superposition, which is the ability of a quantum object such as a photon, electron, atom or anything sufficiently isolated, to be in multiple positions at the same time until it is measured.
This comes from the Schrodinger equation which contains a term called the wave function. The wavefunction for an object contains all the information that describes the quantum object, such as its position, spin, momentum, etc. Objects can take on almost any value according to the wavefunction prior to measurement. The wavefunction only tells us the probability. But once a measurement is made, the properties of the particle gets fixed to only one of the possible states. Note that a measurement is any kind of interaction and is a physical process that does not require a measurer.
Let’s say you hit a squash ball against the wall in front of you. The ball disappears and shows up on the other side. This phenomenon is known as quantum tunneling. In quantum mechanics, when a quantum object like an electron encounters an energy barrier, like a wall, there is a non zero chance that it will end up on the other side of the wall. This is because its wavfunction extends to all of spacetime, meaning it can in principle end up anywhere, including the other side of the wall.
But can any player hit the squash ball in the first place? If the squash ball is a quantum object, it is subject to the Uncertainty Principle. This principle says that there is a fundamental limit to how precisely we can know certain combinations of properties of a particle, such as its position and momentum. So if the player knows where the ball is, he won't know how fast it's going. And if he knows how fast it's going, we won't know where it is. So taking a swing, he may not hit the ball. This is not due to an observer effect. It’s not a limitation of what we can measure. It is a limitation of what we can know.
If a squash ball machine creates and shoots squash balls onto the wall for practice purposes, you would not actually see any balls coming out of the ball machine. All you would see is balls bouncing off the wall in front of you. What's happening is that the balls coming out of the ball machine are in superposition. They only become localized and visible after they have interacted with the wall in front of you. Before this happens, their location could be anywhere in the court. The various locations would have a probability associated with them. They could even be outside the court due to quantum tunneling.
Why don’t we actually see this in our everyday experience? Why don’t these quantum behaviors appear in our macro world? Do the laws of quantum mechanics apply only at micro scales? No, the laws of quantum mechanics apply to everything. But the effects of quantum mechanics are too small to be noticed.
Subatomic and atomic scale objects act like waves, and so behave like quantum objects. But large objects are made of a huge number of individual waves, since a squash ball is made of almost 10^15 atoms. All these waves of atoms act in a disorganized and random way. Their individual waves interfere with each other, and average out to zero. This disorganized wave-like behavior is called “decoherence” in physics. And this cumulatively results in classical behavior. In order to get a macro object to behave like a quantum object, we would need all its quadrillions of individual waves to be coherent, and behave like one large wave. This is usually not possible.
#quantummechanics
#quantumatlargescales
But you should know that coherence has been achieved in some large molecules consisting of up to 2000 atoms. Other large scale quantum effects include superconductors, Bose-Einstein condensate and superfluids.

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2 июн 2024

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Комментарии : 625

@DanteGabriel-lx9bq Год назад

I cannot express how good you are at explaining this stuff, you deserve so much more!

@user-qz5ox5ov2f Год назад

exactly

@divyanshipatel8570 Год назад

Yeah, Like I'm being 14 and understanding all of this says alot

@dongshengdi773 Год назад

@@user-qz5ox5ov2f This is proof that magic is real

@markjapan4062 Год назад

JESUS BSAID SATAN WOULD APPEAR AS AN ANGEL AND DECIEVE MANY THESE ARE MUSLIMS THERE WAS NO GABRIEL ALLAH THE SUN GOD AKBAR THE MOON GOD...

@omarwhaibi8395 Год назад

He actually is. Thank you for videos.

@tomaaron6187 Год назад

I’ve been a geophysicist for 45 years. I must thank you for re-instilling the sense of wonderment I felt in my younger days. I watch your presentations then find myself pondering it all in those quiet times of contemplation when hiking or cycling.

@vinvic1578 Год назад

I love your emphasis on the Heseinberg uncertainty being a consequence of wave mechanics as opposed to an observer effect. As a physics student I can attest this misconception is everywhere in pop science ! Great video all around.

@treeofgrowth Год назад

You mean "woowoo channels" like Destiny?

@dialecticalmonist3405 Год назад

Saying something is "uncertain" is not an answer to any question. Saying something has a point origin at an event horizon, at least makes an attempt at a definitive answer. You might not like the "observer" explanation, but it is a more rigorous definition of reality. "Limitation of what we can know," vs "limitation of what we can measure" is just semantics. It is the same thing.

@vinvic1578 Год назад

@@dialecticalmonist3405 what are you talking about ? its quite obvious you have no scientific training, I'm sorry, read up on the Heisenberg uncertainty principle, Fourier transforms and an undergrad QM book (I recommend Griffiths) and I think these concepts will be much clearer. This has nothing to do with dialectics, its a mathematical property of wave packets.

@rolandmeyer3729 Год назад

I see you are a materialist "scientist."

@herrroin6867 Год назад

We don’t really know if it has an effect though

@claudiorassouli1240 Год назад

Your animations about physics are some of the best anywhere. I love how you point to formulas and break them down. How long does it take you to make the animations? Do you do them yourself? Either way it is very impressive.

@ArvinAsh Год назад

Thanks. I don't make them myself. I just guide the animators. This ones in this video took about a month by people who know what they are doing.

@thezone5840 Год назад

@@ArvinAsh Can you tell me what would happen if something that is 1inch X 1inch X 1 Inch would behave if the waves were all in coherence? According to particle physics, why is this impossible or overly difficult to accomplish?

@flambambam3578 Год назад

@@thezone5840 An average atom has a radius of 0.1 nanometers. A solid 1'x1'x1' volume would have something on the order of 10^23 atoms, each with their own wave functions that would have to be nearly perfectly in-phase which each other to produce a noticeable effect from our perspective. If you had a ball of 10^23 tangled rubber bands, how difficult would it be to lay out every single one in a neat grid?

@siddharthshekhar909 Год назад

@@ArvinAsh Give my respects to the animators and the people involved in the storyboarding . They deserve an applause . 👏

@markjapan4062 Год назад

WHY ARE THERE MILLIONS OF QURAN IN THE SEWERS IN MECCA IF IT IS HOLY IT IS NOT..

@elpuerco6059 Год назад

Decoherence perfectly describes my mental state 😂 Excellent explanation and video, as always, professor.

@TheFos88 Год назад

That's what I said when he mentioned frustrated total internal reflection lol

@adels8205 Год назад

I agree with the other comment here, I cannot express how grateful I am for having discovered you. Really like your style of explaining complex problems.

@mmogaddict Год назад

I am already living the Quantum Mechanical lifestyle, most of the time I know neither where I am nor where I am going.

@alimmaqsa Год назад

I love when u say :" right now".👍

@jmcsquared18 Год назад

It should be noted, decoherence is often quoted as a solution to why we never see quantum behavior on macroscopic scales, but this isn't the full story. Decoherence is just a term used to describe what happens when a huge quantum system's many parts interact, both with each other and with their environment. Everything gets scrambled up, and the system's parts begin to behave according to classical probability rules instead of the Born rule. What this does model is the emergence of classical statistical mechanics. But there is no mechanism that decoherence provides that explains the quantum measurement problem. As a system begins to interact with its environment, the state of the system, at least in principle, remains stuck is a massive entangled superposition, all the way to the macroscopic level. Interactions by themselves do nothing, according to Schrödinger's equation, to force a system to leave a superposition of states. This only appears to happen (for some reason) once the system interacts with measurement devices. Therefore, it's still an interpretive question, and an unanswered one at that, to ask what the state of the system at large scales.

@ArvinAsh Год назад

Good. Thanks.

@b43xoit Год назад

Can it be explained as entanglement? I think this is something that Susskind is saying. The system under observation gets entangled with the particles of the measuring instrument.

@jmcsquared18 Год назад

@@b43xoit You may be describing one of two things with the words "entanglement" and "Susskind." One is the idea of Everette's interpretation, which is that the universe splits in some sense. Different branches of the entangled wave function describes different outcomes of a measurement. The other thing you could be referring to is the ER = EPR conjecture from Susskind and Maldacena. So, I'd ask to clarify what specifically you're referencing here.

@b43xoit Год назад

@@jmcsquared18 I don't know about an entangled wave function having branches; that's farther along than I have studied to. My understanding is that for any given pair of particles, there is no entanglement, full entanglement, or partial entanglement, and these things can be inferred from measurements, at least partially. And when I refer to Leonard Susskind, I'm not referring to the conjecture you cite, necessarily. Just the material he states here on RU-vid.

@jmcsquared18 Год назад

@@b43xoit Then I suppose I'm not sure what specifically you're asking/claiming.

@jmcampo9388 Месяц назад

Excellent presentation with utmost insight and clarity, Congratulations Arvin!

@christiannissen5339 Год назад

Thanks Arvin, and what excellent job you do

@kallesamuelsson8052 Год назад

After another 1000 explanation clips or so I just might start to grasp this subject. It's so fascinating but so confusing. Keep up the good work Arvin!

@mariobrambilla4099 Год назад

The most excellent explanation I’ve ever seen on this subject. Congratulations Arvin! Keep going!

@magellantv Год назад

Wow! This was amazing and incredibly well done 👏

@bobs182 Год назад

This is the first time I have understood why large objects don't act like quantum objects. I was stuck on the idea that it must be a perception problem of different scales of existence but your wave function interference cancelling each other makes sense.

@aryansingh7209 Год назад

I'm a big fan of you, Arvin! You made everything complex as hell simple as a piece of cake.

@markjapan4062 Год назад

ALLAH THE SUN GOD LOLOLOLOL

@aryansingh7209 Год назад

@@markjapan4062 ALLAH THE GAY LOLLILOLI

@JohnSmith-pd2dq Год назад

Excellent .... take my hat off for you Arvin!!

@beniaminmarin1596 Год назад

I've been waiting for years for someone to make this video.

@rwarren58 Год назад

Thanks for another great video! I love being able to understand the basics of Quantum Mechanics. Oh and great splash page. 😎

@jorgearango6108 Год назад

Wow!!! Excellent Thank you for that explanation!🏆

@robertryder1097 Год назад

Thank you - brilliant presentation of a fascinating subject!

@Quantum-1157 Год назад

As always a great upload full of insights explained in a simple and interesting way! Thnx!

@maitlandbowen5969 Год назад

What a marvellously clear capture of the information related to the question asked - provides guidance (frameworks) for ongoing and greater explanation in the area. Thank you. You are tops, so very across the material.

@cycklist Год назад

This is beautifully explained. Thank you.

@Trevesten Год назад

This video should be in the top-5 videos one should start watching to get familiar with the quantum world. Thank you so much Arvin, you are doing an amazing job in educating us!

@MrFlemmingjensen Год назад

Great video Mr. Ash , as always. :)

@surajvkothari Год назад

Content like this is a blessing! Such a unique take on quantum behaviour compared to lectures!

@captainzappbrannagan Год назад

Love these vids on how to simplify and make the hard topics understandable and exciting!

@brunofalconeguerra3428 Год назад

What a great video!! Congrats

@robotaholic Год назад

This is creative and interesting and funny. Thank you for all that work!

@anishashee8511 Год назад

Excellent work. You always make that much awesome video and explain it very intuitively. 👏🔥

@saeeddargahi4750 Год назад

Very glad that I found this channel,really great topics👍👍

@eugeniag37 Год назад

Excellent video, as usual!

@hanssteyn9775 Год назад

Love listening to you. Thank you.

@Bhaumikpk Год назад

Very nice presentation. Many thanks.

@Snowman_44 Год назад

You've got a new subscriber. Amazing contents!

@markgowers5713 Год назад

Excellent, the best explanation of Quantum Mechanics I have see on RU-vid!

@Name-js5uq Год назад

You explained that perfectly. I totally get it.thanks so very much!!

@antoniocampos9721 Год назад

Absolutely fantastic. Thanks for this...I'm a Brazilian subscribed.

@abhishek_sengupta Год назад

Aaahaaa!! Loved it ❤️❤️

@joeanarumo616 Год назад

I really wish educators were held to a much much higher standard (& compensated as such). Imagine a generation of people, 80+% of which being educated by people somewhere near Arvin's level.

@6099rahul Год назад

Finally. Thank you Arvinash!

@CassianLore Год назад

Another excellent video Arvin ! See you in the next video my friend 👍

@ScienceNerder Год назад

Awesome explanation....

@poojarakshit1000 Год назад

Outstanding as usual.Your videos excite me like a little child wanting to learn the mysteries of the universe.I'd love to meet you in person & discuss physics.

@mcwulf25 Год назад

Thanks. A clear explanation using some examples I haven't seen before.

@dogasal Год назад

scuh a beatiful explanation! Thank you

@sumedhburbure4173 Год назад

Great video!

@thedouglasw.lippchannel5546 5 месяцев назад

Bravo! Arvin is amazing.

@michaelfoxbrass Год назад

This is a brilliant teaching video for the layman’s introduction to this amazing field of research! Thank you for making it!

@gypsycruiser 9 месяцев назад

Very well presented!

@SampathKumar-nx5xh Год назад

You are wonderful in explaining and extremely knowledgeable man. Hats off !!!

@aem4670 Год назад

Great job 👍

@timjohnson979 Год назад

Very will done, Arvin! I'm reminded of George Gamow's Mr Tompkins series. He did a few short illustrative stories on quantum effects if we could see them such as "Quantum Billiards" and "Quantum Jungles".

@ArvinAsh Год назад

Indeed. It was an inspiration.

@dr.satishsharma9794 Год назад

Excellent..... thanks 🙏.

@theshowmanuk Год назад

Absolutely superb demonstration ! I am sure this will encourage students (young and old) to get into the maths and physics to get a greater understanding and appreciation of quantum mechanics.

@stevensbox9625 Год назад

Dude, Seriously, you keep my retired engineer mind sharp & wanting more. Keep up the good work. God's speed.

@rohankulkarni100 Год назад

Excellent visualisation 😊

@mostafakhorsandi5421 Год назад

Awsome, thank you :)

@mixerD1- Год назад

Thoroughly enjoyed this video...thank you Arvin. An incoherent understanding is slightly more coherent due to it.

@aguma2067 Год назад

Excelente vídeo 👍👌

@damongulley9865 Год назад

Fantastic..loved it dude. Quantum is a tough subject & you pulled it off.

@Name-js5uq Год назад

You really deserve so much more subscribers, like at least a million more!

@evdrivertk Год назад

Thanks for the excellent presentation. Another analogy for the Heisenberg Uncertainty Principle I like to use is detecting audio at different frequencies. You can easily detect the start and stop of a high-pitch noise, light the "high-hat" sound in dance music. Low-frequency tones (20-30Hz) are so spread out that it's far more difficult to tell where they start in time. In typical music, a bass thud is really a short high-pitch impulse followed by the long bass note to give the listener a better sense of when the "beat" starts. Keep up the great videos!

@jayvaibhawverma Год назад

Nice. That's a good analogy. But aren't the low frequency tones generally pressure waves? Or more correctly, sound vibrations are pressure waves. So, can we consider the Energy-time equation of the Heisenberg's Uncertainty to deduce the analogy you have given? Because I think that Position-momentum uncertainty will become vague for understanding this. What do you think?

@niloymondal Год назад

Great Video. A video on everyday life implications of Delayed Choice Experiment would be super cool.

@Parnell50 Год назад

This was a pretty good video, I'm utterly impressed

@jayaprakashrao7535 Год назад

Superb presentation....

@averyzaliasylvia4026 Год назад

I have never been so excited and confused watching RU-vid video

@Mtheory989 Год назад

This was the best explanation of the double slit experiment I have ever seen - which really helps drive home quantum phenomena

@schmetterling4477 9 месяцев назад

Except that the double slit is not a quantum phenomenon. A quantum phenomenon either has Planck's constant in it somewhere or it requires multi-quantum correlations like entanglement. ;-)

@vaclavkrpec2879 Год назад

Re the uncertainty principle: I think that's actually one of the least "weird" properties of "quantum world". Because it's simply an inherent property of all waves, not just the wave function. For example, you can observe a very similar thing with sound: you may have a nice tone, which is a sinusoid wave---so you can easily measure its frequency (wavelength) and that's what defines the pitch. But you can't locate a tone to a singular moment---only to an interval in time during which it sounded. On the other hand, a clap or a gunshot is easily pinned to a moment, but you can't really say what's its pitch; as it's just one sound pressure peak, there's no frequency to it... Same thing.

@shaundurant7415 Год назад

This was insightful.

@That_Freedom_Guy Год назад

You are one of the first, that I know of, to show quantum weirdness at a human scale. I've been looking out for such videos. Thanks. ❤

@juzoli Год назад

In the example where we shoot waves at the wall, and a ball comes back, it would be more accurate to show that another wave comes back, but from a specific point of the wall. It is never “not a wave”, the collapse of the wave function is just the beginning of another wave function.

@ArvinAsh Год назад

it would be a 3D localized wave, which would be like a fuzzy sphere. What we showed is pretty close imo.

@paulbk2322 Год назад

This has been mind blowing 👍👍

@DrSlipperyFist Год назад

I'm 40, wish this content was available when I was 14. Great work, videos keep getting better - huge fan.

@reynalindstrom2496 Год назад

Great video! This was one of the best. Love from Sweden💛💙

@tejasraysad933 Год назад

U nailed it❤️👍

@user-kq8rk1vd3u Год назад

This episode came in the right time i was searching for superposition for weeks and quantum lifes thanks for the episode

@Name-js5uq Год назад

I cannot wait until you reach one million subscribers. You deserve it 10 times over. I love your explanations so very much! Thank you very much Arvin. Don't worry it will happen very soon I hope. You are the best physics explanations on the entire you tube by far. Absolutely love you!!!❤❤❤

@ArvinAsh Год назад

So nice of you

@krisdarthvader7651 Год назад

AWESOME VID

@Dolores5000 Год назад

Dang son! I love this! And you! Fascinating

@davidsellon4580 Год назад

What a great, intuitive explanation of why we don't see quantum behavior at our macro level. How is it that after watching dozens of other videos from various creators about the quantum world, this is the first time I've understood the quantum/macro relationship?

@sunshinemama9143 Год назад

Just found this channel, and WOW!

@mohammedfahadnyc1385 Год назад

As always, Awesome video Arvin! By the way, I was thinking what would the animation look like when you put a photon detector on the double slit experiment? Like then we’d be able to see the ball coming out off the ball throwing machine and going thru the slit in two straight lines but still creating the interference pattern? Also for fingers thru glass containing water, I don’t think thats photon demonstrating quantum behavior , thats merely total internal reflection, but I admit it’s a good analogy for Quantum tunneling

@aryangoswami7512 Год назад

Super explanation sir

@cykkm Год назад

Arvin, what a didactically amazing idea!!! I've never seen anything like this before, and such an animation is immensely instructive for looking at the unintuitive wave properties! A tiny nitpick, at 5:50, about the uncertainty principle (UP), it would have been better to say more unambiguously that the UP had been _estimated_ by Heisenberg and _derived_ a few years later; it's simply the Schwarz inequality between conjugate uncertainties in the position and momentum spaces, related by FT-but you know it, whom I'm talking to! I personally know that many physics enthusiasts who try to wrap their heads around QM believe the inequality has been _postulated_ axiomatically, like, for example, the Born rule has. Possibly, the persistent imprecise wording is due to the fact that Heisenberg didn't derive the formula later named after him, as the Stigler's law (formulated and named after Stigler by Merton, naturally) predicts. He only used an order of mag estimation. Too bad we use imprecise “principle,” “rule,” “postulate” etc. in physics. QM is sheer math, with its complex-valued operators and infinite-dimensional state spaces corresponding to nothing in Nature, that, IMO, it would be less confusing-assuming generously that QM _could be_ less confusing-to use “theorems” and “axioms,” as mathematicians do. “Heisenberg's theorem,” “Born's axiom;” no ambiguity :) Owning a 5-string bass guitar with an added low B2 string (~125 Hz), I often use it as an example: if the player slides his finger up or down a semitone, changing the length and thus resonant frequency on this slow-vibrating string, how much time does one need to recover a new note-i.e, the change in frequency? The answer is derived (with a few technical assumptions) with FT and the same bounding inequality on the time and frequency domain uncertainties: exactly 1/4 of the period. It's a warm-up math before the full UP derivation. :)

@carlstanland5333 Год назад

I followed the link for the FTIR and I’m trying to understand it. How about a video on this phenomenon? Love your videos!

@clarkeeeee 9 месяцев назад

Major props to people who play quantum squash, it looks pretty difficult.

@schmetterling4477 9 месяцев назад

There are no such people, unless they can make an infinite number of clones of themselves. :-)

@channel4me434 Год назад

Thanks (again) Arvin for this video. I always wondered why the double slit experiment doesn't work for large objects, but is does for electrons, while electrons do also interfere with their surrounding. Of course an electron is much smaller than a tennis ball, but is has a charge and mass and even the smallest interaction should prevent an object (electron) to come in superposition. But now I understand that if an object is not a pure wave function because it exists of many waves that are not in sync, it can not be in superposition.

@ArvinAsh Год назад

An electron is a single wave, and so behaves like a single wave. A grain of sand is trillions of waves that interfere with each other. It no longer behaves like a wave overall.

@Rationalific Год назад

As a part-time photographer, my way of thinking about the Heisenberg Uncertainty Principle and not knowing precisely the position and momentum is thus: If the shutter speed of a camera is thus that there is no blur at all on the per-pixel scale (Planck-length, I guess), then you can see a photo of a perfectly clear moving object, but you can't determine its speed from the photo. If you have a slower shutter speed, the object will instead be smeared over the picture somewhat, but using the smear and the shutter speed, you can determine how fast it was moving. Even so, the image is blurred, so you can't get a completely clear look at it like you could if the shutter speed completely stopped the motion (and thus didn't allow you to determine the motion). So with photography, you can never have perfect clarity and know the speed of the object at the same time. By the way, I'd be happy to see Frustrated Total Internal Reflection get it own video!

@user-yg9zb4qi2g Год назад

Many thanks teacher

@DownhillAllTheWay Год назад

In the last month or so, I have seen quite a lot of videos on similar topics to this, of which three have been outstanding. Those three include this one.

@tomusic8887 Год назад

Thank you so much and beautifully done! Making the non intuitive and hard to believe awkwardness of quantum mechanics visible!!!! 👍👍👍😃

@Nesterou Год назад

I'm not done yet with the video, but let me tell you, I've been watching stuff about that uncertainty thing. I'm a real donkey at maths, but somehow I love everything about physics and especially quantum. First time I kind of grasp why it's not possible to have both position and speed. Great, really great illustrations...

@harrybarrow6222 Год назад

Hmm… in the illustrated example of the aircraft seat, the new passenger only seems to determine whether the first seat is occupied. Surely, there is now still uncertainty about the three remaining seats and their occupancy should still be superposed?

@casb2480 Год назад

Thank you for finally mentioning that measurement does not mean measurement in a literal sense, this used to confuse me so much

@aryanayushman3090 Год назад

Arvin can you make a video on how our senses connected to the physical world ? How accurately we perceive the world?

@b43xoit Год назад

That can be a fascinating subject, I am so sure. For example, dogs can be used to sniff molecules that no technology has to date.

@nmarbletoe8210 Год назад

That is largely unknown, but there are some very interesting areas of discovery. For example, grid cells.

@twilightbts7058 Год назад

Great! Perfect video for my doubt for why quantum mechanics doesn't apply for us. Thank you.

@yuwumi870 Год назад

Really enjoyed the video and the tunneling explanation. Would've loved to see mention of De Broglie's hypothesis/equation. For me personally, it really solidified the idea that these subatomic particles aren't bound to "particle-like" behavior.

@NuisanceMan Год назад

Very well explained video! A minor factual nit-pick: you said a squash ball has almost 10^15 atoms. But 10^15 atoms of any substance is less than a microgram.