hah!

Angry upvote

This is good. This is really good. Have a like.

/facepalm

My one didn’t do anything, it’s dyslexic !

No. He just gave a physics lecture that chemistry students could understand. That's even more impressive :)

@@khaitomretro ...shots fired

look at this flextrosexual

He lost me halfway through, then blew my mind when he put it together.

@@khaitomretro this is the principles of optical quantum computing I think

Wow

I agree, first time it clicked. visual learner here

I mean it kinda makes sense since there are similar concepts in maths as well

Was your stash in shot?

Yep, several pennies finally dropped for me too!

Which school did you go I didn't even knew about this up till now.

Profs usually can't explain it in a comprehensive way because they don't fully understand it themselves.

I always had this lack of clarity when it came to chirality. Well, now it's sloved.

@@MagicMarv Not always the case. Good institutions usually have excellent professors. What matters is whether the students are curious or not.

It was explained to use during the first semester for the first time and repeated/applied several times so far... I'm studying bioinformatics.

It's weird how much of traditional teaching (or maybe just how some school curriculums were set up) was just learn the facts / models instead of explaining why, visualizing it, or even just explaining why it's useful. Now that I'm older I"m more willing to take up dry reading like wikipedia while also checking out youtube videos for that extra insight, and when I find them I"m stupefied why this wasn't in school because it seems like such a small investment in extra explanation for the huge help in understanding. So I've learned enough that way so that once he said helical polarization is possible, I immediately figured out a helix is chiral, the sugar molecules must be, there we go. Still kept the video playing for the watch time lol

Your professors wanted to ensure that you wouldn't get a physical understanding. They wanted you to have only a mathematical understanding. In general, they want you to have no physical understanding.

​@@christophergame7977 where did you get that impression from? During my degree only a couple of professors were fantastic at explaining intuitive explanations that go along with the heavy mathematics. Being able to do so is an incredibly difficult skill, it is why Richard Feynman was so revered through his lectures and red books. When you have spent decades studying a specific highly complex field, it becomes difficult to put your self in the position of a first year student, particularly when they come from all over the world with different educational backgrounds. However mathematics is a universal language and despite the complexity of harnessing the Schrödinger equation, it is still easier than relating the underlying concepts in an intuitive, but vitally still accurate, manner. > In general, they want you to have no physical understanding. Why on earth would this ever be their aim?

@beardedchimp Thank you for your response. I didn't say 'intuitive'. I said "physical". Perhaps I malign them? You say that only a couple were good at intuitive explanation. Why only a few?

@@christophergame7977 explanations are intuitive when we can understand them in the context of our physical reality. This is why he used physical pasta to help our intuition. > Why only a few? I thought I had explained that? It is an incredibly difficult skill, hence the revere for Feynman's public speaking. I can give a funny example, my quantum mechanics lecturer was Jeff Forshaw. He was great at giving physical, intuitive examples of systems that are fundamentally non-intuitive, but it still helps. He had to unexpectedly move to CERN for a couple of months and was replaced by his former student. The contrast was stark, he went between using far too advanced mathematics and concepts to patronising us explaining simple concepts we knew at 13. I remember coming out of a lecture and telling some friends that I felt bad for the guy, he clearly lacked experience in public speaking and conveying complex information, Forshaw had put him in a difficult position half way through the year. That man was Brian Cox. When I first saw him doing work with the BBC several years later I was shocked, I thought to myself "Wow! He clearly worked hard and learnt a lot from his early lecture disasters". It is a skill, it is easier for some than others but more importantly it takes hard work and effort which is difficult when you are under pressure to publish papers.

@beardedchimp Thank you again. Yes, now I get your point. It's hard for them to present a physical understanding, so they just give up trying. I'm not so sure. I think perhaps they gave up trying to get a physical understanding themselves, so they didn't even try to present one to their students: maths without physical understanding has become their nature?

Can I ask you a dumb question? When he says polarized light is a superposition of two circularly polarized light waves pointing in opposition directions, does he mean literally just two? Or, like, dozens or thousands that cancel each other out that way? Why would they travel in pairs?

@@TristanCleveland i think we're starting with linearly polarised light, so we have that as a firm statement. From there that could be split up in all sorts of ways actually. It's just for this experiment, because of the handedness of the molecules, rotationally polarised light is the relevant way that the light is affected. The counterclockwise and clockwise aspects of the linearly polarised light are affected differently. Seemingly you could make up any number of different pairs (or other symmetrical sets) of subdivisions of the light wave, but they wouldn't be useful for understanding what's happening here.

@@TristanCleveland in the end the thing is the field and the substance it overlaps with, not the wave. The wave is merely a description of the movement of that field, and you can describe that movement in all sorts of ways as are useful to you and accurate.

Yup a tea genius in physics, and gifted teacher. It's rare.

@@JohnGottschalk I hope I got that right. The wave is just a description of a field, as to my understanding to make a field "visible" to the human mind it has to have a "material" property like a point moving through space - wave. Am I right? And out of this construct one can build the explanatory construct of different waves "creating" the sum-wave of the "visible" light, correct?

"It's genuinely unremarkable."

It was genius. He's making it seem really simple, but I'm sure I'm not the only one who made the reasoning mistake he explained in the beginning.

We need a Steve Mould but out of context

Watch what happens if I turn this _pastor_ upside down.

He made a video about that already

Or he could have added an equal amount of L-Glucose and had no rotation of light. He seems to ignore that D-Glucose has a levorotatory form in L-Glucose.

l-Glucose was once proposed as a low-calorie sweetener and it is suitable for patients with diabetes mellitus, but it was never marketed due to excessive manufacturing costs. The acetate derivative of l-glucose, l-glucose pentaacetate, was found to stimulate insulin release, and might therefore be of therapeutic value for type 2 diabetes.[3] l-Glucose was also found to be a laxative, and has been proposed as a colon-cleansing agent which would not produce the disruption of fluid and electrolyte levels associated with the significant liquid quantities of bad-tasting osmotic laxatives conventionally used in preparation for colonoscopy. I thought, honestly that was a fatal mistake to eat much of that.

I found this explanation to be fascinating but kept waiting for the corroborating demonstration of the L-glucose case which sadly never came. But wait. Wasn’t he using sucrose there?

I worked for a decade and a half in sugar mills as a "Sugar Chemist"/Lab Technician. We did indeed us polarimetry to determine the amount of 'sugar' in the crushed cane juice at the start of the milling process and the processed raw sugar at the end. We also had a process to determine levels of fructose and other "reducing sugars" by measuring the angle of light bent to the left (levo-rotary).

But where did the levose go? Why isn't it 50/50 spit in the sugar he bought from the store?

l-Fusilli is indistinguishable in taste from d-fusilli, but cannot be used by living organisms as a source of energy because it cannot be phosphorylated by hexokinase, the first enzyme in the glycolysis pathway.

Hrm, so is the superposition of l-fusilli and d-fusilli just tagliatelle? 🤔

These are the trully interesting questions that we need answered! Not this bogus about right-handed light. Everyone knows light doesn't have hands!

s-fusilli* and d-fusilli :P or l-fusilli and r-fusilli... can't mix them or the pot will explode...

@@Taricus Handedness of molecules in chemistry is actually notated by D-L or R-S, not D-S or R-L

Thanks!

Because right-handed molecules don't fit on left-handed "slots", and as far as nature is concerned, they are completely different molecules

The above explanation is correct, differently oriented molecules fit into different molecular receptors in the body. Hence the weird 'double personality' of otherwise identical molecules.

A large part of the reason is that many/most molecules in biology, are chiral. And therefore can react differently to the different enantiomers of a molecule.

@@franchufranchu119 I vaguely remember reading somewhere that certain molecules when encountered in the human body (perhaps 'biologically' would be better) have a consistent handedness, but those created in the lab (perhaps 'chemically' would be better) do not, and at the time the author wrote that, the cause was unknown. Have we figured this out yet? have we figured out how to 'artificially' recreate the handedness of molecules yet?

@@temseti0 They usually create both and filter out the undesired ones

Don't need a video for that you just explained it perfectly here. wow.

I remember vividly in 2005 when starting my degree, my optical physics lecturer was explaining polarisation along with some mathematics. As the lecture went on he would stop for a second and place a strip of sellotape (scotch tape) onto the overhead projector. Each strip was at a slight angle so that they only overlapped at the centre. Finally he placed another polariser on top and it projected a beautiful ring of colours, while in the centre white light shone through. It was a beautiful example of polarisation and he used it to teach us how liquid crystal displays worked. Funny enough this was in Manchester where another physicist got the noble prize for isolating and characterising graphene using sellotape. Amazing what you can learn and teach with a bit of ingenuity and some sticky stuff.

Oh, I can see that we don't know the same people..lol

You obviously never had "feelings" for lasagna

Fine, have your thumbs up!

​@@SteveMouldkzbin.info/aero/PLElOK3eZ5OO9uhBTi2aK1ifjDBhTVe2bu&si=HST3uOSmUOwQoN2H

​@@SteveMouldkzbin.info/aero/PLFre9LVBTdQpdfWRktdufJu3mb0OQHko1&si=STmEWhVDpIPNgOaX

holy crap

True! But I was disappointed that the word "chirality" was absent.

A brand new sentence in the universe

Looks like something in the sub-radar range i2.wp.com/yatebts.com/wp-content/uploads/2018/11/Frequency.png

@@gregbernstein9126 Lol!

@@gregbernstein9126 Thank you! I was about to look it up :-D

Tsgphysics.mit.edu/pics/T%20Polarization/T8_2.jpg shows an image of a polarized tube of fluid which gives a spiral appearance. Odd since the wavelengths of visible light are much shorter.

You'd be shining through a prism in the center while the outside would have light diffracting in all sorts of directions. You would need a stepped vase if you will.

I'm pretty sure you can see that with a piece of plastic (like a plastic ruler)

I think I get what you're going for and I was wondering the same thing but I think its not the volume of sugar water that matters but its concentration. If so, changing the shape of the vessel doesn't matter. Instead of using water which is the universal solvent, it would almost need to be an optical gel or something that more capable of stratification. *I haven't actually experimented myself so I'm speaking purely about expectations and willing to be surprised.

@@MrCwildeman the concentration does matter, but so does the distance through which the light has to travel. Look up 'specific rotation' on Wikipedia if you wanna read more about this

@@samj6837 Thank you. That actually unravels my understanding of Steve's explanation though. For refraction, the speed of the light changes at the interface not continually through the medium. For volume to have an effect on the angle of twist, one component of the superposition is continually being slowed down within a homogeneous mixture. That sort of goes against the light slowing logic of refraction right? I'll do more research on my own, but discussion yields better quality results!

Have you ever used polarised sunglasses? I think that are popular with skiers, because light reflected from the snow is partially polarised and they are great bloacking those reflections, but they may have weird effects when looking to the screen of your phone, depending if your phone has a LCD screen or an OLED/AMOLED one.

why ?

*say instead see, for anyone confused.

I dunno why interests and degrees have any connections at all

@Mr. H looks like some rote memoriser got butt hurt

@Mr. H must be nice

You, sir, are a genius!

Oh my god that's brilliant. The wavelength is a match, so... probably?

FBI wants to know your location

@@simonvetter2420 haha no you need The polarization to be oriented vertically/horizontally and the microwave doesn't have a polarization filter so overall net-value is zero, the comment above was purely for the sake of good humor

A microwave oven works by passing microwave radiation, usually at a frequency of 2450 MHz (a wavelength of 12.24 cm) That's probably to big a wavelength for the pasta to have a strong effect 😞

Refractometry has little to do with polarization of light, but I think you understood that. The idea of light traveling more slowly through some mediums over others and how that bends light is briefly explained here.

Photon C: What the hell is a "day"?

Technicaly they are not photons they are oscilations in the magnetic and electric field. Together they make a photon(superposition of those 2)

@@Bishox Technically, it's spelled technically. Also, the comment you replied to was technically a joke.

@@imveryangryitsnotbutter Proton D: Ahh! Talking protons!

Wave-particle: what are these old timers still doing here

That's fascinating and I'd love to see that! That said, slightly unfortunate that it's just called L-dextrose. Sinistrose sounds so much cooler.

@@clockworkkirlia7475 Sinstrose; when the devil wants sugar. Fun fact (which you probably already know, given your "sinistrous" suggestion): dexter is Latin for right and sinister is Latin for left. Since left-handed people were considered "of the devil", sinister became a word roughly meaning "evil". And the word ambidextrous simply means "two right hands". Since right hands were "not of the devil", I guees they just thought it sounded better to call you right-handed but twice as much.

@@trickytreyperfected1482 Furthermore, people who are bad at writing with both their left and right hands, are called ambisinister!

@@LittlePharma always wondered where the "two left feet" thing came from

I think it should be called Levose.

That is quite interesting. 🤓

Yes! Carvone in anyone's curious

I believe that the same applies to compounds in the oil in lemon and orange skin. Can't find he reference though............my organic chemistry is 50 years old!!! Stavros

Actually, all natural sugars are right-handed.

How does sugar rotate in terms of its electron cloud arrangement. Is it linear in solution. I can understand DNA has a clear spiral structure and coupled oscillators could rotate the polarization. Is it because glucose has particular position of OH in the ring.

I am afraid you are wrong here. I am not an expert, correct me please, but one thing is having stream of differently polarized photons (what you refer to as unpolarized - classical ensemble) and another thing is to have superposition of polarization (even with single photon). The difference is in how you create them - you either bounce them from known surface (but with mixed edges/planes thus the ensemble) or you produce or bounce them from unknown source which itself is in superposition producing unknown/superposed polarization... is that possible? I am not a physicist, but do not cut corners in those things, quantum things especially, unless I see good reason for it. Proove me wrong, please :) EDIT: ...and I got corrected - continue reading the responses ;)

@@firdacz Physicist here. He isn't wrong. If you had a completely unpolarized photon - a superposition of ALL polarizations - the net photon would not exist, since all the polarizations would cancel each other out. Isn't any fancier than that. Unpolarized light is always an ensemble.

@@MSpangeO I was confused, but after reading this, it actually makes perfect sense!

@@MSpangeO I am struggling a bit with your explanation - why would they cancel out? Electron can be in spin-superposition, does that cancel the spin? ...but I think I got a bit of understanding reading the wiki, that polarized light already is superposition (which is also stated in the video I think), therefore α | R ⟩ + β | L ⟩ and unpolarized would need that α and β be "in superposition" which is not possible, these are constants (complex numbers, right?), so single photon cannot be unpolarized, because it always is some superposition of left and right which itself defines polarization.

​@@firdacz You definitely have the right idea! Polarization is an intrinsic quality of light, just like spin is an intrinsic quality of electrons. The left/right circular polarization or x/y linear polarization are normalized axes from which you can completely define the polarization of a photon. For example, if I wanted to describe a photon polarized at 20 degrees to the x-axis, I would only need to describe the state | ψ > as a superposition of the | x > and | y > states, using some complex amplitudes α and β. I'm not sure exactly if a photon that is a superposition of ALL polarizations would not exist, per se, but really what it is is that a photon in a superposition of "ALL polarizations" is not a valid way to describe a photon's polarization, and I believe this is what ElderberryEnt was getting at. To quote Harry Nilsson, "A point in every direction is the same as no point at all". I suppose, in some sense, all photons are in a superposition of all polarizations, since you can arbitrarily define your x and y axes (provided that they remain perpendicular) to align with any linear polarization you want (and often we do in order to simplify calculations). If you're still a bit confused, try to describe a photon which is in a superposition of "all polarizations" using that bracket notation. | ψ > = a1 | α1 > + a2 | α2 > + a3 | α3 > + ... + an | αn > where (a1...an) are complex coefficients and (| α1 > ... | αn >) are polarizations along some line. Assuming we're in 3 dimensions, light can only be polarized in a plane. To describe linear polarization using bracket notation, we only need two orthogonal axes. Therefore, all we need to do is pick 2 orthogonal lines, call them x and y, and we can describe every polarization a1 | α1 >...an | αn > as a superposition of those two states, | x > and | y >. If you do some algebra to combine all the coefficients, you'll end up with a photon in a superposition of x polarization and y polarization. So, a photon in a superposition of all polarizations is really just a photon in a superposition of two orthogonal polarizations, as expected. And seeing as right and left polarized photon are just superpositions of linear polarizations (and vice-versa), you can describe circularly polarized photons in terms of linear polarizations and apply the exact same logic.

How was this commented before the video went live? 😂😂

SUGAAAH!

I would love for you to show people magnets can be used as gears. It is possible to create an entire transmission system with all moving parts suspended in a magnet field. Again no gears should touch but still push or pull depending on the set up. If you really cant make a design please ask me for one.

10:16 this is the smartest sentence I've heard this month

Are you trying to say that the light polarization is a phase angle between electric and magnetic component? Never thought that is possible.

Why can we assume that all molecules are oriented either upwards or downwards? Surely the light hits molecules in all kinds of orientations at all kinds of angles. But if some light was always blocked the solution shouldn't be as transparent 🤔

​@@koloblicin4599 Basically, the molecule slows down the light that travels through it, but doesn't absorb it (screws and pasta are opaque but a molecule of glucose is transparent). When a molecule is oriented perpendicularly or something, it just slows down both components equally, so has no effect on polarization. Under an other angle, it might have a reduced effect: for example the clockwise portion crosses the "helix" 21 times while the counterclockwise crosses it 19 times, and therefore travels a tiny bit faster.

Nice, I had wondered why it was called inverted, but never bothered to look it up.

After some digging, it looks like invert syrup is actually D-Fructose and D-Glucose: en.wikipedia.org/wiki/Inverted_sugar_syrup But, D-Sucrose rotates counterclockwise much more than D-Glucose rotates clockwise so the effect is a counterclockwise rotation: pubchem.ncbi.nlm.nih.gov/compound/fructose#section=Decomposition Apparently you can’t tell the difference between D and L Glucose by taste, but because only the D form is found in nature we can’t digest the L form. Apparently it’s marketed as an artificial sweetener as “Tagatose”: spinoff.nasa.gov/Spinoff2004/ch_4.html

Wow...good information

@@MrIanrocks Oh I thought I didn't need to point out it was specifically the D isomer since, as you said, it is the only one in nature. It is implied (much like the isomer for all aminoacids). We tend to leave information out when it is implied.

Like how cosine is just a 90 degree phase-shifted sine and used together provide the coordinates of a circle.

Wait till you hear the one about sinister people!

If I remember right, there is a sugar that is normal calorie count when it's one hand, and almost no calories when it's the other hand.

It's even a literal translation. Chir (hand) al (ed) ity (ness), the first part Greek and the next two parts (Anglified) Latin.

@@laurendoe168 I think this is the case for glucose. It needs to be produced synthetically though, as all known lifeforms that produce glucose produce it in the same handedness. Then in order to make it unusable for our bodies, you need to feed the synthetic creation (which will typically be an even distribution) to an organism that can process it, and once that's been done you're left with the other version. That can then be sold off as low calorie sugar. As I understand it, the chirality does not affect the taste receptors, so it's a perfect substitute for taste, feel and looks, but due to the extra steps in creation it's going to be quite expensive.

@@MrMartinSchou Thank you for both confirming what I seemed to recall, and offering more information about it.

@@MrMartinSchou yep. The first thing I thought about when he said the molecule handed and the you can't move it to make the mirror was but why can't the mirror just form? There is not way we can separate molecules based on that can we... Oh right sugar is organically made!

Not true. Fresnel published a paper about it in 1825 when Pasteur was still 3 years old. Fresnel, A. J. (1825). Sur La Loi Des Modifications Imprimees A La Lumiere Polarise Par Sa Reflexion Totale Dans L'interieur Descorps Transparents. Ann. Chim, 29, 175-87.

@@SirPhysics Wikipedia says "This was the first time anyone had demonstrated molecular chirality, and also the first explanation of isomerism." en.wikipedia.org/wiki/Louis_Pasteur#Molecular_asymmetry Does Fresnel's paper supersede Pasteur's work?

@@JimC Yes, and the work of others does as well. Also from wikipedia [1]: "The rotation of plane polarized light by chiral substances was first observed by Jean-Baptiste Biot in 1815" Pasteur was the first person to suspect that 'chirality' (it wasn't known by that name until Lord Kelvin coined it almost a century later) was a result of molecular structure, not the first person to observe the effects of chiral materials on circularly polarized light. In fact, in Pasteur's time chiral molecules were known as optical isomers specifically because the effect they had on light was already known. [1] en.wikipedia.org/wiki/Chirality_(chemistry)#History

@Richard Lockwood Yeah, the shit scientists had to deal with back then was insane. If you ever want to a story of scientific tedium, look up how Henry Cavendish did his experiment to test Newton's Law of Universal Gravitation. It's hard to imagine that someone managed to directly measure the gravitational force that two metal spheres exert on one another before 1800. It's such a shame that the history of science often isn't taught alongside the science. Knowing where these ideas came from and how we figured shit out is really cool.

@@SirPhysics just started reading "The Structure of Scientific Revolutions", on science history. And holy shit, yeah we should learn this before being let out into the world.

Thanks!

It does, and if you get racemic mixture it should not really affect the light much... would be cool to test it.

Please test this, Steve

The wiki page of normal glucose says: "The earlier notation according to the rotation of the plane of linearly polarized light (d and l-nomenclature) [...]" So I guess it does indeed!

If you have the mirror image of right-handed glucose, you would have the exact same amount of light rotation but in the opposite direction.

Glucose turns left by some amount and fructose turns right by some higher amount (or it is the orther way around but it does not matter) so that when in sucrose (kitchen sugar, in which they are 1:1 ratio) they turn the light to the right, but if you have pure glucose and fructose you can play with concentrations and make it turn whichever way you want by the amount you want, its pretty neat

this also made me giggle to.

Everyone hail the giant spaghetti monster !

*Pastah

Whoah that is pretty strange!

2:32 "If I put this cylinder full of sugar water between the monitor and the filter..." *monitor > sugar water > filter > camera* I initially thought (I think you do, too) that he was placing the filter underneath the cylinder, like so: monitor > filter > sugar water > camera I struggled with this for about 45 minutes before going back and listening more carefully.

@@88fibonaccisequence I also thought that but then saw how easily he was rotating the filter. However, Nigel here is talking about the quantum weirdness effects of a *third* filter! The first filter polarises the light. The second filter blocks the light due to being perpendicular to the first. But then the third filter... shows light again?? So, did the second one really block it? What's going on here?! I'm aware about this phenomenon but don't have any idea how it happens.

Doesn't he mean a superposition of all states of polarisation?

@@dielaughing73 nope, if you had a true superposition of all possible polarization then everything just cancels out. Unpolarized light is a bunch of photons, each polarized in a different way, so that on average the net polarization of the beam is 0. Thats what op means by statistical mixture. The way you treat them in quantum mechanics is also different than a superposition: roughly speaking a superposition can be seen as a vector whereas a mixed state can be seen as a square matrix

Yep, it's simply like a _distributive property_ for interference of waves. (a+b)+(a-b)=2a where: [a] vertical polarized wave [b] horizontal polarized wave with -pi/2 phase in respect to [a] [-b]: horizontal polarized wave with +pi/2 phase to [a], which is the same as inverse of [b], that why the minus sign

Almost - amplitude would be √2 of the original amplitudes

Imagine a circle of radius 1. Any point on the circle is a superposition of an x-coordinate and a y-coordinate; the superposition is chosen such that the amplitude is always 1. So, for the point on the circle at 45°, you have 1/√2 in the x and 1/√2 in the y. The same applies here, but for visual purposes it's better to display all the waves as having the same amplitude because mathematical rigor isn't the goal here, just general understanding.

This is next-level trolling

how were you able to read that ? I just couldnt distinguish what those numbers were !

Nice spot!

I was able to read it by putting the video in the highest quality available and looking at the screen at a weird angle

Beat me to it.

yeah he sometimes switches between superposition meaning addition of to waves and average of two waves, but it doesn't really change much since their just constant multiples of each other

pestering*

@@TS-jm7jm I think he was referring to the pasta used in the example...

Tristan smith wooosh

@@martin-__- degenerate

@@andycrask3531 ah, i see what you mean, i hate puns.

nvidia RTX: hold my FPS

Reality: I have held them for a month now, when are you finally done?

The newest set of hardware has got to a point where the ray tracing light can be refracted through a virtual prism at seemingly infinite number of times without an FPS drop, in real time, it separates the white light into all of the possible colors in the light spectrum. As well when light passes through colored glass it passes through filtering only that color in the lighting source; it's able to both bend and refracts the light, likely able to reflect the light as well.

@@なかった事に無言フォロー I'm not sure what you are talking about (I am interested), but computation will always have cost. The way RTX works is they are using a machine learning (artificial intelligence) to _guess_ the results based on tracing only a 'few' rays. The results are just an approximation that happens to look good enough most of the time. - I don't know of anything real-time that surpasses that.

Grammatical error meant your and when I meant extremely knowledgeable person I mean you are an extremely knowledgeable person! I’m just an avid learner lol and I can’t wait to keep learning from all of your videos!

Broadly speaking, superposition is not a quantum phenomenon; it's really just a question of which basis you're expressing something in. I think superposition and the uncertainty principle are two entirely classical principles that people sweep into quantum mechanics because of the weird implications that they have when brought into a quantum mechanical context.

The diagrams and animations draw on our intuition of classical fields, but molecules and light are quantum systems. The quantum states of light are the polarisation states, and they combine into superpositions in QM exactly as he described, so I think the references are fine. That said, the one you noted at 1:37 is an exception: classically, unpolarised light can be referred to as an 'incoherent superposition', but in QM it would be a mixed quantum state, which is a very different animal to a quantum superposition. But it's a pernickety technical point, and this isn't a pernickety technical talk. He's put together a wonderfully clear explanation, and I'm looking forward to using it for teaching :)

Yes. As already stated, light here is in a mixed state, which is nothing like a superposition of two pure states. The classical/quantum distinction is a bit fuzzy for photons, but i would say this is more of a classical effect than a quantum one (that is, you will not get any trickery like entanglement out of it).

Did u study it in school?

I developed my own tricks to study stereochemistry easier, and they are never wrong, it always works😃😃. By the way, i had to study it in my 11th class but i am still learning more of it, it's interesting right?

@@daphenomenalz4100 Yeah around my 10th grade; was part of advanced coaching, so got introduced to these sooner.

@@daphenomenalz4100 Yeah as I kept learning, I realized some tricks and had them noted down. I must say though, organic chemistry is a pleasure to learn when there's a lot of discipline, as there's a lot of linked topics at play. Glad to say these were inculcated into me nicely by a really good teacher :)

It would be nice if you could actually share your tricks 😉

And he had a scratch.

Biscuits (crumpets maybe) and tea in between takes obviously.

Could be a skin flake

@@mattm7535 pppfffttt we all know he nails it in one take. Stop playin'

You can flip a right handed bolt in the 4th dimension to turn it into a left handed one. (Well, you can’t because your 3D world sucks, but you get the idea)

@@cezarcatalin1406 I'm sorry. My engineering degree is only valid for 3D... :(

@@cezarcatalin1406 hey it's the razzle dazzle Dorito