Deriving the Dirac Equation

Hey all, thanks for checking out this video! :)
While reviewing the video just now, I realized I probably should have been more clear about covariance and contravariance. This affects the sign of the momentum terms (more generally, the space-like terms), and is a perennial source of dropped minus signs 😅 The plus signs at 13:20 are due to using the contravariant Dirac matrices, three of which which absorb the minus signs, see the Wikipedia article “gamma matrices” for more info.
Anyway, the main idea I hope you’ll take away from this video is that the anticommutation relations for the Dirac matrices arise from taking the square root of the mass shell.

The "I'm letting the squares breathe..." was genius for geometrically visualizing variables!

Dirac was known for both the brevity and precision of his speech. At a conference he was lecturing and writing at a blackboard. A member of the audience said at the conclusion of Dirac's presentation, "I don't understand your equation in the upper right." Dirac said nothing and returned to his seat at the table with other lecturers. After an uncomfortable silence, the conference moderator asked, "Mr. Dirac, are you going to answer the man's question?" Dirac: "It wasn't a question. It was a statement."

A thousand jargon-filled wikipedia articles could not have given me the clarity I now posess thanks to this video. Thanks so much

The reason the coefficients don't commute (so the opposite breathing squares cancel out) and why the coefficient squared are negative numbers, is because a spinor is a unit quaternion! In fact, the nature of spin is a bit less mysterious if instead of using Dirac matrices we use quaternions, for rotations on a 4D hypersurface :)

When the math is shouting “PARTICLES AREN’T FUNDAMENTAL, THEY’RE EMERGENT, YOU’RE JUST DOING EPICYCLES AGAIN”

Straight-up the best physics videos on youtube

eigenchris's "Spinors for Beginners" series is a really good introduction to, well, spinors for beginners!

Wow this lesson is much better than in Oxford or Harvard. Very interesting to see visualisation of solution of Dirac equation to compare with Klein-Gordon and Schrodinger equations. Also very interesting to see how do the wave functions in the bispinor responsible for spin up, spin down, and antimatter affect each other

The teacher I had for QFT was one of the best teachers i ever met, and yet, this is so much more insightful then what he ever managed on a blackboard. The visualisation is genius.

I think this is the clearest picture of Dirac equation and I have minimal training in math and physics 😊

Wow. I have devoted all of my time to getting into GR and have only had a basic rundown of QM but have wanted to get into the more interesting QM stuff for a while. You did a great job and I love hearing your excitement for introducing new ideas. That was perfect and felt so clean. Great stuff!!!!

Fun fact. Back in 1972 I was taught some mathematical physics by the late Joe Moyal. Joe was invited by Dirac to Cambridge during the World War 2 to discuss Joe's work on statistical foundatiions of quantim mechanics (there is a 1947 paper with Bartlett and Kendall which also deals with the issues). Joe met Dirac and I can say that I have shaken hands with someone who has shaken hands with Dirac.

This sort of accessible education will prove to be revolutionary.

I never heard of this way of deriving the equation and now the matrices seem so much more understandable... Congrats dude, you just did the impossible of explaining all of this stuff I tried to understand for months

Brilliant content! Looking forward to the next installment on spinors!

Absolutely terrific :)
btw, here's a tip for everyone who sees this: geometric (Clifford) algebra really helps understanding these spinors better (and also space-time in general).

Thank you so much! I was reading the book “The strangest man” by Graham Farmelo, and your video gives an in depth looking into Dirac equation. This let me give the following parallel from a basic math concept to understand Dirac equation.
While Cartesian coordinates, introduced by René Descartes, provide a structured way to map points in space using two or more axes, the Dirac matrices, part of the Dirac equation in quantum mechanics, offer a profound mathematical framework for describing the behavior of particles in spacetime.
Just as Cartesian coordinates allow us to pinpoint locations in space with precision, the Dirac matrices enable us to describe fundamental properties of particles, such as spin and angular momentum, within the framework of quantum mechanics. Both systems provide a means to understand and navigate complex phenomena: Cartesian coordinates in the realm of classical mechanics and geometry, and Dirac matrices in the intricate domain of quantum mechanics.
In essence, while Descartes paved the way for understanding space in terms of ordered pairs of numbers, Dirac expanded this notion to encompass the intricate fabric of spacetime at the quantum level, offering a beautifully intertwined perspective on the mathematical underpinnings of the universe.

I recently started my postgraduate physics studies and one of my modules (which is by far the hardest one for me) covers the Klein-Gordon equation and (now) Dirac equation. The reading material and textbooks for most of the part pretty much assumed the reader knows how to derive certain things and/or where it comes it or what it represents etc, which is why I'm finding them incredibly difficult. Your videos have literally saved my life by providing the much needed intuition for these topics. Keep up the amazing work!

Excellent presentation. I've seen other videos on the Dirac equation but this is the first one that makes me feel like I (just about) understand it!

I was watching Alexander Fufaev video on the Schrodinger equation (He gave an excellent explanation), and he mentioned Diracs equation as the next thing for relativistic SE.
I'm happy to have found this. It's been years since I finished.
So here I am learning new things and brushing up the old, to enable drawing out something new if I persist just enough.
This is excellent and widened my understanding but raised further questions too.

This is an excellent video! It does a great job making the solution feel intuitive!

You do a really nice job explaining these difficult concepts both formally and casually. And your Manim skills are impressive!

Been waiting for this one since your last video! Awesome work!

Thanks for such a clear explanation. Can you also elaborate on why A,B,C,D matrices should be 4x4. Like what should be motivation behind that to choose 4x4 instead of any higher like 16x16 or so?

Fantastic! Looking forward to spinors video :)

Thanks for clearing everything up!❤

This is fantastic. A secret closely guarded by academics has been simplified so that even I can understand it with only a BS in Engineering. Thank you
I need to watch more on spin as it too is a kept secret usually presented and discussed in baloney classical ways. Just a glimpse here helped already.
I would love for someone to simplify Hilbert space as it too is slung around a lot without explanation.

Just thank you, as clear as it can be

I know the Dirac equation but never really saw it being derived before. Either I was incredibly blind in my education or my educators hand waved everything and I struggled from there. These videos are opening my eyes more than my entire journey through undergrad and honors.

I said out loud "Ooh!" excitedly when i saw this video as i was working on visualizing the Schrödinger equation for the Hydrogen atom!

I found the squares (and the whole derivation) breathtaking

The requirement to complete 2 360 degree rotations in order to reset reminds me of mobius strips.. I'll need to watch this lovely video a few times. Subscribed.

You are a treasure! You just put so much into perspective for me wrt spin states, what the equations represent, how they come about. Great video! Thanks

So beautiful. You didn't even get to the half of the video and already all the mystery unveiled. Why nobody told me about this when I was studying theoretical physics is beyond me. It is both obvious and simple, and derivation is logical and could not be otherwise. To me the commutation relations were always introduced without any explanation or big reason other than this makes thing work, but not really. All the implications later are just simple logical conclusions (they might be hard to derive, but there is nothing mystical about them).

Fantastic explanation! Loved the visualization of the breathing matrix and the colour coding of the terms to make it immediately obvious that the coefficients don't commute and the need for Dirac matrices. And then adding the flag to illustrate the double rotation.. Fantastic! Thank you for your time effort on this video

God tier explanation, can’t wait for more stuff

Thank you for another great video :) Cant wait to learn more about the topic.

Well, Diract went a different direction. When I saw those constraints, my brain immediately went "quaternion"

Great explanation of complex subject.

I'm astonished. This is beatiful

I love these videos! Great explanation and visualization!

was a very nice video btw :). and the quaternion modification, i just figured it is easier to call the non commutative root of plus 1 "u" u*u=1 , u*i=i i*u=-i ect.. then it works out, cleaner than special rules for minus one or one, where you have to basically write the same thing anyway.

Informative and concise, great video 🤍

It's also worth noting that the matrix approach is entirely equivalent, mathematically, to the other ways. It's not just that matrices happen to solve this particular problem - matrices form a group, and that group is isomorphic with any group that obeys the same multiplication rules. So not only is this "a way to do it" - you also don't lose ANYTHING by doing it this way.

Soooo superbly made😍😍

So beautiful tears came to my eyes. Please update to a framework based on Clifford Algebra or Geometric Algebra rather than the most commonly used framework. Thanks for your service!

Keep up the good work.

Okay , so I thought Dirac already knew about spinors before combing SR and QM. Thanks to you , now I understand that he might have went for them after finding these relations of A , B , C and D.
That's nice because sometimes I feel like I should go for a masters in mathematics rather than physics. I am gonna go and be happy with physics for sure now because of this video.

Perfect, thanks!

This was awfully well timed, we just saw Dirac's equation last week in our quantum class 😅

Wow!! Really amazing explanation! Thankyou very much

The way the commutation relations came out from x^2 = E^2-p^2 was so cute. Also the anticommutativity is very reminiscent of geometric algebra and specifically space time algebra.

Once again, THANK YOU!

Wonderful!!

I'm an undergrad physics student and you made this look incredibly easy. I'm sure I don't really understand the geometry of it but I have a way to imagine the dirac equation now, thank you.

great explanation and diagrams!

Good work

VERY cool. Thanks for this!

Simply a great video !

Wow though I have just studied 1 year of math at the college level I understood the gist of this well narrated video. Good job!

Brilliant!

This is beautiful.

Amazing video! Thanks!

Richard: 10:39
My physics prof: I'm gonna pretend i didn't hear that.

I loved it! Awesome!

That was surprisingly quick. And you have indeed done a decent job ;).

brilliant !

man,this equation is a kind of awesome awesome art! paul dirac is a genius and one math artist! awesome!

I have zero background in physics and was just listening out of curiosity. But I know linear algebra pretty well and when you said "non-commutative multiplication" I yelled, "they're matrices!" Ha!

This is completely ad-hoc reasoning that it is amazing that it works.

Amazing video! I do have a question about the final form of the equation. Since you are multiplying bispinors by 4x4 matrices, does that mean that the “=0” in the dirac equation is the “zero bispinor” or is it literally the number 0?

Great job dude

Yes, the pleasure of dealing with "highly non-trivial objects"!

it's here! hurrah

i leave it as an exercise for the content creator to look at the differences between the gamma matrices and these types of quaternions with a non commutative real unit.

Thank you!

Beautiful

First, excellent video. Second, one technical point at 14:50 or so, Psi 3 actually corresponds to spin DOWN positron and Psi 4 to spin UP.

You did good!

At the time 12:13 , this equation can only hold as an operator because left side is a matrix and right side is a constant. This means that actually what we are find is only can be satisfied in quantum mechanics and does not any analog representation in classical mechanics.

🙂🙂 , Complimenti!

Thank you

The constraint of 1st order space and time dependence eventually lead to the Dirac field/"wavefunction" being bispinors, signifying spin-1/2 (fermion). Is it possible to come up with an equation 1st order in space and time, for integer spin fields (bosons)? Is the Klein-Gordon equation the most "elementary" equation for bosons?

Amazing explanation and easy to follow, something that I was not expecting when considering how to derive the great Dirac equation. Question (I'm not familiar with Klein-Gordon equation): what is the motivation to get a first-order equation? A second-order equation incidentally does not predict spin?

Far out Man, that 'was' real trippy! :-)

Very nice. I almost understood this, but I don't get what the deal is with the minus sign of the momentum operator. It's usually in QM p_x = - i \hbar \partial_x .
But you used initially p_x = i \hbar \partial_x with the plus sign, but write in the same line in the beginning at time stamp 1:35 \hat{p} = -i \hbar (\partial_x, \partial_y, \partial_z). Then, in the end, in the Dirac equation it's always p_u = i \hbar \partial_u . Is the trick somehow that the imaginary i should be explained from taking the square root of the metric tensor, or signature (+---) or (1,-1,-1,-1) which makes (1,i,i,i) ? I dunno. This is a bit confusing to me right now, I must have missed something.

Such a good video. I only wish it was formulated in terms of geometric algebra. One of the major reasons spinors are trippy is because they're usually all about exact coordinates, while for the purposes of explanation it's possible to split it into two parts: "thing where squares are -1, and AB = -BA, and their algebra" and "how to represent numbers of that algebra as 4x4 matrices to do an actual simulation on a computer". You can't neither draw nor get geometric meaning out of numbers of 3D spacetime algebra anyway.

Really good. Now if we could just come up with a way to simplify this by cutting out two of the three spatial dimensions.

Is it possible to "Dirac-ify" other differential equations in physics? The wave equation is to the second power; are there any mathematical objects we can use to make the wave equation first-order in time?

When you hit the bit with the anti-commutativity and the squaring of A,B,C,D to 1,-1,-1,-1, I thought "Hey, isn't that a rotor?". A would be the scalar part, and B,C,D the bivector parts.

if you modify the quaternions slightly, that is you fuck around with 1 and find out, then its all good as well. what you need is simply to modify the real unit multiplication such that if you multiply the real unit by a non real unit A=+-1 B=i,j,k such that if A*B, A=1 and if B*A, A=-1, then it satisfies the same constraints, basically you make 1 non commutative and you are good to go.

If you stare at the gamma matrices for a bit, it's clear that the last one (gamma 3) is the runt of the litter compared with the beautiful symmetries of the first three. That's probably a hint that we're not quite right in our interpretation of Ma Nature here.
I think I read that the gammas can be decomposed into spinors and perhaps that makes the ugliness of gamma 3 go away?

Great video! Spinors make my head spin. I really can't grasp why these weird, quirky mathematical object describes the universe so well.

Great explanation, and helpful visualizations! However, I think a motivation for the third principle of the Dirac equation would have been nice. Now it was just stated, for no obvious reason. (I know the motivation if it myself since before, but other people may not know it.)
A thing that I'm wondering-at 7:31 when you write out the equations for A, B, C and D, this strikes me as equivalent to the equations for the basis elements of the quaternions, so would it be possible to write the Dirac equation with the quaterion basis elements instead of the gamma matrices, and letting the wave function be quaterion-valued instead of a vector field?

Very good exposition. I was surprised I could follow it as well as I did. It even allows one to play with the matrices to confirm the results for oneself.
I never understood it before.
The Wikipedia exposition, by contrast, I find very difficult to follow.

Anche qua la Fisica ,( ci sono le numeriche o variabili della Fisica ,No!)non c'entra nulla , è una ricerca che è già stata esposta, dalla Dirac Converse , riguardo gli andamenti del ciclo di vita del prodotto,nelle sue varie fasi, durante una linea di produttività. Ciao ciccino un bacione! Può servire la successione di equazione per il riscontro di un andamento o processo di distanziamento. Questo si è vero! Bene.

even the way you have the visuals in motion = NB ... ty
that 4x4 matrix breathing is important for understanding reality.

basically if you replace 1 in the quaternions by a non commutative root of 1, that is what i said by a multiplication rule that picks out either 1 or -1 then we are all good.

Doing this with geometric algebra would obviously be much more convenient and intuitive. I hope it won't be long until we see that being the normal way of doing it.