Thanks!

YOU ARE TOO DUMB TO JUDGE WHETHER SOMEONE IS BRILLIANT, MATE. BECAUSE SHE DOES NOT RECOGNIZE THIS. SHE HAS HER LIMITS TOO.

This is great, glad we could help!

This is great to hear! :)

Glad you like it, and good luck with your learning!

Thanks for your kind comment, and glad you enjoy it! :)

Glad you like it! :)

Thanks for your support!

Glad you found the explanation useful! :)

Thanks for watching, and glad you like the videos!

Glad you like it!

Great you liked the derivation! :)

Thanks for your support! :)

Glad to hear, and good luck with your exam!

Great to hear this! What university are you at?

Thanks for the feedback! We always try to balance the amount of content with the length of the video, and to keep them in the range 10-25 min we have to present the topics in a somewhat piecemeal fashion. However, the idea is that each video is part of a larger whole, with relevant links in the video description and also in the corresponding playlists. In this particular example of angular momentum ladder operators, we use them thoroughly in the related video on angular momentum eigenvalues, where you can start to see their importance: kzbin.info/www/bejne/qmjbZ6mqa92ed6s

They are used for exactly the same reasons as in the harmonic oscillator, which is to factorize the operator you are trying to find the eigenvalues for. In the harmonic oscillator, one factorization works of the form A*A+E. For angular momentum, there are three terms J^2=(J+J-+J-J+)/2+J3^2. Whenever an operator can be factorized in terms of one operator and its adjoint, one can find the eigenvalues purely from algebra. This is very powerful and is why they are employed here. It is just more complicated here because the factorization is into the sum of three factorizations rather than just one. But it can still be done.

This is great to hear, thanks! :)

Glad you like it! :)

Glad you find it helpful!

Yes, for that what we need is to show that mu=m*hbar and that lambda=j(j+1)*hbar^2. These two results are demonstrated in the video on eigenvalues: kzbin.info/www/bejne/qmjbZ6mqa92ed6s I hope this helps!

Glad you like it, and thanks for watching!

Glad you find it clear!

Glad you like it! :)

We are planning a full series on angular momentum, including addition of angular momenta, so we should hopefully get to Clebsch Gordan coefficients soon!

@@ProfessorMdoesScience This will be AMAZING ! You guys are turning in reference in QM.

Thanks!

Thanks!

You can find the link in the video description, but it is this one: kzbin.info/www/bejne/qmjbZ6mqa92ed6s

Glad it was clear! :)

You are correct that J^2 is not a vector, it is the scalar product of a vector with itself, which overall gives a scalar. We could write in a variety of ways (e.g. J (dot) J, J1^2+J2^2+J3^2, etc), and we use the shorthand notation J^2 as it is one of the most commonly used ones. I hope this helps!

Glad you like this!

We do! You can find the details in this video: kzbin.info/www/bejne/qmjbZ6mqa92ed6s In general, if you follow the videos in the order in which they appear in the various playlists, then we build the knowledge step by step: kzbin.infoplaylists

@@ProfessorMdoesScience ah that was a struggle for me too. i think you have ladder operators before the angular momentum eigenvalues video in the playlist. At least that's the order it shows up to me.

Thanks for your continued support! :)

Glad you like it! In principle we could label kets in any way we find convenient. When we have eigenkets, we typically label them using the associated eigenvalue. For example, if we have an eigenvalue "a" for an operator A, then we write the associated eigenket as |a>, and the eigenvalue equation would be A|a>=a|a>. In the video, the states are simultaneous eigenkets of two operators (J^2 and Jz), so we use the two corresponding eigenvalues for the labels, separated by a comma. Specifically, |lambda,mu+h> means that this is an eigenket with J^2 eigenvalue lambda and with Jz eigenvalue mu+h. I hope this helps!

@@ProfessorMdoesScience Wonderful explanation ✨! Thanks you a lot!

Glad you like it!

The norm of a vector (ket) is related to its length, calculated using the scalar product of the vector with itself. We introduce the basics behind these ideas in this video: kzbin.info/www/bejne/nnvSiIBvn8tjnbc I hope this helps!

I also don't see how J₊J_ =J²-(J_3)²+ħJ_3 is derived

For the derivation of J+J-, the first step is: J+J- = (J1+iJ2)(J1-iJ2) This simply uses the definitions of J+ and J- in terms of J1 and J2. The next step is: (J1+iJ2)(J1-iJ2) = J1^2 + J2^2 + i(J2J1-J1J2) This is obtained by multiplying through the two terms in the left hand side, just like you would (a+b)(a-b) = a^2 + b^2 + ba - ab, and note that J2J1 is not equal to J1J2 as the operators don't commute. The next step is realising that the last term in the expression above is simply the commutator of J1 and J2: i(J2J1-J1J2) = -i(J1J2-J2J1) = -i[J1,J2] so that we end up with: (J1+iJ2)(J1-iJ2) = J1^2 + J2^2 - i[J1,J2] The next step is to realise that [J1,J2] = i*hbar*J3, a result we derive in this video: kzbin.info/www/bejne/eKCYoqKXgdh1hac This means we end up with: (J1+iJ2)(J1-iJ2) = J1^2 + J2^2 - i*(i*hbar*J3) Using i^2=-1, we have that -i*(i*hbar*J3) = hbar*J3 This means that: (J1+iJ2)(J1-iJ2) = J1^2 + J2^2 + hbar*J3 Finally, by definition, J^2 = J1^2 + J2^2 + J3^2, so that we can write J1^2 + J2^2 = J^2 - J3^2. Replacing this in the equation above, we get: (J1+iJ2)(J1-iJ2) = J^2 - J3^2 + hbar*J3 And this is the end of the derivation. I hope this is clearer, and in general I would recommend watching the videos in the order provided by the corresponding playlists, so that you are familiar with any results we quote.

For the norm question, the key is that the eigenstates |lambda,mu> and |lamba,mu+hbar> are normalised, so they have norm one. Therefore, if we apply the operator J+ on |lambda,mu>, we may in general end up with a state with a different norm, and we call that state N+|lambda,mu+hbar>. This means that |N+|^2 gives the norm of the new state. I hope this helps!

@@ProfessorMdoesScience Thank you for the detailed answer! i watched the other videos, but this identiy in particular was trickier to me. The second one is also clear now!

@@khedot6291 Glad to hear it is clearer now! :)

Glad you like it! :)

We actually have them in this order on purpose. The idea is that we first introduce the ladder operators, and we show that, in general, they raise/lower the mu eigenvalue by a factor of hbar, where mu is kept general. The derivation of this result does not require that mu has the actual value it takes for angular momentum, hence we can do this derivation first. With this result, we can then figure out the actual values that lambda and mu take in the next video (the one on eigenvalues). I hope this helps!

@@ProfessorMdoesScience I see! What got me confused is that at 11:39 you say "As we discuss in the video about eigenvalues, it turns out..." and I misheard it as "as we descussED" (and I think there was some more places where you mention results that are derived in the other video, so at some point I was under the impression I was supposed to have already watched that!). Thank you!

BTW these videos are AMAZING!

Thanks for watching!

Thanks for watching! We are growing steadily, and one way you can support us further is by telling your friends! :)

@@ProfessorMdoesScience alright I'll ❤️

We do actually use Dirac notation often, see for example the first video where we introduce it: kzbin.info/www/bejne/nnvSiIBvn8tjnbc I hope this helps!

We are hoping to expand the resources we provide, perhaps including live sessions, but it will still take a while for us to get there. In the meantime, I hope you enjoy the videos!

@@ProfessorMdoesScience you're amazing, thank you for the outstanding content!