Angular momentum operators and their algebra

RJ Skerry-Ryan I want to talk to you about an important issue related to quantum mechanics, I hope you will respond to my message
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RJ Skerry-Ryan
Please

@@knowbeautiful2615 I am the press secretary, please tell me all about your important issue.

The universe is your real school

Community college will always accept you and there are often times grants for students of all kinds of backgrounds. I joined CC "late" and took my time learning many concepts and enjoying the CC life, then transferred to university just last year. I am now studying physics at Berkeley. I spent years working and never thought I would join school, but I was also really bored and found myself learning quantum mechanics from TH-cam at 4am. You can do it!

I watched it in 2x dude

Yes! He is a phenomenal lecturer and Professor!

In the first step of [lx,ly], he took out px because it is independent of z,pz, and y. To see this, remember how if you take the derivative of a function with respect to x, you can treat all z,y-related terms in the function as constants. Here, he took out everything unrelated to x, which is [ypz, z], and treated it as a constant.

The actual value of angular momentum doesn't matter when talking of uncertainty, only the magnitude of the operator Lz=hbar. So no matter what the value of 'm' is, the uncertainty principle still holds true

I believe you still have uncertainty in the angular momentum in the x and y directions

You are right that when the value of the z component is zero, it is possible to simultaneously measure both Lx, and Ly with certainty. In fact, since you already know Lz = 0 and you can measure both Lx and Ly exactly, you can know all 3 at the same time! But I wouldn't call this the uncertainty principle failing, because the uncertainty principle only tells you the relationship between the product of the variances of two observables and the commutation, and here, this commutation happens to be 0.

Pz = -ihbar d/dz, and y = y.
d/dz yf = y d/dz f, so the order doesn't matter ( [y, Pz] = 0 ).

@@scalesconfrey5739 Bro thank you sm

[A,B]=A*B-B*A

Thank you

The commutation relation of two operators strikes right at the nature of their physical observability. That is, if two operators commute, it implies that they have a common Eigen vector to act upon and hence produce an Eigen value. In contrast, if they don't commute, these operators find no Eigen vectors that are common to both and hence cannot act simultaneously. To make things a bit more simple, we can, on a lighter note, say that when two operators commute, the measurements corresponding to each of them (made on the system) can be taken simultaneously and if they do not commute, they cannot be measured simultaneously. Hope it was helpful.

@@rohanmathew5728 at the end you must say about two operators that don’t commute that you can’t measure them simultaneously ” with high precision “. because you actually can measure them simultaneously but not with high accuracy.

when did he go to real analysis lol, he just started talking about algebras

[Lz,x^2]+[Lz,y^2]+[Lz,z^2]
[Lz,x]x+x[Lz,x]+[Lz,y]y+y[Lz,y]+[Lz,z]z+z[Lz,z]
(ihxy)+(ihxy)+(-ihxy)+(-ihxy)+0+0
0