Why Can Pl Be Taken Out of the Commutation in Quantum Mechanics?

Chronos000
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Homework Statement



the problem asks for the commutation between momentum P and angular momentum L.

My solutions give an intermediate step of:

ejkl [Pi, Xk *Pl]

ejkl[Pi,Xk]Pl

I don't understand why we can just take out a Pl from the commutation. its not at the end of both parts of the commutation and so will be acted on in a different order
 
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There is a very useful identity,
[A, BC] = [A, B]C + B[A, C],
I suggest you remember it forever :-)

You can easily prove it by writing out the commutator, if you wish.
 
thanks for pointing this out to me. but wouldn't I have two terms if I used that relation?

I have also been told that Pi acting on Xk results in -i*h-bar deltaik

I thought the delta was only used to denote a dot product whereas a differential was just shown as a differential?
 
Doesn't the different components of momentum commute, i.e. [Pi,Pj]=0, i != j ?

In that case the result follows by using the mentioned identity (if I correctly understand that when you write Pi and Pj you mean the different components of momentum P).
 
I can't believe I missed that... I still don't know where this delta comes from though
 
i figured it out, thanks anyway
 

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