Unitarity angular momentum operators

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Yoran91
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Hi,

I'm confused by a sentence in a set of lecture notes I have on quantum mechanics. In it, it is assumed there is some representation [itex]\pi[/itex] of [itex]SO(3)[/itex] on a Hilbert space. This representation is assumed to be irreducible and unitary.

It is then said that the operators [itex]J_i[/itex], which are said to be the infinitesimal generators of the rotation group satisfying [itex][J_i,J_j]=i \epsilon_{ijk}[/itex], are Hermitian as a consequence of the unitarity of this representation.

This confuses me. Shouldn't they say that the operators [itex]\pi (J_i)[/itex] are Hermitian? Are they writing [itex]J_i[/itex] for both the infinitesimal generators of the group and the operators they are mapped to?
 
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Yoran91 said:
This confuses me. Shouldn't they say that the operators [itex]\pi (J_i)[/itex] are Hermitian? Are they writing [itex]J_i[/itex] for both the infinitesimal generators of the group and the operators they are mapped to?

Yes, they should do so. But it is quite common to write J for some representation.
 
Thanks for your quick answer.

Does that, then, imply that the Casimir operator is actually [itex]\sum_i \pi(J_i)^2[/itex]?
Do the commutation relations satisfied by the Lie group generators carry over to the operators under the representation map? I can see that

[itex][\pi(J_i),\pi(J_j)] = \pi(J_i)\pi(J_j) - \pi(J_j)\pi(J_i) = \pi(J_i J_j) -\pi(J_j J_i)[/itex],

but I don't see why I could conclude that the last line equals [itex]\pi([J_i,J_j])[/itex]

EDIT: The only way I could see that happen if the representation is linear, but I haven't seen that assumed in its definition. Should that be included?
 
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How so? I mean : how do you know the representation is linear whenever the representation space is?