Showing that general operator equations are hermitian

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Homework Statement



a)For a general operator A, show that and i(A-A+) are hermitian?

b) If operators A and B are hermitian, show that the operator (A+B)^n is Hermitian.

Homework Equations

The Attempt at a Solution



The first part I did,

(A+A+)+=(A++A)=(A+A+)

i(A-A+)=[i(A-A+)]+=(iA)+-(iA+)+)=i(A-A+)

The second part I used binomial expansion (induction) but I was told they do not commute so this cannot be done?

Is my answer to the first part correct and what route should I take for the second? Thanks
 
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First part looks about right.

For the second part, do you really need to multiply things out? After all, if A and B are Hermitian then A+B is also Hermitian...
 
The problems seems to have no connection with <Advanced Physics> and neither with mathematics, since it's not mathematically (i.e. in agreement with mathematics) formulated and not even semantically.
 
For example, the mathematical problem for point a) should have been

"Let A be a densly defined linear operator on a complex separable Hilbert space \mathcal{H}.

Prove that if D(A)\cap D\left(A^{\dagger}\right) is dense everywhere in \mathcal{H},

then the operator i\left(A-A^{\dagger}\right) is symmetric.
 

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