Momentum operator in "open" space

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Consider the Hilbert space [itex]H=L^2([0,1],dx)[/itex]. Now we define the operator [itex]P=\frac \hbar i \frac{d}{dx}[/itex] on this Hilbert space with the domain of definition [itex]D(P)=\{ \psi \in H | \psi' \in H \ and \ \psi(0)=0=\psi(1) \}[/itex].
Then it can be shown that [itex]P^\dagger=\frac \hbar i \frac{d}{dx}[/itex] with [itex]D(P^\dagger)=\{ \varphi \in H | \varphi ' \in H \}[/itex].
So the operator P is Hermitian but no self-adjoint. But its possible to make P self-adjoint by enlarging its domain to the following:
[itex] D(P)=\{ \psi \in H | \psi ' \in H \ and \ \psi(0)=e^{i \alpha} \psi(1) \} \ \ \ \ \ (\alpha \in \mathbb R)[/itex].
My question is, how does this procedure work if the Hilbert space is [itex]H=L^2((-\infty,\infty),dx)?[/itex](In "open" space, which is of course not in its mathematically rigorous meaning.)
Thanks
 
dextercioby said:
In <open space>, there's no restriction on the domain of the derivative operator other than the norm of the image be finite: ##D(P)=D(P^{\dagger})=\{φ∈H|φ′∈H\}##

I don't think that works. How should we kill the boundary terms when we do the integration by parts then?
 
That ## \phi(-\infty) = 0## and ## \phi(\infty) = 0## follows from the requirements that the functions in the maximal domain of P be absolutely continuous on any finite interval of ##\mathbb{R}## and moreover, as I said, both ##\phi(x)## and ##\phi'(x)## belong to ##\mathcal{L}^2(\mathbb{R})##. This is firstly stated on page 106 of Akhiezer and Glazman's <Theory of Linear Operators in Hilbert Space> and later on page 111. Alternatively, check out page 18 of http://arxiv.org/abs/quant-ph/0103153v1.