- 13,415
- 4,218
And I forgot to add the reference in the best QM textbook there is, section 6.2 of 1st volume of Galindo and Pascual, where my treatment is shortened and put in the full 3D context, where the deficiency indices differ.
DrDu said:The operator p_r is symmetric or Hermitian on e.g. the differentiable functions which vanish at r=0. However, it is then not self-adjoint
I like that book too. :)dextercioby said:And I forgot to add the reference in the best QM textbook there is, section 6.2 of 1st volume of Galindo and Pascual, where my treatment is shortened and put in the full 3D context, where the deficiency indices differ.
In the earlier spherical-polar conundrum, the resolution involving recognizing the the radial momentum should be written (classically) as something like ##\hat e_r \cdot \nabla##, and then symmetrized.stevendaryl said:[itex]\langle \psi | \phi \rangle = \int \psi^* \phi \sqrt{g} dx dy[/itex]
where [itex]g[/itex] is the determinant of the metric tensor. In this case, we have, with [itex]p_x = -i \hbar \partial_x[/itex],

stevendaryl said:There is something (actually, quite a few things) that I don't understand about the business of operators being self-adjoint. In curved space (consider just two-dimensions, for simplicity), what I would think would be the position space representation of the inner product of two wave functions [itex]\psi[/itex] and [itex]\phi[/itex] is:
[itex]\langle \psi | \phi \rangle = \int \psi^* \phi \sqrt{g} dx dy[/itex]
where [itex]g[/itex] is the determinant of the metric tensor. In this case, we have, with [itex]p_x = -i \hbar \partial_x[/itex],
[itex]\langle p_x \psi | \phi \rangle = \langle \psi | {P}_x \phi \rangle + ST[/itex]
where [itex]{P}_x[/itex] is the operator defined by [itex]{P}_x f = -i \hbar \frac{1}{\sqrt{g}} \partial_x (\sqrt{g} f) = (p_x - i \hbar \frac{1}{\sqrt{g}} \partial_x \sqrt{g}) f[/itex], and where [itex]ST[/itex] is the "surface term": [itex]\int ({P}_x (D_x (\psi^* \phi))) \sqrt{g} dx dy[/itex]
So [itex]p_x[/itex] is only symmetric if [itex]ST = 0[/itex] and [itex]g[/itex] is constant.
(Note: An identity that can be used is that: [itex]\frac{1}{\sqrt g} \partial_x \sqrt{g} = \Gamma^i_{i x}[/itex], where [itex]\Gamma[/itex] is the connection coefficients (implicit summation over the dummy index [itex]i[/itex]) So the operator [itex]P_x[/itex] can actually be written in the form: [itex]P_x f = (p_x - i \hbar \Gamma^i_{i x}) f[/itex], which seems like sort of a covariant derivative, except that since [itex]f[/itex] is a scalar, there's no difference between partial derivatives and covariant derivatives.)So if an operator being symmetric is a necessary (but maybe not sufficient) condition for being an observable, then the usual momentum operator isn't an observable in curved space. What does that mean?
vanhees71 said:The point is to formulate your observables in a manifestly covariant way. In non-relativistic quantum theory in the position representation ("wave mechanics") this boils down to express everything in terms of the classical differential operators grad, curl, and div or in terms of the nabla calculus.
Sure, that was my point too. I was trying to address stevendaryl's question: "then the usual momentum operator isn't an observable in curved space. What does that mean?"vanhees71 said:This I don't understand. The operator ##\vec{\nabla}## is linear by definition. In, e.g., spherical coordinates, it's
$$\vec{\nabla} \psi=\vec{e}_r \partial_r \psi+\frac{\vec{e}_{\vartheta}}{r} \partial_{\vartheta} \psi + \frac{\vec{e}_{\varphi}}{r \sin \vartheta} \partial_{\varphi} \psi.$$
Can you quote the part you find confused and specify how it is wrong? I'm not saying anything disagreeing with the rest of your post that I'm aware of.vanhees71 said:I guess, here is some confusion.
Yes, when using nonholonomic basis where i.e. ## \hat p_x## is a bona fide operator but the key issue is that it does depend on the coordinates when using a coordinate-basis.vanhees71 said:In the thread it looked as if different things have been mixed up. On the one hand there is the gradient operator in Euclidean space, expressed in curvilinear coordinates. This is a covariant operator and as such it doesn't make a difference whether I describe it in terms of Cartesian or any curvilinear coordinates. It's almost trivial that the momentum operator doesn't depend on the coordinates you use to express it.
And it seems there is no such momentum operator in those spaces, while there is a Hamiltonian operator. Note that this doesn't arise in curved spacetime where by virtue of the equivalence principle one can always use orthonormal frames locally.On the other hand there are non-Euclidean spaces, where you have to figure out whether there's a momentum operator at all or not. If there is one, it must be possible to express it in terms of any (local) coordinate system, i.e., it's generally (diffeomorphic) covariant.