fzero said:I suppose the most straightforward argument that that is not an eigenvector is simply that it is not orthogonal to any of the eigenvectors with nonzero eigenvalue. Since the operator is Hermitian, it is not a proper eigenfunction (pun intended!)
stevendaryl said:In QM, the usual meaning of "eigenfunction" is a square-integrable function that has a definite value for some operator. But [itex]\psi = x - iy[/itex] isn't square-integrable, so it's not a legitimate wave function. In many instances in quantum mechanics, it's the constraint that the wavefunction be square-integrable that forces its eigenvalues to be discrete. So usually when people talk about the eigenvalues of an operator [itex]O[/itex], they mean those values [itex]\lambda[/itex] such that there is a square-integrable function [itex]\psi[/itex] with [itex]O \psi = \lambda \psi[/itex].
dyn said:the question was from an introductory QM course. At that level Rigged Hilbert Spaces are unheard of. So at the introductory level is there a definite answer of eigenfunction or not ?
dyn said:Sorry to be a pain here but the mathematical definition of eigenvectors doesn't put any requirements on whether they can be normailised or not.
dyn said:I don't have a teacher. Just self-studying. Obviously the QM case is never straight forward - no surprise there but I have a last question. If it was just a maths question regarding eigenvalues and I had a function similar to the KE operator and the function x-iy would it be an eigenfunction with eigenvalue zero ? Whenever I have done eigenfunction questions I have just had to check if it satisfies the eigenvalue equation. Is this not enough ? Do I now need to check normed vector spaces ?
Avodyne said:Whatever source the OP had that asked the original question is badly written and should be dropped.
The KE operator, also known as the kinetic energy operator, is a mathematical representation of the energy associated with the motion of a particle. It is used in quantum mechanics to calculate the kinetic energy of a particle in a given system.
The KE operator is represented by the symbol "T" and is defined as T = -ħ²/2m (∂²/∂x² + ∂²/∂y² + ∂²/∂z²), where ħ is the reduced Planck's constant, m is the mass of the particle, and ∂/∂x, ∂/∂y, and ∂/∂z represent partial derivatives in the x, y, and z directions, respectively.
Eigenfunctions of the KE operator are mathematical functions that, when acted on by the KE operator, result in a multiple of the original function. In other words, they are functions that satisfy the eigenvalue equation Tψ = Eψ, where ψ is the eigenfunction and E is the corresponding eigenvalue.
The eigenfunctions of the KE operator are directly related to the energy of a particle. The eigenvalue E represents the energy of the particle in the system, and the corresponding eigenfunction ψ describes the spatial distribution of the particle's wavefunction.
Eigenfunctions play a crucial role in quantum mechanics as they provide a way to describe the energy and spatial distribution of a particle in a given system. They also form a complete set of basis functions, which allows for the expansion of any wavefunction in terms of these eigenfunctions, making calculations and predictions in quantum mechanics possible.