Quantum particle in a spherical well confined by a cone

Abstract

We consider the quantum problem of a particle in either a spherical box or a finite spherical well confined by a circular cone with an apex angle 2θ0 emanating from the center of the sphere, with 0<θ0<π. This non-central potential can be solved by an extension of techniques used in spherically-symmetric problems. The angular parts of the eigenstates depend on azimuthal angle and polar angle θ as Pλm(θ) eim where Pλm is the associated Legendre function of integer order m and (usually noninteger) degree λ. There is an infinite discrete set of values λ=λim (i=0,1,3,…) that depend on m and θ0. Each λim has an infinite sequence of eigenenergies En(λim), with corresponding radial parts of eigenfunctions. In a spherical box the discrete energy spectrum is determined by the zeros of the spherical Bessel functions. For several θ0 we demonstrate the validity of Weyl's continuous estimate NW for the exact number of states N up to energy E, and evaluate the fluctuations of N around NW. We examine the behavior of bound states in a well of finite depth U0, and find the critical value Uc(θ0) when all bound states disappear. The radial part of the zero energy eigenstate outside the well is 1/rλ+1, which is not square-integrable for λ 1/2. (0<λ 1/2 can appear for θ0>θc≈ 0.726π and has no parallel in spherically-symmetric potentials.) Bound states have spatial extent which diverges as a (possibly λ-dependent) power law as U0 approaches the value where the eigenenergy of that state vanishes.

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