Quantum Mechanics in a Spherical Wedge: Complete Solution and Implications for Angular Momentum Theory
Abstract
We solve the stationary Schr\"odinger equation for a particle confined to a 3D spherical wedge -- the region \(r,θ,φ): 0 ≤ r ≤ R,\, 0 ≤ θ ≤ π,\, 0 ≤ φ ≤ \ with Dirichlet BCs on all surfaces. This exactly solvable constrained-domain model exhibits spectral reorganisation under symmetry-breaking BCs and provides an operator-domain viewpoint on angular momentum quantisation. We obtain three main results. First, the stationary states are standing waves in the azimuthal coordinate and consequently are not eigenstates of Lz; we prove Lz = 0 with Lz = nφπ/ ≠ 0, demonstrating that angular momentum projection becomes an observable with genuine quantum uncertainty rather than a good quantum number. Second, the effective azimuthal quantum number μ = nφπ/ is generically non-integer, and square-integrability of the polar wavefunctions at both poles requires the angular eigenvalue parameter to satisfy - μ ∈ Z≥ 0. This regularity constraint yields a hierarchy: sectoral solutions ( = μ, satisfying the first-order highest-weight condition) exist for any real μ > 0, while tesseral and zonal solutions require integer steps, appearing only when μ itself is integer. Third, application to a Coulomb potential shows that the familiar integer angular momentum spectrum of hydrogen arises from the periodic identification φ φ + 2π that defines the full-sphere Hilbert space domain; modified boundary conditions yield a reorganised spectrum with non-integer effective angular momentum. The model clarifies the distinct roles of single-valuedness (selecting integer m via azimuthal topology) and polar regularity (selecting integer ≥ |m| via analytic constraints) in the standard quantisation of orbital angular momentum.
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