Two charges on a plane in a magnetic field: hidden algebra, (particular) integrability, polynomial eigenfunctions

Abstract

The quantum mechanics of two Coulomb charges on a plane (e1, m1) and (e2, m2) subject to a constant magnetic field B perpendicular to the plane is considered. Four integrals of motion are explicitly indicated. It is shown that for two physically-important particular cases, namely that of two particles of equal Larmor frequencies, ec e1m1-e2m2=0 (e.g. two electrons) and one of a neutral system (e.g. the electron - positron pair, Hydrogen atom) at rest (the center-of-mass momentum is zero) some outstanding properties occur. They are the most visible in double polar coordinates in CMS (R, φ) and relative (, ) coordinate systems: (i) eigenfunctions are factorizable, all factors except one with the explicit -dependence are found analytically, they have definite relative angular momentum, (ii) dynamics in -direction is the same for both systems, it corresponds to a funnel-type potential and it has hidden sl(2) algebra; at some discrete values of dimensionless magnetic fields b ≤ 1, (iii) particular integral(s) occur, (iv) the hidden sl(2) algebra emerges in finite-dimensional representation, thus, the system becomes quasi-exactly-solvable and (v) a finite number of polynomial eigenfunctions in appear. Nine families of eigenfunctions are presented explicitly.