Two charges on plane in a magnetic field I. "Quasi-equal" charges and neutral quantum system at rest cases

Abstract

Low-lying bound states for the problem of two Coulomb charges of finite masses on a plane subject to a constant magnetic field B perpendicular to the plane are considered. Major emphasis is given to two systems: two charges with the equal charge-to-mass ratio (quasi-equal charges) and neutral systems with concrete results for the Hydrogen atom and two electrons (quantum dot). It is shown that for these two cases, but when a neutral system is at rest (the center-of-mass momentum is zero), some outstanding properties occur: in double polar coordinates in CMS (R, φ) and relative (, ) coordinate systems (i) the eigenfunctions are factorizable, all factors except for -dependent are found analytically, they have definite relative angular momentum, (ii) dynamics in -direction is the same for both systems being described by a funnel-type potential; (iii) at some discrete values of dimensionless magnetic fields b ≤ 1 the system becomes quasi-exactly-solvable and a finite number of eigenfunctions in are polynomials. The variational method is employed. Trial functions are based on combining for the phase of a wavefunction (a) the WKB expansion at large distances, (b) the perturbation theory at small distances (c) with a form of the known analytically (quasi-exactly-solvable) eigenfunctions. For the lowest states with relative magnetic quantum numbers s=0,1,2 this approximation gives not less than 7 s.d., 8 s.d., 9 s.d., respectively, for the total energy E(B) for magnetic fields 0.049\, a.u. < B < 2000\, a.u. (Hydrogen atom) and 0.025\, a.u. B 1000\, a.u. (two electrons).