Quantum information measures of the Aharonov-Bohm ring in uniform magnetic fields

Abstract

Shannon quantum information entropies S,γ, Fisher informations I,γ, Onicescu energies O,γ and complexities eSO are calculated both in position (subscript ) and momentum (γ) spaces for azimuthally symmetric 2D nanoring that is placed into combination of transverse uniform magnetic field B and Aharonov-Bohm (AB) flux φAB and whose potential profile is modeled by superposition of quadratic and inverse quadratic dependencies on radius r. Increasing intensity B flattens momentum waveforms nm( k) and in the limit of infinitely large fields they turn to zero, what means that the position wave functions nm( r), which are their Fourier counterparts, tend in this limit to the δ-functions. Position (momentum) Shannon entropy depends on the field B as a negative (positive) logarithm of ωeff(ω02+ωc2/4)1/2, where ω0 determines the quadratic steepness of the confining potential and ωc is a cyclotron frequency. This makes the sum S_nm+Sγnm a field-independent quantity that increases with the principal n and azimuthal m quantum numbers and does satisfy entropic uncertainty relation. Position Fisher information does not depend on m, linearly increases with n and varies as ωeff whereas its n and m dependent Onicescu counterpart O_nm changes as ωeff-1. The products I_nmIγnm and O_nmOγnm are B-independent quantities. A dependence of the measures on the ring geometry is discussed. It is argued that a variation of the position Shannon entropy or Onicescu energy with the AB field uniquely determines an associated persistent current as a function of φAB at B=0. An inverse statement is correct too.