H2+ molecular ion in a strong magnetic field: ground state
Abstract
A detailed quantitative analysis of the system (ppe) placed in magnetic field ranging from 0 - 4.414 × 1013 G is presented. The present study is focused on the question of the existence of the molecular ion H2+ in a magnetic field. As a tool, a variational method with an optimization of the form of the vector potential (optimal gauge fixing) is used. It is shown that in the domain of applicability of the non-relativistic approximation the system (ppe) in the Born-Oppenheimer approximation has a well-pronounced minimum in the total energy at a finite interproton distance for B 1011 G, thus manifesting the existence of H2+. For B 1011 G and large inclinations (of the molecular axis with respect to the magnetic line) the minimum disappears and hence the molecular ion H2+ does not exist. It is shown that the most stable configuration of H2+ always corresponds to protons situated along the magnetic line. With magnetic field growth the ion H2+ becomes more and more tightly bound and compact, and the electronic distribution evolves from a two-peak to a one-peak pattern. The domain of inclinations where the H2+ ion exists reduces with magnetic field increase and finally becomes 0o - 25o at B = 4.414 × 1013 G. Phase transition type behavior of variational parameters for some interproton distances related to the beginning of the chemical reaction H2+ H + p is found.
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