Density-Functional-Theory Calculations of Matter in Strong Magnetic Fields: I. Atoms and Molecules

Abstract

We present new ab initio calculations of the electronic structure of various atoms and molecules in strong magnetic fields ranging from B=1012 G to 2x1015 G, appropriate for radio pulsars and magnetars. For these field strengths, the magnetic forces on the electrons dominate over the Coulomb forces, and to a good approximation the electrons are confined to the ground Landau level. Our calculations are based on the density functional theory, and use a local magnetic exchange-correlation function which is tested to be reliable in the strong field regime. Numerical results of the ground-state energies are given for HN (up to N=10), HeN (up to N=8), CN (up to N=5) and FeN (up to N=3), as well as for various ionized atoms. Fitting formulae for the B-dependence of the energies are also given. In general, as N increases, the binding energy per atom in a molecule, |EN|/N, increases and approaches a constant value. For all the field strengths considered in this paper, hydrogen, helium, and carbon molecules are found to be bound relative to individual atoms (although for B less than a few x 1012 G, the relative binding between C and C2 is small). Iron molecules are not bound at B<1013 G, but become energetically more favorable than individual atoms at larger field strengths.

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