Ultra-Compact accurate wave functions for He-like and Li-like iso-electronic sequences and variational calculus. III. Spin-quartet state of the Lithium sequence

Abstract

As a continuation of Part I, dedicated to the ground state of He-like and Li-like isoelectronic sequences for nuclear charges Z ≤ 20, and Part II, dedicated to two excited states of He-like sequence, two ultra-compact wave functions in the form of generalized Guevara-Harris-Turbiner functions are constructed for Li-like sequence. They describe accurately the domain of applicability of the Quantum Mechanics of Coulomb Charges (QMCC) for energies (2-3 significant digits (s.d.)) of the spin-quartet state 140+ of Li-like ions (in static approximation with point-like, infinitely heavy nuclei). Variational parameters are fitted in Z by 2nd degree polynomials. The most accurate ultra-compact function leads to the absolute accuracy 10-3\,a.u. for energy, and 10-4 for the normalized electron-nuclear cusp parameter for Z ≤ 20. Critical charge Z=ZB, where the ultra-compact trial function for the 140+ state looses its square-integrability, is estimated, ZB(14\,0+) 1.26 - 1.30. As a complement to Part I, square integrability for the compact functions constructed for the ground, spin-doublet state 12\,0+ of the Li-like sequence is discussed. The critical charge, for which these functions stop to be normalizable, is estimated as ZB( 12\,0+) = 1.62 - 1.65. It implies that at Z=2 - the negative helium ion He- - both states 12\,0+ and 14\,0+ exist as states embedded to continuum.