Two-electron atom

In atomic physics, a two-electron atom or helium-like ion is a quantum mechanical system consisting of one nucleus with a charge of Ze and just two electrons. This is the first case of many-electron systems where the Pauli exclusion principle plays a central role.
It is an example of a three-body problem.
The first few two-electron atoms are:

Schrödinger equation

The Schrödinger equation for any two-electron system, such as the neutral Helium atom, the negative Hydrogen ion, or the positive Lithium ion is: For a more rigorous mathematical derivation of the Schrödinger equation, see also.
where r₁ is the position of one electron, r₂ is the position of the other electron, r₁₂ = is the magnitude of the separation between them given by
μ is the two-body reduced mass of an electron with respect to the nucleus of mass M
and Z is the atomic number for the element.
The cross-term of two Laplacians
is known as the mass polarization term, which arises due to the motion of atomic nuclei. The wavefunction is a function of the two electron's positions:
There is no closed form solution for this equation.

Spectrum

The optical spectrum of the two electron atom has two systems of lines. A para system of single lines, and an ortho system of triplets. The energy levels in the atom for the single lines are indicated by ¹S₀ ¹P₁ ¹D₂ ¹F₃ etc., and for the triplets, some energy levels are split: ³S₁ ³P₂ ³P₁ ³P₀ ³D₃ ³D₂ ³D₁ ³F₄ ³F₃ ³F₂. Alkaline earths and mercury also have spectra with similar features, due to the two outer valence electrons.