If we use approximate wavefunction f , then the variation theorem states:

Where E₀ is the ground state energy. We set up the f trial function via the valence bond method or the molecular orbital method.

Molecular orbital method - A molecular orbital (trial function f ) is composed of 1 electron coordinate with several nuclei = it is the linear combination of H-atom like atomic orbitals for which we are dealing with the same (1) electron. The resulting molecular orbital is delocalized over several nuclei, with 1 electron. We finally fill all the molecular orbitals with electrons. LCAO - Linear Combination of atomic orbitals: f = c_{Aj A} + c_{Bj B} one particular 1-electron molecular orbital (as we add electrons we,in essence, multiply these orbitals), where j ₁ & j ₂ are atomic orbitals.

The actual wavefunction (for all electrons and nuclei) is the product of the molecular orbitals (due to the orbital approximation): Y = f ₁ *f ₂ * f ₃ ...

Find the molecular orbital approximate eigenvalues for H₂+ (represented by nuclei H_a H_b and one electron).

1) B.O. Approx'n drop Nuc. K.E., drop Nuc-Nuc repulsion as constant term
2) Treat R as a parameter, such that we will solve H approximately for each value of R.
3) Basis set for H₂⁺ are 1s atomic orbitals centered on nuclei a and b, such that the molecular orbital y ± is a L.C. of these: y ± = c_a(1s_a) _± c_b(1s_b) A linear combination of atomic orbitals LCAO

4) Take spin and Pauli Exclusion Prinicple into account and obtain the total
wavefunction Y (spin-included) MOs by making use of Slater Determinants.
5) Now compute the energy eigenvalues of the system by variational principle
utilizing H_{ele+nuc_rep} and total wavefn Y
If we let c_a = c_b =1 we have two functions: y ± = 1s_{a ±} 1s_b
Let’s compute the normalization for y ± = 1s_{a ±} 1s_b, we must first discuss overlap integral:

Thus we have two cases:

Plus case: {c_a(1s_b)+c_b(1s_a)} = {c_a(1s_a)+c_b(1s_b)}
c_a(1s_a-1s_b) - c_b(1s_a-1s_b) = 0, c_a = c_b = c_g

Minus case {c_a(1s_b)+c_b(1s_a)} = - {c_a(1s_a)+c_b(1s_b)}
c_a(1s_a+1s_b) + c_b(1s_a+1s_b) = 0, c_a = - c_b = c_u

Thus our two possible M.O.s are: s _g = c_g(1s_a+1s_b) , s _u = c_u(1s_a-1s_b)

4) Normalization of each ò s _g^*s _gdt =1 ò s _u^*s _udt =1, leads to values for c_u&c_g
c_g = 1¸ [2(1+s_ab)]^½, c_u= 1¸ [2(1-s_ab)]^½ Where s_ab = ò s_a^*s_bdt

5) Now apply variation principle to compute E_g and E_u for wavefns s _g & s _u
Use fact H_aa=H_bb, and H_ab=H_ba due to Hermiticity (Problem #2 of Homework
#8) E_g = <s _g|H|s _g> = [H_aa+H_ab]¸ [1+S_ab], E_u = <s _u|H|s _u> = [H_aa-H_ab]¸ [1-S_ab]

6) Evaluation of H_aa and H_ab

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