Binding energy/position of maximum energy value

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Homework Statement


The binding energy of the ion H2+ is -16.3 eV at the equilibrium separation 0.106 nm. The Hellman-Feynman theorem states taht the force between the nuclei in a molecule can be calculated from the electrostatic repulsion between the nuclei and the electrostatic attraction of the nuclei to the electron distribution. According to this theorem, where must the squared modulus of the electron wave function in H2+ have its maximum value?

Homework Equations


P(x) = abs(psi(x))^2=1

The Attempt at a Solution


Urepulsion = 1/(4*pi*epsilonnaught)*q^2/r= 13 eV
Uattraction = Ebinding + Urepulsion = -2.7 eV
 
on Phys.org
The sum of attraction plus repulsion is the binding energy. -2.7 eV + 13 eV is positive, so the whole system would be unbound.

How do you find the attraction as function of the electron position?