In 3D systems When applying WKB approximation method to the radial
Schrödinger equation, -\frac{\hbar^2}{2 m} \frac{d^2 R(r)}{dr^2} + [E-V_\textrm{eff}(r)] R(r) = 0 , where the
effective potential is given by V_\textrm{eff}(r) = V(r) - \frac{\hbar^2\ell(\ell+1)}{2mr^2} ( \ell the
azimuthal quantum number related to the
angular momentum operator), the eigenenergies and the wave function behaviour obtained are different from the real solution. In 1937,
Rudolf E. Langer suggested a correction \ell(\ell+1) \rightarrow \left(\ell+\frac{1}{2}\right)^2 which is known as Langer correction or
Langer replacement. This manipulation is equivalent to inserting a 1/4 constant factor whenever \ell(\ell+1) appears. Heuristically, it is said that this factor arises because the range of the radial Schrödinger equation is restricted from 0 to infinity, as opposed to the entire real line. By such a changing of constant term in the effective potential, the results obtained by WKB approximation reproduces the exact spectrum for many potentials. That the Langer replacement is correct follows from the WKB calculation of the Coulomb eigenvalues with the replacement which reproduces the well known result.
In 2D systems Note that for 2D systems, as the effective potential takes the form V_\textrm{eff}(r) = V(r) - \frac{\hbar^2(\ell^2-\frac{1}{4})}{2mr^2}, so Langer correction goes: \left(\ell^2-\frac{1}{4}\right) \rightarrow \ell^2. This manipulation is also equivalent to insert a 1/4 constant factor whenever \ell^2 appears. == Justification ==