The Uehling potential is given by (units ${\displaystyle c=1}$  and ${\displaystyle \hbar =1}$ )

${\displaystyle V(r)={\frac {-e^{2}}{4\pi r}}\left(1+{\frac {e^{2}}{6\pi ^{2}}}\int _{1}^{\infty }dx\,e^{-2rm_{\text{e}}x}{\frac {2x^{2}+1}{2x^{4}}}{\sqrt {x^{2}-1}}\right),}$ 

from where it is apparent that this potential is a refinement of the classical Coulomb potential. Here ${\displaystyle m_{\text{e}}}$  is the electron mass and ${\displaystyle e}$  is the elementary charge measured at large distances.

If ${\displaystyle r\gg 1/m}$ , this potential simplifies to^[3]

${\displaystyle V(r)\approx {\frac {-e^{2}}{4\pi r}}\left(1+{\frac {e^{2}}{16\pi ^{3/2}}}{\frac {1}{(m_{\text{e}}r)^{3/2}}}e^{-2m_{\text{e}}r}\right),}$ 

while for ${\displaystyle r\ll 1/m}$  we have^[3]

${\displaystyle V(r)\approx {\frac {-e^{2}}{4\pi r}}\left(1+{\frac {e^{2}}{6\pi ^{2}}}\left(\log {\frac {1}{m_{\text{e}}r}}-\gamma -{\frac {5}{6}}\right)\right),}$ 

where ${\displaystyle \gamma }$  is the Euler–Mascheroni constant (0.57721...).

Properties edit

It was recently demonstrated that the above integral in the expression of ${\displaystyle V(r)}$  can be evaluated in closed form by using the modified Bessel functions of the second kind ${\displaystyle K_{0}(z)}$  and its successive integrals.^[4]

Since the Uehling potential only makes a significant contribution at small distances close to the nucleus, it mainly influences the energy of the s orbitals. Quantum mechanical perturbation theory can be used to calculate this influence in the atomic spectrum of atoms. The quantum electrodynamics corrections for the degenerated energy levels ${\displaystyle 2\mathrm {S} _{1/2}}$  of the hydrogen atom are given by^[5]

${\displaystyle \Delta E(2\mathrm {S} _{1/2})\approx -1{.}122\times 10^{-7}\,{\text{eV}}}$ 

up to leading order in ${\displaystyle m_{\text{e}}c^{2}}$ . Here ${\displaystyle \mathrm {eV} }$  stands for electronvolts.

Since the wave function of the s orbitals does not vanish at the origin, the corrections provided by the Uehling potential are of the order ${\textstyle \alpha ^{5}}$  (where ${\textstyle \alpha }$  is the fine structure constant) and it becomes less important for orbitals with a higher azimuthal quantum number. This energy splitting in the spectra is about a ten times smaller than the fine structure corrections provided by the Dirac equation and this splitting is known as the Lamb shift (which includes Uehling potential and additional higher corrections from quantum electrodynamics).^[5]

The Uehling effect is also central to muonic hydrogen as most of the energy shift is due to vacuum polarization.^[5] In contrast to other variables such as the splitting through the fine structure, which scale together with the mass of the muon, i.e. by a factor of ${\textstyle m_{\mu }/m_{\mathrm {e} }\approx 200}$ , the light electron mass continues to be the decisive size scale for the Uehling potential. The energy corrections are on the order of ${\textstyle (m_{\mu }^{3}/m_{\mathrm {e} }^{2})c^{2}\alpha ^{5}}$ .^[5]

• QED vacuum
• Virtual particles
• Anomalous magnetic dipole moment
• Schwinger limit
• Schwinger effect
• Euler–Heisenberg Lagrangian

• More on the vacuum polarization in QED, Peskin, M.E.; Schroeder, D.V. (2018) [1995]. "§7.5 Renormalization of the Electric Charge". An Introduction to Quantum Field Theory. CRC Press. pp. 244–256. ISBN 978-0-429-98318-4.