Consider an electrical
dipole transition from the initial vibrational state (
υ) of the ground electronic level (
ε), |\epsilon v\rangle, to some vibrational state (
υ′) of an excited electronic state (
ε′), |\epsilon' v'\rangle (see
bra–ket notation). The molecular dipole operator
μ is determined by the charge (−
e) and locations (
ri) of the
electrons as well as the charges (+''Z'
j'e
) and locations (Rj'') of the
nuclei: :\boldsymbol{\mu} = \boldsymbol{\mu}_e + \boldsymbol{\mu}_N = -e\sum\limits_i \boldsymbol{r}_i + e\sum\limits_j Z_j \boldsymbol{R}_j. The
probability amplitude P for the transition between these two states is given by : P = \left\langle \psi'\right|\boldsymbol{\mu} \left| \psi \right\rangle =\int {\psi'^*} \boldsymbol{\mu} \psi \,d\tau, where \psi and \psi' are, respectively, the overall
wavefunctions of the initial and final state. The overall wavefunctions are the product of the individual vibrational (depending on spatial coordinates of the nuclei) and electronic space and
spin wavefunctions: : \psi = \psi_e \psi_v \psi_s. This separation of the electronic and vibrational wavefunctions is an expression of the
Born–Oppenheimer approximation and is the fundamental assumption of the Franck–Condon principle. Combining these equations leads to an expression for the probability amplitude in terms of separate electronic space, spin and vibrational contributions: : P = \left\langle \psi_e' \psi_v' \psi_s' \right| \boldsymbol{\mu} \left| \psi_e \psi_v \psi_s \right\rangle = \int \psi_e'^* \psi_v'^* \psi_s'^* (\boldsymbol{\mu}_e + \boldsymbol{\mu}_N) \psi_e \psi_v \psi_s \,d\tau :: = \int \psi_e'^* \psi_v'^* \psi_s'^* \boldsymbol{\mu}_e \psi_e \psi_v \psi_s \,d\tau + \int \psi_e'^* \psi_v'^* \psi_s'^* \boldsymbol{\mu}_N \psi_e \psi_v \psi_s \,d\tau :: = \underbrace{\int \psi_v'^* \psi_v \,d\tau_n}_{\displaystyle{\text{Franck–Condon} \atop \text{factor}}} \underbrace{\int \psi_e'^* \boldsymbol{\mu}_e \psi_e \,d\tau_e}_{\displaystyle{\text{orbital} \atop \text{selection rule}}} \underbrace{\int \psi_s'^* \psi_s \,d\tau_s}_{\displaystyle{\text{spin} \atop \text{selection rule}}} + \underbrace{\int \psi_e'^* \psi_e \,d\tau_e}_{\displaystyle 0} \int \psi_v'^* \boldsymbol{\mu}_N \psi_v \,d\tau_v \int \psi_s'^* \psi_s \,d\tau_s. The spin-independent part of the initial integral is here
approximated as a product of two integrals: : \iint \psi_v'^* \psi_e'^* \boldsymbol{\mu}_e \psi_e \psi_v \,d\tau_e d\tau_n \approx \int \psi_v'^* \psi_v \,d\tau_n \int \psi_e'^* \boldsymbol{\mu}_e \psi_e \,d\tau_e. This factorization would be exact if the integral \int \psi_e'^* \boldsymbol{\mu}_e \psi_e \,d\tau_e over the spatial coordinates of the electrons would not depend on the nuclear coordinates. However, in the Born–Oppenheimer approximation \psi_e and \psi'_e do depend (parametrically) on the nuclear coordinates, so that the integral (a so-called
transition dipole surface) is a function of nuclear coordinates. Since the dependence is usually rather smooth it is neglected (i.e., the assumption that the transition dipole surface is independent of nuclear coordinates, called the
Condon approximation is often allowed). The first integral after the plus sign is equal to zero because electronic wavefunctions of different states are orthogonal. Remaining is the product of three integrals. The first integral is the vibrational overlap integral, also called the
Franck–Condon factor. The remaining two integrals contributing to the probability amplitude determine the electronic spatial and spin selection rules. The Franck–Condon principle is a statement on allowed
vibrational transitions between two
different electronic states; other quantum mechanical
selection rules may lower the probability of a transition or prohibit it altogether. Rotational selection rules have been neglected in the above derivation. Rotational contributions can be observed in the spectra of gases but are strongly suppressed in liquids and solids. It should be clear that the quantum mechanical formulation of the Franck–Condon principle is the result of a series of approximations, principally the electrical dipole transition assumption and the Born–Oppenheimer approximation. Weaker
magnetic dipole and electric
quadrupole electronic transitions along with the incomplete validity of the factorization of the total wavefunction into nuclear, electronic spatial and spin wavefunctions means that the selection rules, including the Franck–Condon factor, are not strictly observed. For any given transition, the value of
P is determined by all of the selection rules, however spin selection is the largest contributor, followed by electronic selection rules. The
Franck–Condon factor only
weakly modulates the intensity of transitions, i.e., it contributes with a factor on the order of 1 to the intensity of bands whose
order of magnitude is determined by the other selection rules. The table below gives the range of extinction coefficients for the possible combinations of allowed and forbidden spin and orbital selection rules. == Franck–Condon metaphors in spectroscopy ==