The vibronic spectra of diatomic molecules in the gas phase also show rotational fine structure. Each line in a vibrational progression will show
P- and R-branches. For some electronic transitions there will also be a Q-branch. The transition energies, expressed in wavenumbers, of the lines for a particular vibronic transition are given, in the
rigid rotor approximation, that is, ignoring
centrifugal distortion, by G(J', J'') = \bar \nu_{v'-v''} + B'J'(J'+1) - B
J(J''+1) Here are
rotational constants and are rotational
quantum numbers. (For B also, a double prime indicates the ground state and a single prime an electronically excited state.) The values of the rotational constants may differ appreciably because the bond length in the electronic excited state may be quite different from the bond length in the ground state, because of the operation of the Franck-Condon principle. The rotational constant is inversely proportional to the square of the bond length. Usually as is true when an electron is promoted from a
bonding orbital to an
antibonding orbital, causing bond lengthening. But this is not always the case; if an electron is promoted from a non-bonding or antibonding orbital to a bonding orbital, there will be bond-shortening and . The treatment of rotational fine structure of vibronic transitions is similar to the treatment of
rotation-vibration transitions and differs principally in the fact that the ground and excited states correspond to two different electronic states as well as to two different vibrational levels. For the P-branch , so that \begin{align} \bar \nu_P &= \bar \nu _{v'-v''} + B'(J
-1)J - B
J(J''+1) \\ &= \bar \nu _{v'-v''} - (B'+B
)J + (B'-B
){J}^2 \end{align} Similarly for the R-branch , and \begin{align} \bar \nu_R &= \bar \nu _{v'-v''}+B'J'(J'+1)-B''J'(J'-1) \\ &= \bar \nu _{v'-v''} + (B '+B'')J' + (B'-B''){J'}^2 \end{align} Thus, the wavenumbers of transitions in both P- and R-branches are given, to a first approximation, by the single formula \bar \nu_{P,R} = \bar \nu _{v',v''}+(B'+B'')m +(B'-B'')m^2,\quad m=\pm 1, \pm 2 \ etc. Here positive values refer to the R-branch (with ) and negative values refer to the P-branch (with ). The wavenumbers of the lines in the P-branch, on the low wavenumber side of the
band origin at \bar \nu _{v',v''}, increase with . In the R-branch, for the usual case that , as increases the wavenumbers at first lie increasingly on the high wavenumber side of the band origin but then start to decrease, eventually lying on the low wavenumber side. The Fortrat diagram illustrates this effect. In the rigid rotor approximation the line wavenumbers lie on a
parabola which has a maximum at x = -\frac{B' + B''}{2(B'-B'')} The line of highest wavenumber in the R-branch is known as the
band head. It occurs at the value of which is equal to the
integer part of , or of . When a Q-branch is allowed for a particular electronic transition, the lines of the Q-branch correspond to the case , and wavenumbers are given by \bar\nu_Q=\bar \nu _{v',v''}+(B'-B'')J(J+1) \quad J=1, 2, \dots The Q-branch then consists of a series of lines with increasing separation between adjacent lines as increases. When the Q-branch lies to lower wavenumbers relative to the vibrational line.
Predissociation The phenomenon of predissociation occurs when an electronic transition results in dissociation of the molecule at an excitation energy less than the normal dissociation limit of the upper state. This can occur when the
potential energy curve of the upper state crosses the curve for a
repulsive state, so that the two states have equal energy at some internuclear distance. This allows the possibility of a radiationless transition to the repulsive state whose energy levels form a continuum, so that there is blurring of the particular vibrational band in the vibrational progression.
Applications torch showing excited molecular
radical band emission and
Swan bands due to C2. The analysis of vibronic spectra of diatomic molecules provides information concerning both the ground electronic state and the excited electronic state. Data for the ground state can also be obtained by vibrational or pure rotational spectroscopy, but data for the excited state can only be obtained from the analysis of vibronic spectra. For example, the bond length in the excited state may be derived from the value of the rotational constant
B′. In addition to stable diatomic molecules, vibronic spectroscopy has been used to study unstable species, including CH, NH,
hydroxyl radical, OH, and
cyano radical, CN. The
Swan bands in hydrocarbon flame spectra are a progression in the C–C stretching vibration of the
dicarbon radical, C2 for the d^3\Pi_u \Leftrightarrow a^3\Pi_g electronic transition. Vibronic bands for 9 other electronic transitions of C2 have been observed in the infrared and ultraviolet regions. == Polyatomic molecules and ions ==