Ion
pairing is a fundamental consideration in many areas of chemistry
and has implications in a wide range of sciences and technologies
that include batteries and organic photovoltaics. Ions in solution
are known to inhabit multiple possible states, including free ions
(FI), contact ion pairs (CIP), and solvent-separated ion pairs (SSIP).
However, in solutions of organic radicals and nonmetal electrolytes,
it is often difficult to distinguish between these states. In the
first part of this work, we report evidence for the formation of SSIPs
in low-polarity solvents and distinct measurements of CIP, SSIP, and
FI, by using the ν(CN) infrared (IR) band of a nitrile-substituted
fluorene radical anion. Use of time-resolved IR detection following
pulse radiolysis allowed us to unambiguously assign the peak of the
FI. In the presence of nonmetal electrolytes, two distinct red-shifted
peaks were observed and assigned to the CIP and SSIP. The assignments
are interpreted in the framework of the vibrational Stark effect (VSE)
and are supported by (1) the solvent dependence of ion-pair populations,
(2) the observation of a cryptand-separated sodium ion pair that mimics
the formation of SSIPs, and (3) electronic structure calculations.
In the second part of this work, we show that a blue-shift of the
ν(CN) IR band due to the VSE can be induced in a nitrile-substituted
fluorene radical anion by covalently tethering it to a metal-chelating
ligand that forms an intramolecular ion pair upon reduction and complexation
with sodium ion. This adds support to the conclusion that the shift
in IR absorptions by ion pairing originates from the VSE. These results
combined show that we can identify ion-pair structures by using the
VSE, including the existence of SSIPs in a low-polarity solvent
