Diffusion of Solvent-Separated Ion Pairs Controls
Back Electron Transfer Rate in Graphene Quantum Dots
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Abstract
In
the present study, the stability of the photogenerated, solvent-separated
charged states
of graphene quantum dots (GQDs) in the presence of <i>N</i>,<i>N</i>-diethylaniline (DEA) has been evaluated in a
series of organic solvents. The results indicate that the rate constant
for back electron transfer (<i>k</i><sub>BET</sub>) from
GQD radical anion to DEA radical cation is diffusion-controlled. As
a result of the diffusion-controlled back electron transfer (BET), <i>k</i><sub>BET</sub> exhibits an inverse exponential relation
to (a) the viscosity coefficient (η) of the solvent and (b)
the average radius of the graphene quantum dots. An analytical expression
for the diffusion-controlled back electron transfer rate constant
has been formulated. The dependence of <i>k</i><sub>BET</sub> on the diffusion of solvent-separated ion pairs has been evaluated
for the first time for quantum dot systems and the results provide
an efficient method for enhancing the lifetime of the photogenerated
charge-separated states from graphene quantum dots. The present findings
can potentially improve the performance of GQD-based photovoltaic
and optoelectronic devices