posted on 2016-11-29, 00:00authored byAdam E. Colbert, Erin Jedlicka, Wenbi Wu, David S. Ginger
We
use transient absorption (TA) spectroscopy to study the origin
of photon-energy dependent hole transfer yields in blends of PbS quantum
dots with the conjugated polymer poly(3-hexylthiophene-2,5-diyl) (P3HT).
We selectively excite only the quantum dots at two different wavelengths
and measure the polymer ground state bleach resulting from the transfer
of photoexcited holes. The higher photon-energy pump shows a greater
prompt yield of hole transfer compared to the lower photon-energy
excitation, on time scales sufficient to out-compete hot carrier cooling
in lead chalcogenide quantum dots. We interpret the results as evidence
that the excess energy of nonthermalized, or “hot,”
excitons resulting from higher photon-energy excitation allows more
efficient charge transfer to the polymer in these systems. The data
also demonstrate slow charge transfer rates, up to ∼1 ns, of
the relaxed excitations on the PbS dots. These findings help to clarify
the role of excess photon energy and carrier relaxation dynamics on
free carrier generation in donor/acceptor solar cells.