Conjugated polymers in the solid state usually exhibit low fluorescence quantum yields, which limit their applications in many areas such as light-emitting diodes. Despite considerable research efforts, the underlying mechanism still remains controversial and elusive. Here, the nature and properties of excited states in the archetypal polythiophene are investigated via aggregates suspended in solvents with different dielectric constants (ɛ). In relatively polar solvents (ɛ>∼ 3), the aggregates exhibit a low fluorescence quantum yield (QY) of 2–5%, similar to bulk films, however, in relatively nonpolar solvents (ɛ<∼ 3) they demonstrate much higher fluorescence QY up to 20–30%. A series of mixed quantum-classical atomistic simulations illustrate that dielectric induced stabilization of nonradiative charge-transfer (CT) type states can lead to similar drastic reduction in fluorescence QY as seen experimentally. Fluorescence lifetime measurement reveals that the CT-type states exist as a competitive channel of the formation of emissive exciton-type states.
Excitonic energy migration was studied using single molecule spectroscopy of individual conjugated polymer (CP) chains and aggregates. To probe the effect of interchain morphology on energy migration in CP, tailored interchain morphologies were achieved using solvent vapor annealing to construct polymer aggregates, which were then studied with single aggregate spectroscopy. We report that highly ordered interchain packing in regioregular poly(3-hexylthiophene) (rr-P3HT) enables long-range interchain energy migration, while disordered packing in regiorandom poly(3-hexylthiophene) (rra-P3HT), even in aggregates of just a few chains, can dramatically impede the interchain mechanism. In contrast to rr-P3HT, interchain energy migration in poly(3-(2'-methoxy-5'-octylphenyl)thiophene) (POMeOPT), a polythiophene derivative with bulky side chains, can be completely inhibited. We use simulated structures to show that the reduction in interchain coupling is not due simply to increased packing distance between backbones of different chains, but reflects inhibition of stacking due to side-chain-induced twisting of the contours of individual chains. A competition from intrachain coupling has also been demonstrated by comparing POMeOPT aggregates with different polymer chain sizes.
With a tunable size-dependent photoluminescence (PL)
over a wide
infrared wavelength range, lead chalcogenide quantum dots (QDs) have
attracted significant scientific and technological interest. Nevertheless,
the investigation of intrinsic exciton photophysics at the single-QD
level has remained a challenge. Herein, we present a comprehensive
study of PL properties for the individual core/shell PbS/CdS QDs emissive
near 1.0 eV. In contrast to the sub-meV spectral line widths observed
for II/VI QDs, PbS/CdS QDs are predicted to possess broad homogeneous
line widths. Performing spectroscopy at cryogenic (4 K) temperatures,
we provide direct evidence confirming theoretical predictions, showing
that intrinsic line widths for PbS/CdS QDs are in the range of 8–25
meV, with an average of 16.4 meV. In addition, low-temperature, single-QD
spectroscopy reveals a broad low-energy side emission attributable
to optical as well as localized acoustic phonon-assisted transitions.
By tracking single QDs from 4 to 250 K, we were able to probe temperature-dependent
evolutions of emission energy, line width, and line shape. Finally,
polarization-resolved PL imaging showed that PbS/CdS QDs are characterized
by a 3D emission dipole, in contrast with the 2D dipole observed for
CdSe QDs.
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