This
account aims at providing an understanding of singlet fission,
i.e., the photophysical process of a singlet state (
S1
) splitting into two triplet states
(2 ×
T1
) in molecular
chromophores. Since its discovery 50 years ago, the field of singlet
fission has enjoyed rapid expansion in the past 8 years. However,
there have been lingering confusion and debates on the nature of the
all-important triplet pair intermediate states and the definition
of singlet fission rates. Here we clarify the confusion from both
theoretical and experimental perspectives. We distinguish the triplet
pair state that maintains electronic coherence between the two constituent
triplets,
1(TT)
, from one
which does not,
1(T···T)
. Only the rate of formation of
1(T···T)
is defined as that of singlet
fission. We present distinct experimental evidence for
1(TT)
, whose formation may occur via incoherent
and/or vibronic coherent mechanisms. We discuss the challenges in
treating singlet fission beyond the dimer approximation, in understanding
the often neglected roles of delocalization on singlet fission rates,
and in realizing the much lauded goal of increasing solar energy conversion
efficiencies with singlet fission chromophores.
The ability to advance our understanding of multiple exciton generation (MEG) in organic materials has been restricted by the limited number of materials capable of singlet fission. A particular challenge is the development of materials that undergo efficient intramolecular fission, such that local order and strong nearest-neighbour coupling is no longer a design constraint. Here we address these challenges by demonstrating that strong intrachain donor-acceptor interactions are a key design feature for organic materials capable of intramolecular singlet fission. By conjugating strong-acceptor and strong-donor building blocks, small molecules and polymers with charge-transfer states that mediate population transfer between singlet excitons and triplet excitons are synthesized. Using transient optical techniques, we show that triplet populations can be generated with yields up to 170%. These guidelines are widely applicable to similar families of polymers and small molecules, and can lead to the development of new fission-capable materials with tunable electronic structure, as well as a deeper fundamental understanding of MEG.
We apply attenuated total internal reflection Fourier transform infrared (ATR-FTIR) spectroscopy to directly probe active layers in organic thin film transistors (OTFTs). The OTFT studied uses the n-type organic semiconductor N-N'-dioctyl-3,4,9,10-perylene tetracarboxylic diimide (PTCDI-C8) and a polymer electrolyte gate dielectric made from poly(ethylene oxide) and LiClO4. FTIR spectroscopy of the device shows signatures of anionic PTCDI-C8 species and broad polaron bands when the organic semiconductor layer is doped under positive gate bias (VG). There are two distinctive doping regions: a reversible and electrostatic doping region for VG 2 V. On the basis of intensity loss of vibrational peaks attributed to neutral PTCDI-C8, we obtain a charge carrier density of 2.9 x 10(14)/cm2 at VG=2 V; this charge injection density corresponds to the conversion of slightly more than one monolayer of PTCDI-C8 molecules into anions. At higher gate bias voltage, electrochemical doping involving the intercalation of Li+ into the organic semiconductor film can convert all PTCDI-C8 molecules in a 30-nm film into anionic species. For comparison, when a conventional gate dielectric (polystyrene) is used, the maximum charge carrier density achievable at VG=200 V is approximately 4.5 x 10(13)/cm2, which corresponds to the conversion of 18% of a monolayer of PTCDI-C8 molecules into anions.
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