Traditional long-persistent luminescence (LPL) materials, which are based on inorganic systems containing rare elements and with preparation temperatures of at least 1000 °C, exhibit afterglow times of more than 10 h and can be tuned for different applications. However, the development of this field is hindered due to the large thermal energy consumption and the need for nonrenewable resources. Thus, the development of a "green" design and preparation of LPL materials is of some importance. A doped-crystalline material based on two metal-free organic small molecules is easily prepared through ultrasonic crystallization at room temperature. It has a high-quality, singlecrystalline structure, and visible LPL performance with a duration of more than 6 s upon low-energy photoexcitation. A green, flexible, and convenient screen-printing technology for controllable pattern anticounterfeiting is then developed from this purely organic material, which improves the prospects for commercial utilization in the future.
We demonstrate the preparation of diacenaphthopentalene derivatives via a palladium-catalyzed dimerization of 1-iodo-2-arylethynyl-acenaphthylenes. The resulting 7,14-diarylpentaleno[1,2-a:4,5a']diacenaphthylenes, which contain four linearly fused five-membered rings, are benchtop stable and behave as hole-transporting or ambipolar semiconductors in organic field effect transistors. The X-ray crystal structure shows the important role of the fused naphthalene unit that enforces a formal pentalene subunit at the central five-membered rings and [5]-radialene-like structures at the proximal five-membered rings. Nucleus-independent chemical shift (NICS) calculations show the internal pentalene rings are intermediate in antiaromaticity character between known pentalene and dibenzopentalenes derivatives. The diacenaphthopentalene derivatives give high optical gap materials owing to a forbidden HOMO to LUMO transition, yet have narrow electrochemical gaps and are reduced at small negative potentials giving LUMO energy levels of -3.57 to -3.74 eV.
Three systems were designed, synthesized,
and characterized to
understand decay processes of photoinduced charge separation in organic
semiconductors that are imperative for efficient solar energy conversion.
A styrene-based indoline derivative (YD) was used as donor moiety
(D), a triazine derivative (TRC) as the first acceptor (A1), and 9,10-anthraquinone (AEAQ) as a second acceptor (A2) in constructing two systems, YD-TRC and YD-TRC-AEAQ. The lifetime
of the photoinduced charge-separated states in YD-TRC, a D–A1 system, was found to be 215 ns and that in YD-TRC-AEAQ, a
D–A1–A2 system, to be 1.14 μs, a 5-fold increase
with respect to that of the YD-TRC. These results show that YD is
a more effective donor in YD-TRC and YD-TRC-AEAQ systems at forming
long-lived charge-separated states compared to a previously reported
atriphenylamine derivative (MTPA) that generated charge-separated
states with a lifetime of 80 ns in MTPA-TRC and 650 ns in MTPA-TRC-AEAQ.
The third system was constructed using a metal-free porphyrin derivative
(MHTPP) to form a MHTPP-TRC-AEAQ structure, a D–L (linker)–A
system with a charge separation lifetime less than 10 ns. Therefore,
the D–A1–A2 architecture is the
best at generating long-lived charge-separated states and thus is
a promising design strategy for organic photovoltaics materials.
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