Solid
state luminescence enhancement (SLE) of conjugated organic
materials has had a great impact in materials science, but a deep
understanding has been rather limited to date. Here, we investigate
a prototype example of SLE materials, cyano-substituted distyrylbenzene
(DCS), by varying systematically and subtly the substitution pattern
(inter alia of the position of the cyano-substituent)
to give largely different photoresponse in fluid and solid solution
as well in the crystalline state. The combination of quantitative
(ultra)fast optical spectroscopic techniques, appropriate quantum-chemical
methods, and structural (X-ray) data allows us to elucidate and rationalize
all details of the SLE process, including steric versus electronic
factors, radiative versus nonradiative decay channels, and intra-
versus intermolecular contributions, providing a first holistic picture
of SLE.
We have rationally designed a densely packed 1:1 donor-acceptor (D-A) cocrystal system comprising two isometric distyrylbenzene- and dicyanodistyrylbenzene-based molecules, forming regular one-dimensional mixed stacks. The crystal exhibits strongly red-shifted, bright photoluminescence originating from an intermolecular charge-transfer state. The peculiar electronic situation gives rise to high and ambipolar p-/n-type field-effect mobility up to 6.7 × 10(-3) and 6.7 × 10(-2) cm(2) V(-1) s(-1), respectively, as observed in single-crystalline OFETs prepared via solvent vapor annealing process. The unique combination of favorable electric and optical properties arising from an appropriate design concept of isometric D-A cocrystal has been demonstrated as a promising candidate for next generation (opto-)electronic materials.
We have designed and synthesized asymmetric cyano-stilbene derivatives containing trifluoromethyl (-CF(3)) substituents with the aim of producing tightly packed pi-dimer systems that as crystals exhibit reversible [2 + 2] cycloaddition with characteristic fluorescence modulation. (Z)-3-(3',5'-Bis(trifluoromethyl)biphenyl-4-yl)-2-(4'-(trifluoromethyl)biphenyl-4-yl)acrylonitrile (CN(L)-TrFMBE) and its derivatives were found to form antiparallel pi-dimer stacks in crystals due to their specific intermolecular interactions, including C-F...H and C-F...pi interactions. The CN(L)-TrFMBE pi-dimer crystals (and powder) are not at all fluorescent initially but switch to a highly fluorescent state (Phi(PL) = 24%) when an external shear-strain and/or prolonged UV (365 nm) irradiation is applied. Our experimental and theoretical investigations show that the fluorescence modulation in this particular system is due to the external and/or internal (in the case of UV irradiation) shear-induced lateral displacement of the pi-dimer molecular pair, which effectively turns the fluorescence emission on at the cost of frustrated [2 + 2] cycloaddition. Further, the fluorescence 'off' state can be restored by thermal annealing, which regenerates the tightly packed pi-dimer by reverse displacement together with the thermal dissociation of the [2 + 2] cycloaddition product. This system provides a very rare example of high-contrast reversible fluorescence switching that is driven by a change in the molecular packing mode in the solid state, which enables piezochromic and photochromic responses.
A novel donor-acceptor-donor triad that exhibits fluorescence on-off switching with high contrast ratio (ca. 10(3) ) in response to a mechanical stimulus in the solid state is reported. This system provides a very unique example of high-contrast fluorescence switching that is driven by a mechanical-force-controlled photo-induced electron transfer (eT) in molecular assemblies.
We describe the preparation of highly efficient stimulus-responsive fluorescence color-tuning in self-assembled supramolecular scaffold systems. The systems consisted of a photochromic compound (BP-BTE) in combination with unique luminescent organic materials (CN-MBE, TPS-CNMBE, TPA-2CNMBE) that exhibited intense fluorescence in the solid state. The emission spectrum was tuned by introducing fluorescence resonance energy transfer and photochromic switching capabilities into the system. The materials were used to successfully demonstrate novel fluorescence patterns that were responsive to multiple stimuli, displayed reversible fluorescence switching, and provided a nondestructive readout of the fluorescence signal.
Three-in-one: A novel distyrylbenzene-based material forms J-type aggregates in single crystals with highly polarized and bright red emission, giving rise to optical gain narrowing, for which different mechanisms (amplified spontaneous emission, laser emission and stimulated resonance Raman scattering) are observed. These are correlated with the favorable intrinsic and macroscopic properties of the crystal, in particular to the orientation of the molecules to the crystal surface.
Fluorescence switching or modulation of π-conjugated molecules
is of great interest in the area of optoelectronic materials science
and technology because of their promising applications. However, the
“concentration fluorescence quenching” problems commonly
associated with conventional π-conjugated molecules in the solid
state were occasionally an obstacle to use of π-conjugated
molecules in high-contrast memory storage devices. We designed and
synthesized a novel class of fluorescence switching π-conjugated
molecule, (Z)-CN-MBE, that exhibits a reversible
photo/thermal E/Z isomerization process, accompanied
by a remarkable fluorescence on/off switching in the solid state.
This may provide a promising way to construct high-contrast optical
binary memory storage devices. (Z)-CN-MBE is virtually
nonfluorescent but exhibits an extraordinary Z to E isomerization upon external light/thermal stimuli even
in the solid state with a concomitant drastic fluorescence enhancement
owing to the unique “aggregation-induced enhanced emission”
(AIEE)’ phenomenon of its trans isomer.
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