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Handbook of Aggregation-Induced Emission, Volume 2


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tune the structures and photophysical properties of DSA effectively [51, 52].

      The intrinsic photophysical process of DSA and four derivatives 1‐1, 2‐2, 2‐7, and 2‐8 upon excitation were studied by steady‐state and ultrafast spectroscopy. It was confirmed that the intramolecular rotation around the vinyl moiety plays the vital role in the whole photophysical process besides the electronic properties of the peripheral substituents. In dilute solutions, these molecules have twisted structures in the ground state, which can relax to planar structures within picoseconds. The fluorescence process is dominated by the relaxed excited state, and the quantum yield is affected by the competition between the nonradiative and radiative deactivations. The enhanced fluorescence of the molecules in aggregated states originates from the optically allowed S1S0 transition as well as the suppressed nonradiative deactivation via molecular stacking. The results furnish an in‐depth understanding of the origin of the aggregation‐enhanced emission process [53].

Schematic illustration of small molecules and macromolecules of DSA derivatives that exhibit high solid-state luminescence.

      The electronic structures and charge transport properties of DSA and three DSA derivatives 2‐2, 2‐9, and 2‐10 were investigated by density functional theory. The results indicate that DSA and the derivatives have high charge mobility and high solid‐state fluorescent efficiency. The introduction of one electron‐withdrawing group, cyano group, to DSA decreases the reorganization energy of holes, which is conducive to the high hole mobility of 2‐9. The hole mobility of 2‐9 is of the same order of magnitude as that of DSA. However, the electron mobility of 2‐9 is about 30 times lower than that of DSA owing to its larger reorganization energy and disadvantageous transfer integral of electrons. As to the electron‐donating substituted molecules, 2‐2 and 2‐10, they exhibited lower charge mobility compared to DSA because of the steric hindrance of the substituents. However, both of them tend to exhibit balanced transport properties, which primarily results from the balanced values of transfer integrals for both hole and electron [55].

Schematic illustration of single crystal of 2-7 under UV light (365 nm), and the perspective view of unit cell structure of 2-7 along the b axis

      Source: Reproduced with permission from Ref. [56].

      A uniaxially oriented crystal from 2‐12, which exhibited an excellent waveguide and polarization performance, was prepared by Tian et al. It was found that the low loss coefficient (2.75 cm−1) and the high polarization contrast (0.72) result from the uniaxially oriented packing and layer‐by‐layer molecular structure in the 2‐12 crystal. Furthermore, ASE was observed from the 2‐12 crystal with a low threshold of 265 μJ/cm2, and the gain coefficient was 52 cm−1 at a peak wavelength of 509 nm. These properties of the 2‐12 crystal indicate that it has potential application in the field of optical waveguides and organic solid‐state lasers [58].

      Tian et al. prepared two polymorphs (the block‐like crystal C1 and needle‐like crystal C2) of a supramolecular cocrystal by self‐assembly with an AEE‐active luminogen 1‐2 as the luminescent host molecule and an aromatic molecule 1,3,5‐trifluoro‐2,4,6‐triiodobenzene (FIB) as the guest molecule. The two polymorphs of C1 and C2 were obtained by slow solvent evaporation at room temperature under the rigorous exclusion of light. The self‐assembly behavior, molecular stacking structures, and photophysical properties of C1 and C2 were investigated. The block‐like crystal C1 packed in segregated stacking with strong ππ interactions between the host and guest molecules. It showed weak green emission with a low efficiency (ΦF) of 2%. However, the needle‐like crystal C2, packed in segregated stacking with no obviously strong intermolecular interactions, showed a bright yellow emission. In addition, C1 exhibited obvious mechanochromic behavior, and the fluorescence of C1 showed a red‐shift after grinding and recovered to the initial state by itself after 24 hours at room temperature. Specifically, the emission peak of C1 changes from the initial 510 nm to the final 546 nm under grinding, whereas it returns to 515 nm after 24 hours [59].

      In addition, Yang et al. introduced the DSA molecule to bridge two pillarenes to form a dimeric host, which can assemble into a linear supramolecular polymer upon cooperatively binding to a neutral guest linker and then achieving a yellow fluorescence emission in solution and solid states [60].

      Besides