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Handbook of Aggregation-Induced Emission, Volume 2


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the other hand, due to the symmetry of TPP, its researches on the reticular chemistry have sprung up. For example, TPP‐based organic cage and metal–organic framework (MOF) can be designed easily to exhibit self‐assembling and sensing properties. Herein, we summarize recent research efforts on the development of this AIE system, including synthesis and functions, and we hope, with this chapter, new ideas could be stimulated to exploit the advanced functional materials based on TPP.

       1.2.1 Cyclization Reaction

Schematic illustration of reaction mechanism of synthesizing TPP with benzoin and ammonia. Schematic illustration of current synthetic routes to TPP.

      This method not only affords TPP readily but is also useful for preparing its derivatives with diverse structures. For example, by using mono‐ or disubstituted benzoin, di‐ or tetrasubstituted TPP derivatives can be easily obtained. The reaction is less affected by the electronic effect of substituents. However, if the substituents are bulky, the crude products are difficult to purify by recrystallization. It is worth noting that two isomers are usually formed by using monosubstituted benzoin in the reaction. Such behavior is similar to that in the preparation of disubstituted TPE derivatives by the McMurry coupling reaction [44]. The presence of isomerization in TPP derivatives is proved by the fact that four resonance signals exist around 148 ppm in their 13C NMR spectra due to the four different chemical environments of carbon atoms in the pyrazine ring [33].

      Subsequently, Tamaddon found that the multicomponent reaction can be carried out without SnCl2·2H2O as catalyst (Scheme 1.2, Route A, Condition 3) [46]. That is, SnCl2·2H2O is not necessary in the reactions. By directly heating the solid mixture of benzoin and ammonium acetate at 80 °C, the product can be obtained in a very high yield. Overall, this reaction is very close to the original one reported by Laurent, Erdmann, Japp, and Wilson, except that the ammonium chloride has been replaced by ammonium acetate. This optimal reaction condition was confirmed by the author after evaluation of the influence of ammonium salt, solvent, and reaction temperature on the reaction efficiency. The yields remain high in the reaction of benzoin derivatives regardless of the electron effect of the substituents. The reaction mechanism was similar to the previous one. Ammonium acetate releases the ammonia by heating to react with benzoin to generate an intermediate. Because the ammonium acetate is subtly excess, few acetic acid is formed, which can hardly react with the intermediate to produce 2‐methyl‐4,5‐dipenylglyoxaline. On the other hand, the solid‐state reaction