Handbook of Aggregation-Induced Emission, Volume 1. Группа авторов. Читать онлайн. Newlib. NEWLIB.NET

Автор: Группа авторов
Издательство: John Wiley & Sons Limited
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Жанр произведения: Химия
Год издания: 0
isbn: 9781119642893
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be hindered and make the excitons stabilized in the higher excited state to generate enhanced anti‐Kasha emission. However, these results still remain controversial. Zhou et al. have recently employed more DFT functions to recheck the excited‐state properties of the BODIHY derivatives and have challenged the SOKR mechanism [11b]. They have found that the TDA‐PBE method used in Ref. [11a] may not describe the correct order of the excited states, and the energy gaps between S3 and S2 states obtained from this method are small enough to generate efficient internal conversion from S3 and S2 states. Hence, the emission of BODIHY derivatives in higher viscosity may not be induced by the SOKR. Instead, they proposed that the restriction of access to the CI caused by the flip‐flop motion is responsible for the AIE behaviors of BODIHY derivatives.

      Exciton population on the higher excited states can also occur in the triplet states. Taking the ClBDBT as an example (Figure 1.9c, d), it exhibits white‐light emission under UV light and persistent yellow afterglow in the room temperature [11d]. According to the calculated energy levels, T1 and T2 states are all lower than the S1 state in energy, which makes both T1 and T2 accessible for the exciton population coming from the S1 state. Furthermore, the T2 state mainly contains the (n,π*) transition character, which leads to a larger spin–orbit coupling (SOC) between T2 and the S0 and a higher radiative decay rate, whereas the T1 state contains more (π,π*) transition character. At room temperature, the small energy gap between T2 and T1 can promote the thermal population from T1 to T2. According to Boltzmann distribution, T2 has a smaller population than T1, but the faster radiative decay from T2 results in a balanced emission intensity from both T2 and T1 states. Thus, the combined anti‐Kasha blue light from T2 and the yellow light from T1 generate the efficient white‐light emission at room temperature.

      In fact, it is also the RIM process in the crystal state that stabilizes the specific electronic structures of T2 and T1 and restricts the nonradiative decay from triplet states to the ground state, and then the balanced dual emission can be restored.

Schematic illustration of molecular structure, calculated energy levels, fluorescence, and internal conversion rate constants of DMF-BP-PXZ in the (a) solution and (b) solid state.

      Source: Adapted from Ref. [11c] with permission from John Wiley and Sons.

      (c) Molecular structure, calculated energy levels, and (d) emission spectra of ClBDBT in the solid state.

      Source: Adapted from Ref. [11d] with permission from Springer Nature.

      Most of the classical AIEgens are constructed by chromophores with through‐bond conjugation (TBC), and their emission can be enhanced through restricting the nonradiative decay driven by molecular motions, whereas the light emission can also be boosted by promoting the radiative rates through the through‐space conjugation (TSC) [13]. The TSC plays a key role in radiative decay processes of molecular systems with clusterization‐triggered emission (CTE) property [21]. Moreover, a certain degree of molecular motions in the solid state will facilitate the intra‐ or intermolecular excited‐state TSC for the nonconjugated molecules and stabilize the radiative channels and, thus, promote the emission intensity [13].

      1.6.1 Clusterization‐Triggered Emission

Schematic illustration of (a) the cluster formation, energy variation, and (b) the formation of through-space conjugation involved in the CTE.