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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821 1.22 × 108 1.66 × 109 6.86 In solid phase HPS [37] 3.48 5.85 403 6.56 × 107 2.06 × 107 76.0 TPS [38] 3.26 0.60 932 1.15 × 106 3.32 × 106 25.8 BrTPS [38] 2.91 1.80 890 8.12 × 106 1.50 × 106 82.3 HPS [38] 2.70 5.90 753 7.43 × 107 1.57 × 106 97.9 BTPES [38] 2.49 5.75 592 6.57 × 107 1.93 × 106 97.1 BFTPS [38] 2.30 9.10 607 1.14 × 108 1.07 × 107 91.4

      The reorganization energy analysis from S1 → S0 process for each normal mode in the gas phase reflects that the C=O stretching vibration contributes the most (∼1974.37 cm−1), consistent with the corresponding large structural modification (0.08 Å between S0 and S1). However, in the solid phase, this value is reduced to 212.96 cm−1 and the corresponding structural change is only 0.01 Å. Such a remarkable reduction is due to the alternation to ππ* electronic transition, which is decoupled with the C=O stretching vibration. As a result, from the gas to solid phases, kic decreases about 1 order of magnitude from 4.97 × 107 to 5.15 × 106 s−1. That is, the nonradiative decay process is blocked by the decoupling between the high‐frequency C=O stretching vibration and transition electrons (Figures 2.2c and 2.4b). Overall, the largely accelerated radiative decay rate and slowed nonradiative decay rate induce the observed strong fluorescence in the solid phase [41].

      2.3.3 Bending Vibration of Bonds

Schematic illustration of calculated reorganization energies versus normal mode of (a) HPS, (b) TPA, (c) (CAACAd)CuCl, and (d) COTh in both gas/solution and solid phases, respectively.

      2.3.4 Flipping Vibrations of Molecular Skeletons