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 π → π* 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
(CAACAd)CuCl (see Figure 2.3) is a two‐coordinate Cu(I) complex, which exhibits highly efficient fluorescence in aggregate [50]. The excited‐state decay dynamics for (CAACAd)CuCl in both solution and solid states is studied by the hybrid QM/MM approach, coupled with the TVCF rate formalism [42]. Analyzing the geometrical changes between S0 and S1 upon excitation, it is found that the complex is more flexible in solution. The largest changes appear in the coordination bond angles between copper and two ligands with ∠C1−Cu−Cl, ∠Cu−C1−N, and ∠Cu−C1−C4 decreasing from 9.67°, 12.82°, and 10.73° in solution to 3.66°, 4.46°, and 6.75° in the solid phase, respectively. And the transition character changes from metal‐to‐ligand charge transfer (MLCT) to hybrid MLCT and halogen‐to‐ligand charge transfer (XLCT) upon aggregation. The kr are close in both phases, while kic decreases by about 3 orders of magnitude from 8.38 × 107 to 1.47 × 104 s−1 (see Table 2.2). The λtotal decreases a lot from solution (7121 cm−1) to solid state (2274 cm−1). It is found that the largest contributions to λtotal come from several low‐frequency bending modes and one high‐frequency stretching mode in solution. These low‐frequency modes are assigned to be the bending vibrations associated with coordination bonds C1−Cu and Cu−Cl, and the high‐frequency mode belongs to the stretching vibration of the C−N bond in carbene ligand. Upon aggregation, the vibrations of angles C1−Cu−Cl and Cu–C1–N are restricted largely, while the stretching vibrations of the C1−N bond are insensitive to the environment (Figure 2.4c). Overall, the strong solid‐state fluorescence of (CAACAd)CuCl is induced by removing the nonradiative decay channels owing to the decoupling between transition electron and the bending vibrations of coordination bonds (see Figure 2.2d).
Figure 2.4 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
Cyclooctotetraene (COT) is a prototype molecule with nonaromatic annulenes [51–53]. The COT derivative cyclooctatetrathiophene (COTh) was found to be AIE active and its AIE mechanism was further investigated theoretically and experimentally [43]. The theoretically optimized geometries in the S0 and S1 states show that the isolated COTh is much more flexible than that in a cluster. For example, from the S0 to S1 state, the modifications of the dihedral angles ΘI–II and ΘII–III (I, II, and III denote the aromatic rings marked in Figure 2.3) are 22.82° and 24.22° in the gas phase, much larger than those in the solid state of 12.78° and 12.96°. Upon excitation, the dihedral angles between the neighboring thienyl rings are decreased from S0 to S1. As shown in Table 2.3, for example, ΘI–II decreases from 44.93° to 22.11° in the gas phase, while it reduces from 43.84° to 31.06° in the solid phase, indicating a better planarity of the central large eight‐membrane ring. Therefore, the conjugation of the central eight‐membrane improves and the oscillator strength of S1 enhances accordingly. In addition, the excitation energy at the S1 geometry increases from 2.42 eV in the gas phase to 2.69 eV in cluster. Therefore, kr increases from 9.80 × 104 to 6.05 × 105 s−1, owing to the enhancement of oscillator strength and excitation energy; see Table 2.2. The kic is closely related to the reorganization energy. For COTh, the λtotal decreases to 636 meV in crystal from 860 meV in the gas phase and then the kic decreases by 2 orders of magnitude. Thus, the ΦF in the crystal is 3 orders of magnitude