DOI:
10.1039/D2TC01093C
(Paper)
J. Mater. Chem. C, 2022,
10, 13797-13804
Modulation of the intramolecular hydrogen bonding and push–pull electron effects toward realizing highly efficient organic room temperature phosphorescence†
Received
18th March 2022
, Accepted 9th April 2022
First published on 12th April 2022
Abstract
The exploitation of ultralong organic room temperature phosphorescence (UORTP) materials lags far behind the need because of the lack of general design strategies. Here we proposed a facile design strategy based on the structural control of intramolecular hydrogen bonding (IHB) and push–pull electron effects (PPEEs) to construct highly efficient UORTP materials. Two series of carbazole derivatives with different IHBs and PPEEs were designed accordingly. By enhancing the IHB interactions of the luminophores, the molecular planarity, intermolecular interactions and packing mode were effectively tuned, facilitating the intermolecular electron coupling. PPEEs, enhanced by introducing heteroatoms and heavy atoms, strengthened the intramolecular charge transfer states, which changed the orbital transition configuration of excited states, thus boosting the intersystem crossing (ISC) and spin–orbit coupling (SOC). Consequently, CzPM and CzPMBr with dual IHBs and the strongest PPEEs exhibited ultralong lifetimes (τP) of 1.31 s and 233 ms with the highest phosphorescence quantum yields (ΦP) of 1.7% and 48.6% in their series, respectively. Theoretical investigations revealed that the high-lying intersystem crossing (HISC) between excited singlet states (Sm, m > 1) and triplet states (Tn, n > 1) occurred and played a vital role in enhancing the ΦP values of UORTP materials. Significantly, the SOC matrix elements between S3 and T7 (ξ(S3,T7)) of CzPMBr reached up to 39.95 cm−1. Finally, CzPMBr was successfully used as an anti-counterfeiting ink in calligraphy and painting due to its excellent RTP properties. The design strategy based on the structural control of IHBs and PPEEs will greatly widen the design platform of UORTP materials. Meanwhile, the discovery of the HISC process will also provide a new insight for the design of UORTP materials.
Jianguo Wang
| Prof. Jianguo Wang was born in Inner Mongolia (China). He received his PhD in 2014 from the Institute of Chemistry, Chinese Academy of Sciences (ICCAS) under the supervision of Prof. Deqing Zhang. He spent two years as a postdoctoral fellow in Prof. Ben Zhong Tang's group at the Hong Kong University of Science and Technology (HKUST). In 2019, he started his research group as a Professor at Inner Mongolia University. His research interests focus on organic optoelectronic materials with aggregation-induced emission (AIE) features for disease diagnosis and treatment. |
Introduction
In the last decade, ultralong organic room temperature phosphorescence (UORTP) materials with durations ranging from several seconds to hours have become the focus of scientific research for their potential applications in optoelectronic technologies,1–6 such as anti-counterfeiting,7–13 information storage,14–18 chem/biosensors,19–21 and bioimaging.22–28 Being superior in terms of structural versatility, flexibility, processability and biocompatibility, UORTP materials have displayed broader development prospects and are ideal alternatives to inorganic phosphors.29–32 However, different from the well-developed inorganic counterparts, the design and formulation of pure organic room temperature phosphorescence (RTP) luminophores with bright and long-lived emissions remain to be further explored, due to the inherent problems of organic molecules including inefficient intersystem crossing (ISC)33 and rapid nonradiative decay rate.34,35
According to the first-order perturbation theory, Fermi Golden Rule and Marcus–Levich–Jortner theory, the rate constants of ISC (kISC) are positively correlated with the spin–orbit coupling (SOC) Hamiltonian and the energy gap (ΔEST) between the lowest excited singlet (S1) and triplet states (Tn).36 Thus, boosting SOC or minimizing the ΔEST of organic compounds is an effective approach to obtaining highly efficient UORTP luminophores.37–40 Common strategies to promote SOC focus on introducing heavy atoms or heteroatomic groups (e.g. CO, N, S, P, etc.) with lone pair electrons.41–43 For example, Kim et al. found that the halogen bonding in crystals can activate the heavy atom effect, achieving strong RTP emission with a phosphorescence quantum yield (ΦP) of up to 55%.44 Chi and coworkers proposed the intermolecular electronic coupling of n electrons and π units with different excited-state configurations, which can facilitate the ISC process.43 In terms of reducing ΔEST, methods including intramolecular donor–acceptor interactions and polymerization have been employed. Tang et al. reported an efficient UORTP luminophore with a lifetime of 795 ms and ΦP of 2.1% by structural isomerism tuning in ΔEST and the first excited triplet state (T1) configuration.45 Zhang et al. proposed polymerization-induced energy splitting to create small ΔEST and thus to promote ISC.46 On the other hand, suppression of nonradiative deactivation pathways of triplet excitons, such as crystallization,47,48 polymer–matrix assistance,49–51 host–guest interactions,52–58 H-aggregation,59 intermolecular halogen bonding,60 ionic crystals,61 and self-assembly,62,63 was also found to play critical roles in constructing UORTP luminophores. Although these strategies have largely promoted the development of UORTP materials, most of them are based on the modulation of intermolecular interactions with poor operability. Therefore, a facile design strategy of UORTP materials, which directly correlates molecular structure with phosphorescence performance, is highly desired.
Based on the above considerations, we proposed a facile strategy for modulating intramolecular hydrogen bonding (IHB) and push–pull electron effects (PPEEs) to construct UORTP luminophores with high ΦP. We envisaged that molecular planarization can be manipulated by IHB, thus conducive to promoting conjugation and inducing intermolecular π–π interactions. In addition, the intramolecular PPEEs improved by the introduction of heteroatoms and heavy atoms can probably lead to decreased ΔEST and increased SOC. Meanwhile, the π–π interactions induced by IHBs and PPEEs are expected to promote intermolecular electron coupling, thus obtaining efficient UORTP materials (Scheme 1). To verify our hypothesis, six compounds were designed and synthesized in two series (with and without heavy atoms), namely 9-phenyl-9H-carbazole (CzPh), 9-(pyridin-2-yl)-9H-carbazole (CzPy), 9-(pyrimidin-2-yl)-9H-carbazole (CzPM), 9-(4-bromophenyl)-9H-carbazole (CzPhBr), 9-(5-bromopyridin-2-yl)-9H-carbazole (CzPyBr), and 9-(5-bromopyrimidin-2-yl)-9H-carbazole (CzPMBr). As shown in Fig. 1A, each compound contained a donor group (carbazole) and an acceptor group (phenyl, pyridinyl or pyrimidinyl derivatives). The experimental results demonstrated that IHBs and PPEEs gradually intensified with increasing numbers of nitrogen atoms in the acceptor group. As a result, the molecular structure became planar and intermolecular π–π interactions were remarkably enhanced. In particular, CzPM and CzPMBr with dual IHBs and the strongest PPEEs exhibited the phosphorescence lifetimes (τP) of 1.31 s and 233 ms with ΦP values of 1.7% and 39.7%, respectively. Theoretical calculations revealed that IHB-induced planarization together with PPEEs greatly contributed to the increased SOC. More interestingly, high-lying intersystem crossing (HISC) from excited singlet states (Sm, m > 1) to triplet states (Tn, n > 1) was found in the compounds CzPM and CzPMBr with strong IHBs and PPEEs, accounting for higher ΦP values. In short, this work demonstrates that highly efficient UORTP materials can be successfully achieved by structural control of IHBs and PPEEs, promoting the rapid development of UORTP materials.
|
| Scheme 1 Illustration of the structural control strategy of IHBs and PPEEs for boosting the efficiency of UORTP materials. | |
|
| Fig. 1 (A) Chemical structures and phosphorescence properties of CzPh, CzPy, CzPM, CzPhBr, CzPyBr, and CzPMBr in the crystalline state. (B) Photographs of the six crystalline solids taken before (left) and after (right) switching off the 365 nm excitation source. Prompt (unfilled) and delayed (filled) PL spectra (C and D) and time-resolved decay of phosphorescence (E and F) of CzPh (black), CzPy (red), CzPM (blue), CzPhBr (navy), CzPyBr (purple), and CzPMBr (pink) in the crystalline state at 298 K. The delayed PL spectra were taken after a delay of 50 ms. Excitation wavelength: 360 nm. | |
Results and discussion
Synthesis and characterization
Six carbazole derivatives were synthesized via a one-step reaction in high yields (Schemes S1–S6, ESI†) and characterized by standard spectroscopic methods with satisfactory results (Fig. S1–S18, ESI†). All compounds were purified multiple times by high-performance liquid chromatography and recrystallization (Fig. S19, ESI†). Their single crystals were obtained by slow solvent evaporation of ethyl acetate and characterized crystallographically (Table S1, ESI†).
Photophysical performance
First, the absorption spectra of the obtained six compounds were recorded as shown in Fig. S20 (ESI†). The experimental results showed that they have similar absorption bands. All compounds in the crystalline state exhibited typical RTP characteristics with an afterglow of a few seconds after removing 365 nm excitation (Fig. 1B and Fig. S21, ESI†). Steady-state photoluminescence (PL) spectra were recorded to further investigate their photophysical properties. As shown in Fig. 1C, for CzPh, CzPy and CzPM without heavy atoms, their prompt PL spectra showed a strong fluorescence band at 360–500 nm with lifetimes of 50.54 ns (@430 nm for CzPh), 4.32 ns (@382 nm for CzPy) and 8.6 ns (@400 nm for CzPM) (Fig. S22–S24 and Tables S2–S4, ESI†) at room temperature, respectively. In particular, for CzPM, apart from the dominant high-energy fluorescence band, weak dual emission in the long-wavelength region (500–720 nm) was also captured in its prompt PL spectrum. The delayed PL spectra of the three compounds were found to be very similar at a low-energy region of 500–720 nm (Fig. 1C). The τP values were calculated to be 579 ms (@550 nm), 197 ms (@550 nm) and 1.31 s (@530 nm) for CzPh, CzPy and CzPM at room temperature, respectively (Fig. 1A, E and Tables S5–S12, ESI†). Their τP was significantly prolonged under vacuum due to isolation from moisture and oxygen (Tables S13–S15, ESI†). These results indicate that CzPh, CzPy and CzPM have UORTP properties. Their absolute ΦP (integrating sphere method) increases gradually from 0.4% to 1.7% with the addition of nitrogen atoms to the acceptor moiety, which is entirely consistent with our expectation (Fig. 1A). Their variable temperature steady-state and transient PL spectra were recorded (Fig. S25–S33, ESI†). When the temperature was lowered from 298 K to 80 K, the intensity of their phosphorescence signal gradually increased, and their τP increased to 966 ms, 808 ms and 1.88 s, respectively (Fig. S25, S28, S31 and Tables S6, S9, S12, ESI†). Additionally, as the temperature decreased, a new phosphorescence band at 488 nm gradually appeared for the three compounds. This implies that at low temperatures, the triplet excitons in Tn may transfer directly to the ground state (S0) without passing through T1via internal conversion. Notably, different from CzPh and CzPy, some unique features were observed for CzPM. An emission band at 360–450 nm with a lifetime of 435 ms at 298 K was recorded in the delayed PL spectrum (Fig. 1C and Table S10, ESI†). The emission intensity remarkably enhanced at 340 K, but almost completely disappeared at 240 K (Fig. S31 and S32, ESI†), which can be attributed to triplet–triplet annihilation (TTA).
To confirm the applicability of our design strategy, CzPhBr, CzPyBr and CzPMBr were designed by introducing bromine atoms. As expected, their ΦP increased to 1.8%, 14.1% and 48.6%, respectively (Fig. 1A), compared to their heavy atom-free counterparts CzPh, CzPy and CzPM. Interestingly, ΦP was proportional to the number of nitrogen atoms in the acceptor moiety. This indicated that the anticipatory design strategy of UORTP materials is of certain universality. The steady-state PL spectra showed that the three brominated compounds possessed a stronger phosphorescence emission band at 500–720 nm than their counterparts (Fig. 1D). In particular, for CzPyBr and CzPMBr, even in the prompt PL spectrum, there was still a stronger phosphorescence band than the fluorescence band, which can be ascribed to more efficient SOC between the Sm and Tn promoted by the heavy atom effect and PPEE. The τP of these brominated compounds is shortened to 293 ms (CzPhBr), 65 ms (CzPyBr) and 233 ms (CzPMBr), respectively (Fig. 1A and F). The brominated compounds also displayed temperature and oxygen dependent phosphorescence behaviours (Fig. S34–S44 and Tables S16–S27, ESI†). Additionally, a new phosphorescence band (Tn → S0) at 450–500 nm with τP values of 150 ms (@460 nm) for CzPhBr and 60 ms (@470 nm) for CzPyBr appeared and increased gradually, which is similar to that of their heavy atom-free counterparts (Fig. S35, S39 and Tables S17, S21, ESI†).
The phosphorescence spectra of all compounds exhibited excitation wavelength dependence (Fig. S45, ESI†). Time-resolved emission spectra further showed that CzPy displayed an intense phosphorescence emission band around 450 nm even at room temperature (Fig. S46, ESI†). This may be due to the fact that CzPy has more triplet states lower than S1. For CzPM, a TTA emission band centered at 400 nm was clearly observed, indicating that TTA could easily occur due to the longest τP of 1.31 s and efficient population of Tn states.
Single crystal diffraction analyses
Single crystal X-ray diffraction analyses were carried out to further uncover the origin of enhanced ΦP. As shown in Fig. 2A, two molecular conformations were observed in the single crystal structures of CzPh and CzPy, while only one conformation was recorded for the other four compounds. For CzPh, the dihedral angles between the carbazole and benzene rings in two conformations were 77.60° and 53.46°, respectively. For CzPy with pyridine as the acceptor moiety, a single hydrogen bond between the carbazole and pyridine rings was found at distances of 2.771 Å and 2.630 Å for each conformation, leading to decreased dihedral angles of 56.93° and 47.20°. When pyrimidine served as the acceptor, CzPM was almost planar with a dihedral angle of 5.87°, accompanied by shorter IHB distances of 2.291 Å and 2.312 Å. Similar tendencies were found in CzPhBr, CzPyBr and CzPMBr. Their dihedral angles between the donor and acceptor were found to be 48.44°, 38.13°, and 4.93°, respectively. IHB interactions were not observed in CzPhBr. For CzPyBr, the distance of the IHB was 2.498 Å, and stronger IHB interactions at 2.316 Å and 2.320 Å were observed for CzPMBr. This elucidated that the molecular conformation was driven to be planar by progressively strengthened IHBs. Since intermolecular packing modes of organic phosphors are directly correlated with their molecular structures and conformations, the intermolecular packing of the six phosphors was further investigated. As depicted in Fig. 2B and Fig. S47, S48 (ESI†), the intermolecular interactions of CzPh and CzPhBr were mainly C–H···π interactions, with the absence of π–π interactions. In addition, dual Br–H interactions between adjacent CzPhBr molecules were also observed. These C–H···π and Br–H interactions efficiently suppressed the nonradiative transition of triplet excitons, which contributed a lot to their phosphorescence behaviours. In the single crystal of CzPy, apart from plentiful C–H···π interactions, weak π–π (3.438 Å) and intermolecular hydrogen bonding (N···H 2.574 Å) interactions were observed (Fig. 2B and Fig. S49, ESI†). Compared to CzPy, stronger dual π–π interactions (3.423 Å and 3.456 Å) rendered the two adjacent CzPyBr molecules in an antiparallelly head-to-tail arrangement in their crystal structures (Fig. 2B), and the two adjacent layers were locked by intermolecular hydrogen bonding (N···H 2.720 Å) and Br···Br interactions (3.304 Å) (Fig. S50, ESI†). We assumed that the antiparallel arrangements coupled with the stronger intermolecular PPEE of CzPyBr dominantly contributed to its layered stacking pattern and needle-like crystal shape. CzPM and CzPMBr with dual IHB interactions and near-planar structure presented parallel head-to-tail arrangements with strong π–π interactions, forming J-aggregates as a result (Fig. 2B and Fig. S51, S52, ESI†). Also, the intermolecular PPEEs between the carbazole and pyrimidine of adjacent molecules may enhance the intermolecular electronic coupling which greatly promoted the ISC rate. Together, the synergistic effect of J-aggregates and intermolecular electronic coupling induced by π–π stacking and intermolecular PPEEs endowed CzPM and CzPMBr with the highest ΦP in their series. These results again manifested that highly efficient UORTP can be achieved by enhanced IHBs and PPEEs through regulating the planarity and packing mode of molecular structures.
|
| Fig. 2 (A) Single crystal structures, conformations, dihedral angles and intramolecular hydrogen bonding distances of CzPh, CzPy, CzPM, CzPhBr, CzPyBr, and CzPMBr. (B) C–H···π and π–π interactions of CzPh, CzPy, CzPM, CzPhBr, CzPyBr, and CzPMBr. | |
Theoretical calculation
To further reveal the essence of the UORTP design strategy, time-dependent density functional theory (TD-DFT) calculations were performed to investigate the energy level information and SOC matrix elements (ξ) of the six UORTP luminophores. In Fig. S53 (ESI†), as the number of nitrogen-atom increased from CzPh to CzPM, the energy gaps between S1 and S0 decreased gradually. Three UORTP materials with bromine atoms exhibited the same tendency (Fig. 3A and Fig. S54, ESI†). This is due to the better molecular planarity and conjugation degree resulting from enhanced IHBs and PPEEs. The energy level of the excited state indicated that CzPy possessed more transition pathways from S1 to Tn than CzPh, accounting for its higher ΦP (Fig. S53A and S53B, ESI†). Even so, both the compounds showed negligible ξ(Sm,Tn) between Sm and Tn, demonstrating their poor ISC efficiency. Surprisingly, CzPM with higher ΦP exhibited fewer transition pathways compared to CzPy. In order to find out the reason, the ξ(Sm,Tn) of CzPM was analysed (Fig. S53C, ESI†). The results displayed that its ξ(S3,T7) can be up to 1.576 cm−1, and ΔES3T7 is only 0.09 eV. Therefore, HISC may exist in CzPM due to the perturbation of the charge transfer state and the small ΔES3T7, leading to its higher ΦP. To verify the occurrence of HISC, the energy levels and ξ values of CzPhBr, CzPyBr and CzPMBr were then calculated. The results further confirmed the HISC pathways with larger ξ values (Fig. 3A and Fig. S54, ESI†). For example, ξ(S3,T7) and ξ(S3,T3) of CzPMBr are as high as 39.95 cm−1 and 6.737 cm−1, respectively. Thus, the dual influences of the heavy atom effect and PPEE on the orbital transition configuration and the charge transfer strength resulted in a more efficient HISC. The calculated natural transition orbitals demonstrated that almost all of the electronic configurations of excited states in CzPh and CzPy are dominated by π → π* transition (Fig. S55 and S56, ESI†). Hence, a small ξ was observed because the ISC from Sm (π → π*) to Tn (π → π*) is spin-forbidden. In contrast, the Sm involved in the HISC of CzPM and CzPMBr possesses an n → π* configuration due to the presence of a heteroatom and heavy atom, while Tn still exhibits a predominant π → π* configuration (Fig. S57–S60, ESI†). Thus, efficient SOC occurs and the HISC process opens up for the spin-allowed transition from n → π* to π → π*. In addition, Tn (π → π*) also guarantees the generation of RTP with long lifetimes. Together, with the aid of IHBs and PPEEs, the efficient HISC breaks through the limitations of the highly efficient RTP caused by the spin-forbidden ISC process.
|
| Fig. 3 (A) Schematic diagrams of the TD-DFT calculated energy levels, possible HISC channels and spin–orbit coupling matrix elements of CzPMBr. (B) Proposed mechanism of UORTP produced by the high-lying intersystem crossing between Sm (m > 1) and Tn (n > 1). (S0 = ground state, S1 and Sm = excited singlet state, T1 and Tn = excited triplet state, Abs. = Absorption, Fluo. = Fluorescence, Phos. = Phosphorescence, ISC = intersystem crossing, IC = internal conversion, HISC = the intersystem crossing between high-lying Sm (m > 1) and Tn (n > 1), IHB = intramolecular hydrogen bonding, PPEE = push–pull electron effect) | |
Anti-counterfeiting
Given the superior ultralong RTP properties of CzPMBr, its potential application as a security ink for anti-counterfeiting in calligraphy and painting was investigated. As shown in Fig. 4, a seven-character quatrain and a painting containing fluorescence area and phosphorescence area were made. The quatrain is an acrostic poem that contained four sentences, and the first word of each sentence is composed of the Chinese words “”, namely, “room temperature phosphorescence”. The painting was entitled “Cat and Mouse”. The fluorescence areas were written by an aggregation-induced emission luminogen TTAPE-Me dissolved in aqueous solution. In contrast, the phosphorescence areas were drawn by using the THF solution of TPE with 5% of CzPMBr (Fig. S61, ESI†). When exposed to 365 nm UV light, the whole poem was seen with bright blue emission. When turning off UV excitation, however, only yellow-emissive Chinese words “” were observed, and it lasted for several seconds benefiting from the ultralong RTP lifetime of CzPMBr. Similarly, a blue-emissive cat emerged in the painting under UV irradiation. Upon switching off the light source, a mouse giving yellow emission appeared instead. These results demonstrated that the UORTP properties of CzPMBr made it a promising candidate for a security ink material for anti-counterfeiting.
|
| Fig. 4 Photographs of calligraphy and painting under 365 nm irradiation (left) and after removing the excitation light (right). | |
Conclusions
In summary, we proposed a facile design strategy based on the structural control of IHBs and PPEEs to construct highly efficient UORTP materials. Accordingly, two series of carbazole derivatives with a D–A structure were designed and synthesized. When the acceptor changed from phenyl, pyridinyl to pyrimidinyl, their molecular conformations became planar with strengthened IHB interactions and PPEEs. This further led to the changes in intermolecular interactions from C–H···π to π–π interactions. The strong π–π interactions combined with intermolecular D–A interactions are in favour of the formation of J-aggregates and intermolecular electron coupling, promoting the ISC rate. Consequently, CzPM and CzPMBr with dual IHBs and the strongest PPEEs exhibited τP of 1.31 s and 233 ms and highest ΦP of 1.7% and 48.6%. Theoretical investigations revealed that the heavy atom effect and PPEE strengthened the intramolecular charge transfer states to change the orbital transition mode of Sm. This makes HISC possible, which plays a crucial role in preparing UORTP materials. Specifically, ξ(S3,T7) of CzPMBr reached up to 39.95 cm−1, and thus CzPMBr exhibited the highest ΦP. Finally, CzPMBr has been successfully used as a multifunctional ink for anti-counterfeiting in calligraphy and painting due to its excellent RTP properties. Collectively, the design strategy based on the structural control of IHBs and PPEEs will greatly widen the design platform of UORTP materials. Meanwhile, the discovery of the HISC process will also provide a new idea for the design of UORTP materials.
Author contributions
Guoyu Jiang: conceptualization, validation, formal analysis, investigation, data curation, methodology, funding acquisition, and writing – original draft, review and editing. Qiyao Li: visualization, formal analysis, and writing – review and editing. Anqi Lv: visualization, investigation, and data curation. Lingxiu Liu: investigation. Jianye Gong: investigation. Huili Ma: investigation, methodology, conceptualization, and writing – review and editing. Jianguo Wang: conceptualization, validation, formal analysis, methodology, funding acquisition, writing – review and editing, and supervision. Ben Zhong Tang: writing – review and editing, and supervision.
Conflicts of interest
There are no conflicts to declare.
Acknowledgements
This work was supported by the National Natural Science Foundation of China (22165020, 22161034, 21871060, and 21973043), the Grassland Talent Program of Inner Mongolia Autonomous Region of China, the Science and Technology Program of Inner Mongolia (2021GG0154), the Natural Science Foundation of Inner Mongolia Autonomous Region of China (2020JQ02 and 2020MS02004), the Natural Science Foundation of Jiangxi Province (20192BCBL23013) and the Young Science and Technology Talents Cultivation Project of Inner Mongolia University (21221505). We also thank Mr Zhenghe Zhai at ORDOS No. 1 High School for the poetry creation, and Mr Meijia Chen and Ms Qingqing Chen at Gannan Normal University for calligraphy and painting. We are grateful to the High Performance Computing Center at Nanjing Tech University for supporting the computational resources.
Notes and references
- N. A. Kukhta and M. R. Bryce, Mater. Horiz., 2021, 8, 33–55 RSC .
- Q. Li and Z. Li, Acc. Chem. Res., 2020, 53, 962–973 CrossRef CAS PubMed .
- B. Zhou, G. Xiao and D. Yan, Adv. Mater., 2021, 33, e2007571 CrossRef PubMed .
- H. Gao and X. Ma, Aggregate, 2021, 2, e38 Search PubMed .
- K. Liu, K. Huang, A. Lv, W. Ye, Y. Yang, K. Shen, J. Zhi, H. Wang, R. Zhang, J. Wang, H. Ma, H. Shi, W. Yao, Z. An and W. Huang, Chem. Commun., 2021, 57, 7276–7279 RSC .
- W. Dai, X. Niu, X. Wu, Y. Ren, Y. Zhang, G. Li, H. Su, Y. Lei, J. Xiao, J. Shi, B. Tong, Z. Cai and Y. Dong, Angew. Chem., Int. Ed., 2022, 61, e202200236 CAS .
- K. Jiang, L. Zhang, J. Lu, C. Xu, C. Cai and H. Lin, Angew. Chem., Int. Ed., 2016, 55, 7231–7235 CrossRef CAS PubMed .
- X. Yu, H. Zhang and J. Yu, Aggregate, 2021, 2, 20–34 CrossRef .
- K. Jiang, X. Gao, X. Feng, Y. Wang, Z. Li and H. Lin, Angew. Chem., Int. Ed., 2020, 59, 1263–1269 CrossRef CAS PubMed .
- Y. Lei, W. Dai, J. Guan, S. Guo, F. Ren, Y. Zhou, J. Shi, B. Tong, Z. Cai, J. Zheng and Y. Dong, Angew. Chem., Int. Ed., 2020, 59, 16054–16060 CrossRef CAS PubMed .
- M. Jian, Z. Song, X. Chen, J. Zhao, B. Xu and Z. Chi, Chem. Eng. J., 2022, 429, 132346 CrossRef CAS .
- Y. Yang, Y. Liang, Y. Zheng, J.-A. Li, S. Wu, H. Zhang, T. Huang, S. Luo, C. Liu, G. Shi, F. Sun, Z. Chi and B. Xu, Angew. Chem., Int. Ed., 2022 DOI:10.1002/anie.202201820 .
- Y. Ren, W. Dai, S. Guo, L. Dong, S. Huang, J. Shi, B. Tong, N. Hao, L. Li, Z. Cai and Y. Dong, J. Am. Chem. Soc., 2022, 144, 1361–1369 CrossRef CAS PubMed .
- L. Ma, S. Sun, B. Ding, X. Ma and H. Tian, Adv. Funct. Mater., 2021, 31, 2010659 CrossRef CAS .
- X. Yu, K. Liu, H. Zhang, B. Wang, G. Yang, J. Li and J. Yu, CCS Chem., 2021, 3, 252–264 CrossRef CAS .
- Y.-J. Ma, X. Fang, G. Xiao, B. Lu and D. Yan, Chem. Commun., 2021, 57, 6684–6687 RSC .
- D. Wang, Y. Xie, X. Wu, Y. Lei, Y. Zhou, Z. Cai, M. Liu, H. Wu, X. Huang and Y. Dong, J. Phys. Chem. Lett., 2021, 12, 1814–1821 CrossRef CAS PubMed .
- H. Wang, Q. Li, J. Zhang, H. Zhang, Y. Shu, Z. Zhao, W. Jiang, L. Du, D. L. Phillips, J. W. Y. Lam, H. H. Y. Sung, I. D. Williams, R. Lu and B. Z. Tang, J. Am. Chem. Soc., 2021, 143, 9468–9477 CrossRef CAS PubMed .
- R. Gui, H. Jin, Z. Wang, F. Zhang, J. Xia, M. Yang, S. Bi and Y. Xia, Nanoscale, 2015, 7, 8289–8293 RSC .
- X. Zhen, R. Qu, W. Chen, W. Wu and X. Jiang, Biomater. Sci., 2021, 9, 285–300 RSC .
- W. Wu, C. Zhang, T. W. Rees, X. Liao, X. Yan, Y. Chen, L. Ji and H. Chao, Anal. Chem., 2020, 92, 6003–6009 CrossRef CAS PubMed .
- Y. Hou, G. Jiang, J. Gong, R. Sha and J. Wang, Chem. Res. Chin. Univ., 2021, 37, 73–82 CrossRef CAS .
- Z. He, H. Gao, S. Zhang, S. Zheng, Y. Wang, Z. Zhao, D. Ding, B. Yang, Y. Zhang and W. Z. Yuan, Adv. Mater., 2019, 31, 1807222 CrossRef PubMed .
- H.-B. Cheng, Y. Li, B. Z. Tang and J. Yoon, Chem. Soc. Rev., 2020, 49, 21–31 RSC .
- Y. Wang, H. Gao, J. Yang, M. Fang, D. Ding, B. Z. Tang and Z. Li, Adv. Mater., 2021, 33, 2007811 CrossRef CAS PubMed .
- J. Qi, H. Ou, Q. Liu and D. Ding, Aggregate, 2021, 2, 95–113 CrossRef .
- H.-J. Yu, Q. Zhou, X. Dai, F.-F. Shen, Y.-M. Zhang, X. Xu and Y. Liu, J. Am. Chem. Soc., 2021, 143, 13887–13894 CrossRef CAS PubMed .
- F. Lin, H. Wang, Y. Cao, R. Yu, G. Liang, H. Huang, Y. Mu, Z. Yang and Z. Chi, Adv. Mater., 2022, 34(15), 2108333 CrossRef CAS PubMed .
- W. Zhao, Z. Z. THe, W. Y. L. Jacky, Q. Peng, H. Ma, Z. Shuai, G. Bai, J. Hao and Z. T. Ben, Chem, 2016, 1, 592–602 CAS .
- L. Gu, X. Wang, M. Singh, H. Shi, H. Ma, Z. An and W. Huang, J. Phys. Chem. Lett., 2020, 11, 6191–6200 CrossRef CAS PubMed .
- L. Gu, H. Wu, H. Ma, W. Ye, W. Jia, H. Wang, H. Chen, N. Zhang, D. Wang, C. Qian, Z. An, W. Huang and Y. Zhao, Nat. Commun., 2020, 11, 944 CrossRef CAS PubMed .
- Q. Huang, Z. Lin and D. Yan, Small Struct., 2021, 2, 2100044 CrossRef CAS .
- X. Cai, X. Li, G. Xie, Z. He, K. Gao, K. Liu, D. Chen, Y. Cao and S.-J. Su, Chem. Sci., 2016, 7, 4264–4275 RSC .
- H. Ma, A. Lv, L. Fu, S. Wang, Z. An, H. Shi and W. Huang, Ann. Phys., 2019, 531, 1800482 CrossRef .
- L. Feng, C. Li, L. Liu, Z. Wang, Z. Chen, J. Yu, W. Ji, G. Jiang, P. Zhang, J. Wang and B. Z. Tang, ACS Nano, 2022, 16, 4162–4174 CrossRef CAS PubMed .
- Z. Chen, F. Ni, Z. Wu, Y. Hou, C. Zhong, M. Huang, G. Xie, D. Ma and C. Yang, J. Phys. Chem. Lett., 2019, 10, 2669–2675 CrossRef CAS PubMed .
- H. Gao, B. Ding, C. Wang and X. Ma, J. Mater. Chem. C, 2021, 9, 16581–16586 RSC .
- H. Li, H. Li, J. Gu, F. He, H. Peng, Y. Tao, D. Tian, Q. Yang, P. Li, C. Zheng, W. Huang and R. Chen, Chem. Sci., 2021, 12, 3580–3586 RSC .
- J. Ren, Y. Wang, Y. Tian, Z. Liu, X. Xiao, J. Yang, M. Fang and Z. Li, Angew. Chem., Int. Ed., 2021, 60, 12335–12340 CrossRef CAS PubMed .
- L. Yang, X. Wang, G. Zhang, X. Chen, G. Zhang and J. Jiang, Nanoscale, 2016, 8, 17422–17426 RSC .
- J. Wang, X. Gu, H. Ma, Q. Peng, X. Huang, X. Zheng, S. H. P. Sung, G. Shan, J. W. Y. Lam, Z. Shuai and B. Z. Tang, Nat. Commun., 2018, 9, 2963 CrossRef PubMed .
- X. Sun, B. Zhang, X. Li, C. O. Trindle and G. Zhang, J. Phys. Chem. A, 2016, 120, 5791–5797 CrossRef CAS PubMed .
- Z. Yang, Z. Mao, X. Zhang, D. Ou, Y. Mu, Y. Zhang, C. Zhao, S. Liu, Z. Chi, J. Xu, Y.-C. Wu, P.-Y. Lu, A. Lien and M. R. Bryce, Angew. Chem., Int. Ed., 2016, 55, 2181–2185 CrossRef CAS PubMed .
- O. Bolton, K. Lee, H.-J. Kim, K. Y. Lin and J. Kim, Nat. Chem., 2011, 3, 205–210 CrossRef CAS PubMed .
- Y. Xiong, Z. Zhao, W. Zhao, H. Ma, Q. Peng, Z. He, X. Zhang, Y. Chen, X. He, J. W. Y. Lam and B. Z. Tang, Angew. Chem., Int. Ed., 2018, 57, 7997–8001 CrossRef CAS PubMed .
- X. Sun, X. Wang, X. Li, J. Ge, Q. Zhang, J. Jiang and G. Zhang, Macromol. Rapid Commun., 2015, 36, 298–303 CrossRef CAS PubMed .
- J. Yang, M. Fang and Z. Li, Aggregate, 2020, 1, 6–18 CrossRef .
- H. Wu, C. Hang, X. Li, L. Yin, M. Zhu, J. Zhang, Y. Zhou, H. Ågren, Q. Zhang and L. Zhu, Chem. Commun., 2017, 53, 2661–2664 RSC .
- Z.-A. Yan, X. Lin, S. Sun, X. Ma and H. Tian, Angew. Chem., Int. Ed., 2021, 60, 19735–19739 CrossRef CAS PubMed .
- B. Wu, N. Guo, X. Xu, Y. Xing, K. Shi, W. Fang and G. Wang, Adv. Opt. Mater., 2020, 8, 2001192 CrossRef CAS .
- D. Li, J. Yang, M. Fang, B. Z. Tang and Z. Li, Sci. Adv., 2022, 8, eabl8392 CrossRef CAS PubMed .
- B. Ding, H. Gao, C. Wang and X. Ma, Chem. Commun., 2021, 57, 3154–3157 RSC .
- B. Chen, W. Huang, X. Nie, F. Liao, H. Miao, X. Zhang and G. Zhang, Angew. Chem., Int. Ed., 2021, 60, 16970–16973 CrossRef CAS PubMed .
- J. Zhang, S. Xu, Z. Wang, P. Xue, W. Wang, L. Zhang, Y. Shi, W. Huang and R. Chen, Angew. Chem., Int. Ed., 2021, 60, 17094–17101 CrossRef CAS PubMed .
- X. Liu, W. Dai, J. Qian, Y. Lei, M. Liu, Z. Cai, X. Huang, H. Wu and Y. Dong, J. Mater. Chem. C, 2021, 9, 3391–3395 RSC .
- Y. Lei, J. Yang, W. Dai, Y. Lan, J. Yang, X. Zheng, J. Shi, B. Tong, Z. Cai and Y. Dong, Chem. Sci., 2021, 12, 6518–6525 RSC .
- X. Zhang, L. Du, W. Zhao, Z. Zhao, Y. Xiong, X. He, P. F. Gao, P. Alam, C. Wang, Z. Li, J. Leng, J. Liu, C. Zhou, J. W. Y. Lam, D. L. Phillips, G. Zhang and B. Z. Tang, Nat. Commun., 2019, 10, 5161 CrossRef PubMed .
- S. Hirata, K. Totani, J. Zhang, T. Yamashita, H. Kaji, S. R. Marder, T. Watanabe and C. Adachi, Adv. Funct. Mater., 2013, 23, 3386–3397 CrossRef CAS .
- Z. An, C. Zheng, Y. Tao, R. Chen, H. Shi, T. Chen, Z. Wang, H. Li, R. Deng, X. Liu and W. Huang, Nat. Mater., 2015, 14, 685–690 CrossRef CAS PubMed .
- Z. Yin, M. Gu, H. Ma, X. Jiang, J. Zhi, Y. Wang, H. Yang, W. Zhu and Z. An, Angew. Chem., Int. Ed., 2021, 60, 2058–2063 CrossRef CAS PubMed .
- W. Ye, H. Ma, H. Shi, H. Wang, A. Lv, L. Bian, M. Zhang, C. Ma, K. Ling, M. Gu, Y. Mao, X. Yao, C. Gao, K. Shen, W. Jia, J. Zhi, S. Cai, Z. Song, J. Li, Y. Zhang, S. Lu, K. Liu, C. Dong, Q. Wang, Y. Zhou, W. Yao, Y. Zhang, H. Zhang, Z. Zhang, X. Hang, Z. An, X. Liu and W. Huang, Nat. Mater., 2021, 20, 1539–1544 CrossRef CAS PubMed .
- M. Huo, X.-Y. Dai and Y. Liu, Angew. Chem., Int. Ed., 2021, 60, 27171–27177 CrossRef CAS PubMed .
- X.-K. Ma, W. Zhang, Z. Liu, H. Zhang, B. Zhang and Y. Liu, Adv. Mater., 2021, 33, 2007476 CrossRef CAS PubMed .
Footnotes |
† Electronic supplementary information (ESI) available. CCDC 2085870–2085875. For ESI and crystallographic data in CIF or other electronic format see DOI: https://doi.org/10.1039/d2tc01093c |
‡ These authors contributed equally to this work. |
|
This journal is © The Royal Society of Chemistry 2022 |
Click here to see how this site uses Cookies. View our privacy policy here.