Yujie
Wu‡
abc,
Jiasen
Zhang‡
ab,
Deli
Li‡
d,
Songyu
Du
ab,
Xilin
Mu
ab,
Chunyu
Liu
ab,
Kaibo
Fang
abc,
Tingting
Feng
ab,
Tao
Wang
c,
Wei
Li
*ab and
Ziyi
Ge
*ab
aZhejiang Provincial Engineering Research Center of Energy Optoelectronic Materials and Devices, Ningbo Institute of Materials Technology and Engineering, Chinese Academy of Sciences, Ningbo, 315201, P. R. China. E-mail: liwei1987@nimte.ac.cn; geziyi@nimte.ac.cn
bCenter of Materials Science and Optoelectronics Engineering, University of Chinese Academy of Sciences, P. R. China
cSchool of Materials Science and Engineering Zhejiang Sci-Tech University, Hangzhou 310018, P. R. China
dInstitute for Smart Materials & Engineering, University of Jinan, No. 336 Nanxin Zhuang West Road, Jinan 250022, P. R. China
First published on 2nd June 2024
To effectively compete with the quenching process in long-wavelength regions like deep red (DR) and near-infrared (NIR), rapid radiative decay is urgently needed to address the challenges posed by the “energy gap law”. Herein, we confirmed that it is crucial for hot exciton emitters to attain a narrow energy gap (ΔES1–T2) between the lowest singlet excited (S1) state and second triplet excited (T2) state, while ensuring that T2 slightly exceeds S1 in the energy level. Two proofs-of-concept of hot exciton DR emitters, namely αT-IPD and βT-IPD, were successfully designed and synthesized by coupling electron-acceptors N,N-diphenylnaphthalen-2-amine (αTPA) and N,N-diphenylnaphthalen-1-amine (βTPA) with an electron-withdrawing unit 5-(4-(tert-butyl) phenyl)-5H-pyrazino[2,3-b]indole-2,3-dicarbonitrile (IPD). Both emitters exhibited a narrow ΔES1–T2, with T2 being slightly higher than S1. Additionally, both emitters showed significantly large ΔET2–T1. Moreover, due to their aggregation-induced emission characteristics, J-aggregated packing modes, moderate strength intermolecular CN⋯H–C and C–H⋯π interactions, and unique, comparatively large center-to-center distances among trimers in the crystalline state, both αT-IPD and βT-IPD emitters exhibited remarkable photoluminescence quantum yields of 68.5% and 73.5%, respectively, in non-doped films. Remarkably, the corresponding non-doped DR-OLED based on βT-IPD achieved a maximum external quantum efficiency of 15.5% at an emission peak wavelength of 667 nm, representing the highest reported value for hot exciton DR-OLEDs.
New conceptsThe efficient development of deep-red (DR) and near-infrared (NIR) emitters encounters considerable obstacles due to their emission efficiency being relatively lower compared to those of visible light emitters, despite their immense potential for various applications. One major quenching mechanism is known as the “energy gap law”, and this nonradiative process experiences significant enhancement in the DR/NIR emitters since they possess smaller emission gaps compared to visible emitters. Fortunately, the “hot exciton” process provides a promising solution to address the challenges. Herein, we confirmed that it is crucial for hot exciton emitters to attain a narrow energy gap (ΔES1–T2) between the lowest singlet excited (S1) state and second triplet excited (T2) state, while ensuring that T2 slightly exceeds S1 in the energy level. Two proofs-of-concept of hot exciton DR emitters exhibited a narrow ΔES1–T2, with T2 being slightly higher than S1. Additionally, both emitters showed significantly large ΔET2–T1. Moreover, due to the aggregation-induced emission characteristics, J-aggregated packing modes, moderate strength intermolecular CN⋯H–C and C–H⋯π interactions, and unique comparatively large center-to-center distances among trimers in the crystalline state, both target emitters exhibited remarkable photoluminescence quantum yields in non-doped films. Remarkably, the corresponding non-doped DR-OLED achieved a maximum external quantum efficiency of 15.5% at an emission peak wavelength of 667 nm, representing the highest reported value for hot exciton DR-OLEDs. |
Two feasible approaches for suppressing the quenching process and increasing the efficiency of DR/NIR emitters can be formed and described as follows: one approach is to minimize vibrational overlap as much as possible.9 To achieve this, deuterated or fluorinated methods are used to reduce high-frequency vibrations from C–H, O–H, and N–H stretching. Nevertheless, despite these techniques preserving a multitude of additional modes of vibration and their combination, the resulting improvements are only partial or even insignificant. The second approach involves the creation of a shallow or repulsive potential energy surface (PES) in the ground (S0) state, which significantly reduces quenching caused by high-frequency vibrations.10 This type of PES can be formed in excimers/excited oligomers, where interactions between mono-molecules are minimal or absent in the S0 state, and excimers/excited oligomers can form in excited states. Due to the repulsive-like or shallow nature of the PES in the S0 state, the emission of excimers is less affected by vibrational quenching. However, such excimers have only been reported and utilized in Pt-containing complexes with square-planar structures and are challenging to create in typical luminous materials.6–8 Therefore, effectively harnessing triplet excitons in pure DR/NIR emitters while reducing nonradiative decay remains a formidable challenge that requires further investigation.
Fortunately, the “hot exciton” process provides a promising solution by enhancing the rate of radiative decay, effectively competing with the quenching process. Previous studies have demonstrated the presence of high-energy reverse intersystem crossing (hRISC) processes in commonly utilized fluorophores, including isoquinoline, quinoline, naphthalene, anthracene, and their derivatives, as well as tetraphenyl-porphyrin.11–13 In 2012, Ma et al. ingeniously employed this photophysical phenomenon to design organic light-emitting materials and subsequently synthesized a series of novel organic electroluminescent (EL) materials with various colors.14–16 they named this innovative luminescent mechanism the “hot exciton” mechanism. Novel emitters based on this principle are known as hot exciton materials. By implementing efficient hRISC mechanisms, OLEDs based on hot exciton materials achieved a significant enhancement in the utilization efficiency of excitons (EUE).
Firstly, the breakthrough of hot excitons emitters-based OLEDs in overcoming the spin-statistical limit of fluorescent materials relies on the hRISC from high-lying triplet states (Tn, n ≥ 2) to singlet states (Sm, m ≥ 1). Secondly, to attain a high EUE, it is crucial to ensure that the high-energy hRISC rate (khRISC) from Tn to Sm significantly exceeds the rate of internal conversion (kIC) from Tn to T1. According to Fermi's golden rule,17,18
To address the challenges, we have developed two efficient DR emitters, namely αT-IPD and βT-IPD, based on the hot exciton mechanism. These emitters are synthesized by combining electron-acceptors αTPA and βTPA with an electron-withdrawing unit IPD (Fig. 1A).20 The intelligent molecular structures of these emitters allow for precise modulation of their energy levels in both singlet and triplet excited states. Both emitters exhibit significant energy gaps, with ΔET2–T1 approximately 0.75 eV and ΔES1–T1 around 0.70 eV, effectively reducing the dissipation of triplet excitons via IC mechanism. Furthermore, when compared to DT-IPD, both αT-IPD and βT-IPD possess larger ΔET2–T1 and ΔES1–T1 values. As a result, αT-IPD and βT-IPD demonstrate reduced kIC from the T2 to the T1 state as well as kISC from the S1 to the T1 state. Consequently, αT-IPD and βT-IPD achieve high photoluminescence quantum yields (ΦPLQYs) of 68.5% and 73.5%, respectively. Remarkably, a groundbreaking maximum external quantum efficiency (EQEmax) of 15.5% was achieved for non-doped DR-OLEDs based on βT-IPD, which is the highest value among non-doped DR-OLEDs employing the hot exciton mechanism.
To gain a more comprehensive understanding of the electronic configurations in the excited states, the natural transition orbits (NTOs) for both emitters were implemented. In the S1 state, the dihedral angle between the IPD and αTPA/βTPA in both emitters was relatively small (∼17°), resulting in a significant overlap of holes and particles, as well as large oscillator strength (f) values of 1.291 and 1.252 for αT-IPD and βT-IPD, respectively, suggesting that their LE state character dominate in the S1 state with minimal involvement of the charge-transfer (CT) state. Moreover, such large f values exhibited by both emitters are particularly advantageous for long-wavelength luminescent materials, as they enable intense light emission while significantly bolstering their competitive edge against non-radiative decay processes. In the T1 state, both emitters exhibit an even stronger LE character compared to the S1 state due to a smaller dihedral angle.
To further investigate the luminescence mechanism and exciton dynamics process of αT-IPD and βT-IPD, transient PL decay photoluminescence quantum yields (ΦPLQYs) were evaluated in their neat films (Fig. S12, ESI†). As expected, both emitters exclusively exhibit nanosecond lifetimes (Table S1, ESI†), while no delayed lifetimes in the microsecond range could be detected, ruling out their TADF mechanism. Interestingly, αT-IPD and βT-IPD achieved remarkably high ΦPLQY values of 68.5% and 73.5%, respectively, in non-doped films. Such high ΦPLQY values are exceptionally rare in the field of DR light, indicating the effective suppression of various exciton quenching pathways.
To elucidate the underlying factors contributing to the exceptional ΦPLQYs observed in non-doped states, as well as the dynamics of energy transfer for both αT-IPD and βT-IPD emitters, the singlet/triplet energy levels were evaluated using TD-DFT calculations (Fig. 1C). It is worth noting that a remarkable ΔET2–T1 of up to 0.75 eV was achieved for both emitters, leading to a highly effective suppression of the IC process from the T2 to the T1 state. Additionally, both emitters feature a significant ΔES1–T1 value of nearly 0.70 eV, which serves to weaken the rate of ISC (kISC). Furthermore, all the energy levels of the higher-lying Tn states (n ≥ 2) were found to be elevated compared to that of the S1 state, ensuring rapid hRISC processes from Tn to S1. Given the small energy gap between Tn (n = 2, 3, 4) and S1 ΔES1–Tn, multi-channel hRISC is anticipated, facilitating effective utilization of excitons (Fig. 2A). In comparison with DT-IPD, reported by our group the considerably smaller ΔET2–T1 and ΔES1–T1 values of DT-IPD pose a heightened vulnerability of undergoing IC from the T2 to the T1 state, as well as ISC from the S1 to the T1 state. This configuration is unfavorable for the efficient utilization of excitons (Fig. 2B). Ma and coworkers also reported intriguing findings regarding certain blue emitters characterized by the hot exciton mechanism (Fig. 2C).13,21–25 They emphasize that maintaining an n value lower than 4 is crucial at high-lying triplet energy levels to prevent rapid intersystem crossing between triplet states, which can weaken the efficiency of the Tn–S1 conversion process.23 However, according to our current research, in an emitter predominantly governed by the hot exciton mechanism, it is preferable for a minimal energy gap to exist between the high-lying triplet state and S1 state (ΔETn–S1, n ≥ 2) to occur, while ensuring that the energy level of the T2 state slightly surpasses that of the S1 state. This configuration enables the efficient transfer of triplet excitons to the S1 state even during the IC process between high energy states (Tn-T2, n > 2). Therefore, αT-IPD and βT-IPD exhibit a more favorable energy level arrangement for achieving efficient exciton utilization and contributing to exceptional EL characteristics.
Luminophores exhibiting aggregation-induced emission (AIE) have attracted considerable attention as promising candidates for non-doped OLED construction due to their exceptional ability to emit bright light and significantly enhance the PLQYs in the aggregate state.26,27 Hence, to delve deeper into the intricate mechanisms governing the ΦPLQY, a comprehensive investigation was conducted on the AIE properties in a mixture of tetrahydrofuran (THF) and water (Fig. 3A–D). Remarkably, both αT-IPD and βT-IPD exhibit minimal emission when the fraction of water (fW) is below 50%. However, the photoluminescence intensities experienced a rapid increase as the fW reached 60%, indicating a pronounced AIE characteristic in the aggregate state.
The investigation of single crystals plays a pivotal role in acquiring profound insights into the chemical characteristics of materials, as well as understanding the intricate relationship between structure and properties. Therefore, both αT-IPD and βT-IPD crystals were successfully cultivated (Fig. 3E, F, and Table S2, ESI†). Single-crystal analysis revealed that the interlayer slip angles of the two emitter is smaller than 54.7° (Fig. S13, ESI†), thereby adopting J-aggregate stacking frameworks, which can significantly improve the emissive properties. Notably, although the dimers in both crystal structures exhibit a close intermolecular distance, the trimer composed of three monomers is comparatively further apart (Fig. S14, ESI†). This feature holds crucial importance in mitigating exciton annihilation, as a considerable number of long-lived triplet excitons are generated under electrical excitation, and exciton annihilation is primarily governed by short-range multi-molecular processes facilitated by the Dexter energy transfer (DET) mechanism. Therefore, minimizing the distance between multiple molecules effectively reduces the diffusion length of long-lived triplet excitons, thereby mitigating the annihilation process and significantly improving the EL performance of these molecules. Additionally, it is worth mentioning that the PLQY of αT-IPD is marginally lower compared to that of βT-IPD, and this observation appears to be partly attributed to the arrangement of single crystals. The formation of dimers in αT-IPD crystals induces π–π interactions, leading to an aggregation-caused quenching (ACQ) effect to a certain extent, consequently resulting in a reduction in PLQY for αT-IPD (Fig. S14 and Table S1, ESI†).
The optimization of the horizontal alignment (Θ) of the emissive transition dipole moment (TDM) in OLEDs holds significant potential for enhancing light extraction efficiency (ηout), resulting in a possible 50% improvement compared to random TDM orientation. Therefore, actively promoting a horizontal dipole orientation is crucial for bolstering OLEDs’ efficiency. To determine the Θ of both emitters, we measured the intensity of angle-dependent PL spectra in neat thin films (Fig. 3G and H). Remarkably, both αT-IPD and βT-IPD manifested high Θ of 80% and 82%, respectively. These noteworthy values can be attributed to the presence of rigid polycyclic aromatic hydrocarbon acceptors and a planar molecular framework.
Footnotes |
† Electronic supplementary information (ESI) available. CCDC 2309641 (αT-IPD) and 2309564 (βT-IPD). For ESI and crystallographic data in CIF or other electronic format see DOI: https://doi.org/10.1039/d4mh00441h |
‡ These authors contributed equally to this work. |
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