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Color tuning of multi-resonant thermally activated delayed fluorescence emitters based on fully fused polycyclic amine/carbonyl frameworks

John Marques dos Santos a, Chin-Yiu Chan c, Shi Tang d, David Hall ab, Tomas Matulaitis a, David B. Cordes a, Alexandra M. Z. Slawin a, Youichi Tsuchiya c, Ludvig Edman *d, Chihaya Adachi *c, Yoann Olivier *b and Eli Zysman-Colman *a
aOrganic Semiconductor Centre, EaStCHEM School of Chemistry, University of St Andrews, St Andrews, KY16 9ST, UK. E-mail: eli.zysman-colman@st-andrews.ac.uk
bLaboratory for Computational Modeling of Functional Materials, Namur Institute of Structured Matter, University of Namur, Rue de Bruxelles, 61, 5000 Namur, Belgium. E-mail: yoann.olivier@unamur.be
cCenter for Organic Photonics and Electronics Research (OPERA), Kyushu University, Motooka 744, Nishi-ku, Fukuoka 819-0395, Japan. E-mail: adachi@cstf.kyushu-u.ac.jp
dThe Organic Photonics and Electronics Group, Department of Physics, Umea University, SE-90187 Umea, Sweden. E-mail: ludvig.edman@umu.se

Received 20th February 2023 , Accepted 1st May 2023

First published on 2nd May 2023


Abstract

Two novel π-extended amine/carbonyl-based multi-resonance thermally activated delayed fluorescence (MR-TADF) emitters have been designed and synthesized. The two emitters are isomeric, composed of nine fused rings and show green-yellow emission. Sym-DiDiKTa and Asym-DiDiKTa possess tert-butyl groups distributed in a symmetrical and asymmetrical fashion, respectively, which significantly impact the single-crystal packing structure. The two compounds possess similar singlet–triplet energy gaps, ΔEST, of around 0.23 eV, narrowband emission characterized by a full-width at half-maximum, FWHM, of 29 nm and a photoluminescence quantum yield, ΦPL, of 70% and 53% for the symmetric and asymmetric counterparts, respectively, in toluene. Investigation in OLEDs demonstrated that the devices with Sym-DiDiKTa and Asym-DiDiKTa displayed electroluminescence maxima of 543 and 544 nm, and maximum external quantum efficiencies (EQEmax) of 9.8% and 10.5%, respectively. The maximum EQE was further improved to 19.9% by employing a hyperfluorescence strategy. We further present the first example of a neutral MR-TADF emitter incorporated in a LEC device where Sym-DiDiKTa acts as the emitter. The LEC shows a λEL at 551 nm and FWHM of 60 nm with luminance of 300 cd m−2 and a fast turn-on time of less than 2 s to 100 cd m−2.



10th Anniversay statement

The journal of Materials Chemistry C has been one of our favourite journals for electroluminescent materials and device research. The quality and breadth of the science covered in the journal particularly in the area of emitter development for electroluminescent devices has been excellent. It is always a pleasure to peruse each week's table of contents and to then read exciting and new science in optoelectronic materials. We look forward to the next 10 years and beyond and will continue to support JMCC.

Introduction

Organic light-emitting diodes (OLEDs) have now matured as a technology and are now integrated in efficient, flexible and ultra-high contrast next-generation displays.1,2 Organic thermally activated delayed fluorescence (TADF) materials are increasingly viewed as an attractive alternative emitter class to phosphorescent complexes that contain noble metals as they do not contain scarce elements yet can likewise harvest both singlet and triplet excitons in the device to generate light at comparable efficiencies.3–7 Unlike phosphorescent OLEDs that funnel the emitting excitons via the lowest-lying triplet excited state, TADF compounds convert triplet excitons into singlets via reverse intersystem crossing (RISC),8,9 which is possible at ambient temperatures due to the small S1T1 energy gap, ΔEST.10 Compounds that possess a small ΔEST show a small overlap of the electron density between the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO). To adhere to this requirement, the great majority of organic TADF emitters are based on a highly twisted donor-acceptor architecture and emit from a long-range charge transfer (LRCT) state.7 This strategy, however, leads to molecules for which the conformational space is large in the excited state11,12 that manifests in broadband emission with full width half maximum (FWHM) values of around 70–100 nm.13 This is unattractive to the display industry as the color purity of these devices is poor and color filters must therefore be used to meet the industry standards for red, green and blue pixels. Hence, significant effort has been devoted in recent years to suppress vibrational and conformational relaxation within the emitter through the development of narrowband emitters.14–20

An exciting molecular design strategy to achieve these requirements was introduced by Hatakeyama and co-workers and relies typically on p- and n-doped nanographenes.21,22 Termed multiple resonance (or multiresonant) TADF (MR-TADF) emitters, these compounds possess small-to-moderate ΔEST values, narrowband emission (with FWHM typically < 30 nm) and limited positive solvatochromism due to the short-range charge transfer (SRCT) nature of the emissive S1.22 Maximum external quantum efficiencies (EQEmax) as high as 34% for deep blue,22 40% for sky-blue,23 35%24 for green and 36% for red25 have been achieved for OLEDs containing MR-TADF emitters comprised of boron–nitrogen (B/N) doped polycyclic aromatic frameworks. Recently, the library of MR-TADF emitters has been expanded to contain boron–oxygen (B/O)-based emitters26 and carbonyl–nitrogen (C[double bond, length as m-dash]O/N)-based emitters14–19 as well as C[double bond, length as m-dash]O/N/O-,17,27,28 C[double bond, length as m-dash]O/N/S-17, 29 and C[double bond, length as m-dash]O/N/SO2-based29 emitters.

While the recent conceptual progress in MR-TADF emitter design has delivered a burgeoning number of efficient B/N-doped compounds that emit across the entirety of the visible spectrum,30,31 few tactics have been advanced to exploit the promising class of C[double bond, length as m-dash]O/N-based MR-TADF emitters, which are represented by the emitter DiKTa (Fig. 1).14–19,32,33 Recently, Yasuda et al. reported a linearly extended C[double bond, length as m-dash]O/N-based emitter, QA-2 (Fig. 1) displaying TADF in 3 wt% PPCz doped film, with a ΔEST of 0.19 eV.27 Similar to the design strategy used for v-DABNA, where the central ring is functionalized with meta-disposed B–π–B and N–π–N groups, QA-2 also contains meta-disposed C[double bond, length as m-dash]O–π–C[double bond, length as m-dash]O and N–π–N, which leads to an improvement of the TADF properties over the parent compound DiKTa, with a faster delayed lifetime (48 μs in 3 wt% PPCz and 93.3 μs in 5 wt% mCP, respectively). Despite the apparent increased conjugation length, a slightly blue-shifted λPL of 465 nm in toluene was observed for QA-2, compared to that of DiKTaEST of 0.15 eV and λPL of 473 nm in toluene).15 The OLED with QA-2 showed an EQEmax of 19.0%. Our group has recently reported a helically chiral isomer of QA-2 that contains meta-disposed C[double bond, length as m-dash]O–π–C[double bond, length as m-dash]O and N–π–N skeleton. Enantiomers of Hel-DiDiKTa (Fig. 1)34 display circularly polarized luminescence (CPL), with a |gPL| of 4 × 10−4, but likewise, its λPL (473 nm) is similar to that of DiKTa.


image file: d3tc00641g-f1.tif
Fig. 1 Schematical representation of the molecular design discussed in this work.15,27,31,34,36,37,42

The exploitation of para-disposed functional groups to generate π-extended skeletons is a powerful strategy to tune the photophysical properties of MR-TADF emitters to the red.25,35 Yasuda and co-workers have adopted this strategy where both the B–π–B and N–π–N-based groups are para-linked to construct red MR-TADF emitters such as BBCz-R (Fig. 1) that exhibits a λPL of 615 nm and a narrow FWHM of 21 nm (0.07 eV) in dilute toluene solution.31 This strategy has also been used to generate B/O and B/S derivatives as shown in Fig. 1.36,37 Remarkably, among the many MR-TADF emitters reported, comprehensive studies on compounds containing para-C[double bond, length as m-dash]O–π–C[double bond, length as m-dash]O and N–π–N frameworks have not as of yet been presented. In this context, expanding the chemical space explored in ketone-based MR-TADF emitters is desired.

Herein, we present two new isomeric π-extended C[double bond, length as m-dash]O/N-based polycyclic aromatic compounds based on the annellation of two triangulene DiKTa units to form tetraketone structures. Differently from QA-2 and Hel-DiDiKTa, the central ring in each of Sym-DiDiKTa and Asym-DiDiKTa is functionalized with para-C[double bond, length as m-dash]O–π–C[double bond, length as m-dash]O and N–π–N groups, these molecules represent the first ketone-based MR-TADF examples of their kind (Fig. 1).17–19,33Sym-DiDiKTa is composed of nine fully fused rings with symmetrically arranged tert-butyl substituents while the tert-butyl groups are disposed asymmetrically in Asym-DiDiKTa. Both emitters show moderate ΔEST of around 0.23 eV, red-shifted emission at ∼540 nm compared to DiKTa, a small FWHM of 29 nm and delayed lifetime, τd, of 4.6 ms and 3.0 ms for Sym-DiDiKTa and Asym-DiDiKTa, respectively.

Owing to their exciting properties, these compounds were employed as emitters in OLED devices, and to assess improvements in efficiency roll-off, they were also investigated as terminal emitters in hyperfluorescence (HF) OLEDs, which combine a narrowband emitter as terminal dopant with a co-deposited TADF emitter acting as an assistant dopant in a host matrix. Although MR-TADF OLEDs have achieved extremely high EQEmax, an issue generally encountered is the severe efficiency roll-off that is mainly caused by quenching mechanisms such as singlet–triplet annihilation (STA) and triplet–triplet annihilation (TTA) due to the accumulation of triplet excitons as a result of their typically slow reverse intersystem-crossing rate (kRISC).17,38 Therefore, a potential solution to circumvent this issue is to use MR-TADF compounds in combination with an efficient exciton harvesting assistant dopant in a HF device.39–41 In these devices, exciton harvesting is managed by the donor–acceptor TADF assistant dopant and these excitons are transferred to the terminal MR-TADF emitter via a Förster resonant energy transfer (FRET) mechanism. Emission from the terminal emitter then occurs, benefiting from the typically fast radiative decay and narrowband emission of the MR-TADF compound.39 To ensure efficient FRET, there must be an effective overlap between the emission spectrum of the assistant dopant and the absorption spectrum of the emitter.

Results and discussion

The two emitters were obtained via a four-step linear sequence (Fig. 2a). Compound 1 was obtained in good yield following a copper-catalysed Ullman coupling between the previously reported dimethyl 2,5-bis((4-(tert-butyl)phenyl)amino)terephthalate43 and methyl 2-iodobenzoate. Quantitative saponification yielded the key intermediate 2, which then underwent a four-fold intramolecular Friedel–Crafts acylation of the in situ-prepared acyl chloride derivative in the presence of the Lewis acid AlCl3 to afford a mixture of two isomers, Sym-DiDiKTa and Asym-DiDiKTa, in 36% and 5% yield, respectively, after isolation by column chromatography. The compounds were further purified by gradient-temperature vacuum sublimation and their structure and purity were confirmed by a combination of NMR spectroscopy, high-resolution mass spectrometry, melting point determination and HPLC and elemental analysis.

Single crystals were isolated following the gradient-temperature vacuum sublimation. Crystallographic data of Sym-DiDiKTa and Asym-DiDiKTa revealed that both molecules display very similar structures with each DiKTa unit showing a helical-like structure. The torsion angles generated by this helical section are similar (torsion angles C3–C2–N1–C23): 29.6(5)° for Sym-DiDiKTa and 27.9(3) and 28.1(3)° for Asym-DiDiKTa (Fig. 2c and f). Both compounds pack following a one-dimensional slipped π–π stacking motif with interplanar chains along the c-axis for Sym-DiDiKTa [centroid⋯centroid distance 3.5876(18) Å] and along the a-axis for Asym-DiDiKTa [centroid⋯centroid distances 3.4697(13)–3.7685(13) Å]. The disposition of the tert-butyl groups in the compounds influences their packing. In the case of Sym-DiDiKTa, adjacent molecules are partially superimposed, forming π-stacked chain along the c-axis with the molecules stacked in a slipped manner (Fig. 2d and e). In contrast, for Asym-DiDiKTa, adjacent molecules display a greater degree of overlap and more π-stacking (Fig. 2g), resulting in symmetric pairs of adjacent molecules with the tert-butyl groups pointing in the opposite direction (Fig. 2h). Additional π-stacking interactions link these to form π-stacked chains along the a-axis. The distance between the central ring (e) between two nearest molecules is 9.1422(9) Å for Sym-DiDiKTa, whereas for Asym-DiDiKTa it is only 3.4699(17) Å. We also obtained single crystals of Sym-DiDiKTa from slow evaporation of a CH2Cl2:MeOH solution (8[thin space (1/6-em)]:[thin space (1/6-em)]2 ratio). Under these conditions, the crystal structure is comprised π-stacked columns of molecules along the crystallographic a-axis (Fig. S13a and b, ESI), with greater superimposition than in the previous case (distance between the central rings (e) of 3.8500(2) Å). This is achieved with the aid of MeOH molecules forming both strong and weak hydrogen bonds between and within the columns.


image file: d3tc00641g-f2.tif
Fig. 2 (a) Synthesis of Sym-DiDiKTa and Asym-DiDiKTa. (b) Schematic of molecular structure of Sym-DiDiKTa and Asym-DiDiKTa showing atom labels (double bonds omitted for clarity). (c and f) View showing Sym-DiDiKTa and Asym-DiDiKTa in the crystal structure (diagonal view). (d and g) Side view of the packing diagram of Sym-DiDiKTa and Asym-DiDiKTa. (e and h) Top view of the packing diagram of Sym-DiDiKTa and Asym-DiDiKTa.

We have previously demonstrated that DFT methods are not appropriate for accurately predicting the excited state properties of MR-TADF materials.44 Explicit inclusion of second-order electronic correlation effects using wavefunction-based methods such as spin component scaling second-order approximate Coupled–Cluster (SCS-CC2) calculations with the cc-pVDZ basis set addresses this problem, resulting in accurate ΔEST prediction for MR-TADF materials.45 The two isomers possess identical S1 and T1 energies of 2.93 eV and 2.69 eV, respectively, and thus a ΔEST of 0.24 eV (Fig. 3), which is similar to previously reported ketone-containing MR-TADF materials.46 Compared to the parent compound DiKTaEST = 0.27 eV and S1 = 3.45 eV), there is a modest decrease in ΔEST and significant stabilization of S1. The smaller computed ΔEST in Sym-DiDiKTa to Asym-DiDIKTa relative to DiKTa is due to the increase in the π-conjugation of these materials compared to DiKTa resulting in a lowering of the exchange energy, as has been documented in other extended MR-TADF systems, such as v-DABNA and OAB-ABP-1.26,46 The predicted stabilization of S1 results from the nitrogen atoms being positioned para to each other, which positively reinforce their electron-donating character, as has been previously reported.18,41 The oscillator strength associated with the S0S1 transition is significant at 0.26 and 0.27 for Sym-DiDiKTa and Asym-DiDIKTa, respectively. The difference density plots of S1 and T1 of each emitter highlight the alternating pattern of increasing and decreasing electronic density on neighbouring atoms that produce the emissive short-range charge transfer (SRCT) excited state, which is characteristic of MR-TADF materials.46


image file: d3tc00641g-f3.tif
Fig. 3 Difference density picture and excited state energies of Sym-DiDiKTa (a) and Asym-DiDiKTa (b) calculated at SCS-CC2/cc-pVDZ, where red and green lines indicate S1 and T1 energies respectively of DiKTa, (isovalue = 0.001).

Cyclic voltammetry (CV) and differential pulse voltammetry (DPV) recorded in degassed dichloromethane (Fig. 4a and b) document a reversible reduction wave at Ered = −0.96 and −0.94 V vs. SCE for Sym-DiDiKTa and Asym-DiDiKTa, respectively. The oxidation wave of Sym-DiDiKTa is more reversible than that of Asym-DiDiKTa (both at 1.53 V vs. SCE), revealing the impact of the regiochemistry that the tert-butyl groups play in terms of electrochemical stability. The corresponding HOMO and LUMO levels are nearly identical, at −5.87 eV for both compounds and −3.38 eV for Sym-DiDiKTa and −3.40 eV for Asym-DiDiKTa, respectively, which align well with the gas-phase DFT calculations at the PBE0/6-31G(d,p) level of theory (−5.94 eV and −2.69 eV, respectively, Table S11 and Fig. S20, ESI). The experimentally determined HOMO levels of Sym-DiDiKTa and Asym-DiDiKTa are similar to that of DiKTa (−5.93 eV), while the LUMO levels are significantly stabilized (LUMO of DiKTa = −3.11 eV).15 The electrochemical data are summarized in Table S9 (ESI).


image file: d3tc00641g-f4.tif
Fig. 4 Optoelectronic characterization of Sym-DiDiKTa and Asym-DiDiKTa: (a and b) cyclic and differential pulse voltammograms of Sym-DiDiKTa and Asym-DiDiKTa, respectively, in degassed CH2Cl2 with 0.1 M [nBu4N]PF6 as the supporting electrolyte and Fc/Fc+ as the internal reference (Fc/Fc+ = 0.46 V vs SCE).47 (c and d) Absorption (black line), steady-state PL spectra obtained in toluene at 300 K (blue line) and 77 K (red line; delay: 1 ns; gate time: 100 ns, λexc = 343 nm), and phosphorescence (Phos.; delay: 1 ms; gate time: 8.5 ms, λexc = 343 nm) spectra in toluene glass at 77 K (green olive line) of Sym-DiDiKTa and Asym-DiDiKTa, respectively.

The monomolecular photophysical properties of Sym-DiDiKTa and Asym-DiDiKTa were first studied in dilute toluene solution (Fig. 4c, d and Table 1). The UV-vis absorption spectra of both emitters in toluene are expectedly nearly identical, yet show significant differences compared to that of DiKTa in terms of the SRCT absorption band's wavelength (around 435 for DiKTa14,15 but around 515 nm for Sym-DiDiKTa and Asym-DiDiKTa). The molar absorptivity, ε, of the SRCT band for Sym-DiDiKTa and Asym-DiDiKTa is 26,325 M−1 cm−1 and 23,458 M−1 cm−1, respectively, assigned to the transition to S1 according to the SCS-CC2 calculations (Fig. 3). The ε is somewhat larger than reported for DiKTa (ε of DiKTa = 21[thin space (1/6-em)]000 M−1 cm−1),15 which is consistent with the trends in the calculated oscillator strength where f = 0.20 for DiKTa, compared to 0.26 and 0.27 for Sym-DiDiKTa and Asym-DiDiKTa, respectively. The absorption spectra of both Sym-DiDiKTa and Asym-DiDiKTa also show a high-energy shoulder at 485 nm (ε = 11[thin space (1/6-em)]680 and 10[thin space (1/6-em)]238 M−1 cm−1 for Sym-DiDiKTa and Asym-DiDiKTa, respectively), which likely originates from a vibronic band and not a transition to a higher-lying singlet state given that computed energies of the S2 state in each of these two compounds is ca. 0.48 eV higher in energy and the S0S2 transition possesses negligible oscillator strength.16 There is also a high-energy, high-intensity band at 373 nm (ε = 31[thin space (1/6-em)]900 M−1 cm−1 and 28[thin space (1/6-em)]527 M−1 cm−1 for Sym-DiDiKTa and Asym-DiDiKTa, respectively, Fig. 4c and d), which is assigned to transitions to S4 and S5, for Sym-DiDiKTa and Asym-DiDiKTa, respectively (Table S12, ESI) based on the comparison with the SCS-CC2 simulated absorption spectra (Fig. S21 and Table S12, ESI). The difference density plots of these states (Fig. S21, ESI) show that there is only minimal density situated on the central phenyl ring and more density situated on the carbonyl groups compared with the difference density pattern of the S1 state (vide supra).

Table 1 Optoelectronic properties of Sym-DiDiKTa and Asym-DiDiKTa
In toluene In film
λ abs /nm ε a/M−1 cm−1 λ PL /nm Φ PL in N2 (air)c/% FWHMd/nm (eV) S 1 /eV T 1 /eV ΔESTf/eV λ PL/nm Φ PL/% FWHMd/nm (eV)
a UV–vis absorption of CT transition. b Prompt emission in toluene degassing with N2. c Photoluminescence quantum yield in toluene relative to quinine sulfate in 1N H2SO4 (ΦPL = 54.6%) d Full-width at half-maximum. e Obtained using an integrating sphere under N2. f Energy gap between S1 and T1 calculated from the difference of the peaks of the fluorescence and phosphorescence spectra in toluene glass at 77 K. g 1 wt% Sym-DiDiKTa and Asym-DiDiKTa doped in mCP.
Sym-DiDiKTa 373/485/515 31900/11680/26325 540 69 (65) 29 (0.12) 2.26 2.02 0.24 542g 64 35 (0.14)g
Asym-DiDiKTa 373/485/516 28527/10238/23458 541 53 (50) 29 (0.12) 2.25 2.02 0.23 547g 57 35 (0.14)g


Both compounds display green emission in dilute toluene with emission maxima, λPL, of 540 nm and 541 nm for Sym-DiDiKTa and Asym-DiDiKTa, respectively, which are ca. 90 nm red-shifted from that of DiKTa (λPL = 453 nm). This bathochromic shift is corroborated by the SCS-CC2 calculations.19,20,31,48 Both compounds display narrow PL spectra at room temperature (FWHM = 29 nm), and small Stokes shifts of ca. 25 nm, which confirms the small degree of geometrical reorganization in the excited state owing to their conformationally rigid structure (Fig. 2c and d). The small degree of positive solvatochromism (Fig. S15 and Tables S2, S3, ESI) reflects the SRCT character of the emissive excited state.15 The S1 excited state energy levels were determined to be 2.26 and 2.25 eV, respectively, for Sym-DiDiKTa and Asym-DiDiKTa and the T1 excited state energy levels are identical at 2.02 eV, each obtained from the λPL of the respective prompt fluorescence and phosphorescence spectra in toluene glass at 77 K. We note that the nature of T1 and S1 are identical based on the difference density plots (Fig. 3). The corresponding ΔEST values are 0.24 eV and 0.23 eV, respectively, for Sym-DiDiKTa and Asym-DiDiKTa. These values match with those predicted by SCS-CC2 calculations (ΔEST = 0.24 eV for both compounds). The PL quantum yield, ΦPL, in toluene is 70% under N2, which decreases to 64% in air for Sym-DiDiKTa and 53% under N2 and 50% in air for Asym-DiDiKTa. The ΦPL values were next measured for vacuum-deposited 1 wt% doped thin films in 1,3-bis(N-carbazolyl)benzene (mCP). The ΦPL values were determined to be 64% and 57% for Sym-DiDiKTa and Asym-DiDiKTa, respectively (Table S5, ESI). The ΦPL values closely resemble those obtained in dilute toluene, which implies that non-radiative decay due to vibrations is not significant in these compounds.

We next investigated the solid-state photophysical properties of spin-coated 1 wt% Sym-DiDiKTa and Asym-DiDiKTa doped thin films in mCP. The low doping concentration was selected to mitigate the potential for undesired aggregation in the films. As shown in Fig. 5a and c, at 300 K, Sym-DiDiKTa and Asym-DiDiKTa show a similar emission profile with λPL at 542 and 547 nm, respectively, values that are close to the prompt emission maximum in toluene. A small FWHM of 35 nm (0.13 eV) was calculated for both compounds in the films, which is slightly broader than the FWHM of 29 nm (0.12 eV) determined in toluene, indicating the influence of the matrix on the conformational stabilization of the excited states. Another aspect to consider are concentration-dependent aggregation effects since the concentration of emitters at 1 wt% doping in the film is higher than that of the 106 M solution. The average τd values are 4.6 ms and 3.0 ms for Sym-DiDiKTa and Asym-DiDiKTa, respectively (Fig. 5 and Table S7, ESI). We then compared the oxygen dependence of the PL spectrum at room temperature. The PL spectrum in air shows a small decrease in intensity compared to the spectrum under vacuum (Fig. S17a and b, ESI), indicating a weak involvement of triplet excited states. The temperature-dependent PL spectra (Fig. 5a and c) and temperature-dependent time-resolved PL decays (Fig. 5b and d) of both emitters document the characteristic decrease in intensity and in the contribution of the delayed emission, respectively, with decreasing temperature. This could be due to the MR-TADF behavior only being apparent in a suitable host matrix due to exciplex-like host-emitter interactions.29


image file: d3tc00641g-f5.tif
Fig. 5 (a and c) Temperature-dependent PL study of 1 wt% of Sym-DiDiKTa and Asym-DiDiKTa, respectively, in mCP, λexc = 350 nm. (b and d) Temperature-dependent time-resolved PL decays for 1 wt% Sym-DiDiKTa and Asym-DiDiKTa, respectively, in mCP matrix (λexc = 378 nm).

OLED characterization

We fabricated vacuum-deposited OLEDs using Sym-DiDiKTa and Asym-DiDiKTa as the emitters. The following device configuration was used: indium tin oxide (ITO)-coated glass (100 nm)/TAPC (35 nm)/TCTA (10 nm)/mCP: 3 wt% of Sym-DiDiKTa or Asym-DiDiKTa (20 nm)/TmPyPB (30 nm)/Liq (2 nm)/Al (100 nm). 1,1-Bis[(di-4-tolylamino)phenyl]cyclohexane (TAPC) is the hole-transporting layer, 4,4′,4-tris(carbazol-9-yl)triphenylamine (TCTA) is used for electron-blocking and host layers, 1,3,5-tris(3-pyridyl-3-phenyl)benzene (TmPyPB) is the electron-transporting layer, and lithium 8-hydroxyquinolinolate (Liq) and aluminum are the electron injection and cathode layers, respectively. Fig. 6 and Table 2 summarize all the device characteristics. TADF-only devices based on Sym-DiDiKTa (Device I) and Asym-DiDiKTa (Device II) emitted green narrowband electroluminescence, λEL, at 543 and 544 nm, respectively, values that are consistent to their corresponding λPL. The FWHMs of both Devices I and II are 36 nm, which resulted in CIE coordinates of (0.362, 0.623) and (0.376, 0.613), respectively. The EQEmax of Device I is 9.8%, which is slightly lower than the 10.5% measured for Device II. We hypothesized that the moderate ΦPL in the mCP-doped films limits the EQEmax values in Devices I and II. The moderate ΦPL may be due to the long-lived delayed fluorescence that permits a greater probability that non-radiative decay processes such as triplet-polaron quenching and triplet–triplet annihilation will contribute to the decay of the excitons. Both devices suffered from severe efficiency roll-off issues, which in part are due to the long delayed fluorescence lifetimes of Sym-DiDiKTa and Asym-DiDiKTa. Moreover, the linear decrease in the EQE – current density curve indicates possible exciton-polaron annihilation processes, which can be ascribed to trap formation by the emitters.
image file: d3tc00641g-f6.tif
Fig. 6 (a) EQE versus current density curves of Devices I–III. (b) Electroluminescence spectra of Devices I–III at 500 cd m−2.
Table 2 Summary of device characteristics
Device Dopant V on/Va EQE/%b λ EL/nmc Max. brightness (cd m−2)d FWHM/nmc CIE (x, y)c
a Voltage at 1 cd m−2. b Value at maximum, 100 cd m−2 and 1000 cd m−2. c Value at 500 cd m−2. d Maximum brightness.
I 3 wt% Sym-DiDiKTa 3.5 9.8/1.8/0.8 543 4310 36 (0.359, 0.624)
II 3 wt% Asym-DiDiKTa 4 10.5/1.3/0.8 544 3989 36 (0.369, 0.616)
III 3 wt% Asym-DiDiKTa: 20 wt% 4CzIPN 3.2 19.9/9.9/6.4 548 53625 56 (0.397, 0.592)


To improve the device performance, we implemented a hyperfluorescence (HF) strategy in Device III with the following device structure: indium tin oxide (ITO)-coated glass (100 nm)/HAT-CN (10 nm)/Tris-PCz (30 nm)/mCBP (5 nm)/mCBP: 20 wt% 4CzIPN: 3 wt% Asym-DiDiKTa (30 nm)/T2T (10 nm)/BPy-TP2 (40 nm)/Liq (2 nm)/Al (100 nm), where 1,4,5,8,9,11-hexaazatriphenyl-enehexacarbonitrile (HAT-CN) is the hole-injection layer, 9-phenyl-3,6-bis(9-phenyl-9Hcarbazol-3-yl)-9H-carbazole (Tris-PCz) is the hole-transporting layer, mCBP is used in the exciton-blocking and host layers, 1,2,3,5-tetrakis(carbazol-9-yl)-4,6-dicyanobenzene (4CzIPN) is a green TADF assistant dopant, 2,4,6-tris(biphenyl-3-yl)-1,3,5-triazine (T2T) is the hole-blocking layer and 2,7-di(2,2′-bipyridin-5-yl)triphenylene (BPy-TP2) is the electron-transporting layer, and lithium 8-hydroxyquinolinolate (Liq) and Al are the electron injection and cathode layers, respectively. Gratifyingly, the device performance improved and an EQEmax of 19.9% was achieved along with an enhanced maximum brightness of 53625 cd m−2. The HF device not only resulted in a better EQE, but also reduced the efficiency roll-off when compared to Device II. The λEL is red-shifted to 548 nm and there is a slightly larger FWHM of 56 nm. The broader FWHM may originate from an incomplete energy transfer from 4CzIPN to Asym-DiDiKTa.

LEC devices

The light-emitting electrochemical cell (LEC) can be comprised of solely air-stable materials and feature a very simple and robust device structure in the form of a single-layer active material sandwiched between two electrodes. This renders the LEC technology highly fit for scalable and cost-efficient printing and coating fabrication under ambient air.49,50 The characteristic feature of LEC devices is the combination of mobile ions with the emissive organic semiconductor within the emissive layer.51,52 These mobile ions redistribute when a voltage is applied, and enable p-type electrochemical doping of the organic semiconductor at the anode and n-type doping at the cathode. With time, these doping regions grow in size and make contact under the formation of a p–n junction. The fact that Sym-DiDiKTa displays highly reversible electrochemical oxidation and reduction behaviour in the cyclic voltammetry experiments (Fig. 4a) suggests that it could be fit for the task of the emissive organic semiconductor in a LEC device.

We fabricated and characterized LEC devices with the following configuration: indium tin oxide (140 nm)/poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (40 nm)/26DCzPPy (44 wt%):POT2T (44 wt%):Sym-DiDiKTa (4 wt%):THABF4 (8 wt%) (100 nm)/Al (100 nm), where THABF4 (tetrahexylammonium tetrafluoroborate) is the ionic liquid electrolyte that contributes the mobile ions, and 6-bis(3-carbazol-9-yl)pyridine (26DCzPPy):(1,3,5-triazine-2,4,6-triyl)tris(benzene-3,1-diyl)tris(diphenylphosphine oxide) (POT2T) is a blend-host matrix, which was introduced to enable for the formation of a uniform solution-processed thin film and to suppress losses by exciton-polaron53 and exciton-exciton quenching.

Fig. 7a presents the steady-state EL spectrum recorded during the driving with a constant current density of 77 mA cm−2, with the λEL at 551 nm and the FWHM being 60 nm. The broadening of the EL spectrum of the LEC device in comparison to the PL spectra in Fig. 5a indicates the formation of exciplexes with the blend host. This conclusion is supported by the fact that the FWHM of the EL spectrum is essentially independent of the guest concentration for a guest concentration range of 1 to 8 wt% (Fig. S22, ESI). Fig. 7b details the voltage and luminance transients recorded during the early stages of the constant-current driving. The observed initial decrease of the voltage is a characteristic indicator of conductivity-enhancing electrochemical doping, whereas the increase in luminance is in line with the gradual formation of a p-n junction, where electrons and holes can recombine efficiently into excitons. Importantly, these observations imply that the Sym-DiDiKTa emitter can be in situ electrochemically p- and n-type doped during LEC operation. This conclusion is further supported by the fact that the LEC device delivered a significant luminance of 300 cd m−2 despite being equipped with an air-stable Al cathode in direct contact with the active emissive material. Finally, the luminance turn-on time is a direct indicator of the ion mobility in the active material,54,55 and the comparatively fast turn-on time of less than 2 s to 100 cd m−2 demonstrates that the ion mobility in the active material is high.


image file: d3tc00641g-f7.tif
Fig. 7 (a) The steady-state EL spectrum. (b) The temporal evolution of the luminance (left y-axis, solid black squares) and the drive voltage (right y-axis, open red circles) for the ITO/PEDOT:PSS/26DCzPPy:POT2T: Sym-DiDiKTa:THABF4/Al LEC device. The LEC devices were driven by a constant current density of 77 mA cm−2.

Conclusion

In summary, new amine/carbonyl-based MR-TADF materials were developed by an approach that expands the π-conjugated backbone to show green-yellow emission. The regio-functionalization of the tert-butyl groups was shown to significantly impact the single-crystal packing structure. With a ΔEST of around 0.23 eV in toluene, the narrowband emitters, FWHM, of 29 nm, display TADF activity with a τd of 4.6 ms and 3.0 ms for Sym-DiDiKTa and Asym-DiDiKTa, respectively. Application in OLEDs provided devices with electroluminescence maxima at around 544 nm, and an EQEmax of circa 10% which low value is attributed to the long delayed lifetimes of this class. Upon further studies in hyperfluorescence devices, an EQE of 19.9% was finally obtained, showing the promise of this class of molecules towards this strategy. We also show the first examples of a LEC device incorporating an MR-TADF emitter. With a λEL at 551 nm and a larger FWHM of 60 nm due to formation of exciplexes with the host, the device based on Sym-DiDiKTa delivered a significant luminance of 300 cd m−2 and high ion mobility with a fast turn-on time of less than 2 s to 100 cd m−2.

Conflicts of interest

The authors declare that they have no conflict of interest.

Acknowledgements

The St Andrews team would like to thank EPSRC (EP/P010482/1) and the Leverhulme Trust (RPG-2016-047) for financial support. Computational resources have been provided by the Consortium des Équipements de Calcul Intensif (CÉCI), funded by the Fonds de la Recherche Scientifiques de Belgique (F. R. S.-FNRS) under Grant no. 2.5020.11. Y. O. acknowledges funding by the Fonds de la Recherche Scientifique-FNRS under Grant no. F.4534.21 (MIS-IMAGINE). The authors also acknowledge Ms N. Nakamura and Ms K. Kusuhara for their technical assistance with this research. This work was supported financially by the JSPS Core-to-Core Program (grant number: JPJSCCA20180005), Kyulux Inc, the Swedish Research Council, the Swedish Energy Agency, and Bertil & Britt Svenssons stiftelse för belysningsteknik.

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Footnotes

The research data supporting this publication can be accessed at https://doi.org/10.17630/f844ce22-cf6b-413d-ae79-70e2e38a1f74
Electronic supplementary information (ESI) available: A summary of prior examples of carbonyl-containing MR-TADF emitters, experimental details, synthesis procedures and characterization data, NMR spectra, HRMS, HPLC, X-ray crystallographic data, supplemental photophysical data, electrochemical data, xyz coordinate file for computations. CCDC 2225501–2225503. For ESI and crystallographic data in CIF or other electronic format see DOI: https://doi.org/10.1039/d3tc00641g

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