DOI:
10.1039/D3QM00653K
(Research Article)
Mater. Chem. Front., 2023,
7, 5413-5421
TADF emitters based on a tri-spiral acridine donor and a spiro-B-heterotriangulene acceptor with high horizontal dipole orientation ratios and high efficiencies in deep-blue OLEDs†
Received
8th June 2023
, Accepted 24th August 2023
First published on 5th September 2023
Abstract
Developing thermally activated delayed fluorescence (TADF) emitters showing high horizontal transition dipole orientation and molecular rigidity is crucial for enhancing the color purity and performance of deep-blue organic light-emitting diodes (OLEDs). Here, we report two linearly expanded TADF emitters, O-tsAC-BAsBP (1) and S-tsAC-BAsBP (2), based on a tri-spiral acridine donor and a spiro-fluorenyl B-heterotriangulene acceptor. These emitters exhibit deep-blue emissions, with peaks centered at 458–467 nm for 1 and 462–469 nm for 2, respectively, in the host films, with high photoluminescence quantum yields, small singlet–triplet energy splitting (ΔEST < 0.05 eV), and short delayed fluorescence lifetimes (τd < 2 μs). Theoretical studies demonstrate that effective spin–orbit coupling between the charge transfer singlet (1CT) and acceptor-centered local triplet (3LE) excited states accelerates the reverse intersystem crossing (RISC) process, resulting in a high RISC rate constant of ∼106 s−1. Notably, both emitters exhibit very high horizontal dipole orientation ratios (Θ‖) of ∼93% in their doped host films. Owing to the outstanding TADF characteristics and high Θ‖ values, TADF-OLEDs incorporating emitters 1 and 2 achieve high maximum external quantum efficiencies of 27.4% and 31.5%, respectively, in the deep-blue region.
Introduction
Organic thermally activated delayed fluorescence (TADF) materials have attracted ever-growing attention as promising emissive materials in organic light-emitting diodes (OLEDs) because they can effectively harvest triplet excitons through a reverse intersystem crossing (RISC) process, thereby achieving 100% internal quantum efficiency (IQE) in OLEDs.1–7 In general, TADF emitters are composed of donor (D) and acceptor (A) units with a largely twisted D–A structure. The D and A segments possess the well-separated HOMO and LUMO, respectively, leading to a small energy gap between the S1 and T1 states (ΔEST). This enables TADF emitters to undergo a fast RISC process. In addition to the IQE, the light-outcoupling efficiency (ηout) of a device is another key parameter that governs the external quantum efficiency (EQE) of the device.8 Accordingly, achieving a high ηout is necessary to boost the EQE of OLED devices. Many studies reveal that ηout can be significantly improved if the horizontal orientation ratio (Θ‖) of the transition dipole moment (TDM) is above the value corresponding to the completely random orientation case (Θ‖ = 67%). Note that the majority of light is emitted in a direction perpendicular to the TDM vector. Therefore, a significant portion of light emitted from the horizontally oriented TDM can be directly outcoupled to air instead of being coupled to wave guided modes (Fig. S1 in the ESI† for the illustrative description). Hence, a high Θ‖ in the emissive layer in OLEDs can be highly beneficial for improving the EQE without the need for a separate outcoupling structure.9–11 The factors influencing Θ‖ include, but are not limited to, molecular shapes or the presence of certain functional groups that promote the anisotropic molecular arrangement during deposition.12 For instance, TADF emitters in a linear or a planar shape have shown high Θ‖ and, as a result, exhibited high electroluminescence (EL) performances.13–15 However, the elongated molecular conjugation and expanded molecular plane can often compromise the emission color and efficiency of TADF emitters due to various internal D–A interaction strengths or strong molecular interactions in the aggregated state.16,17
To address this issue, spiro-shaped donors and acceptors have been introduced into the D–A backbone to enhance the Θ‖ values without causing serious emission quenching, thanks to large steric hindrance of the spiro-groups.18–21 Among the donors, spiro-acridine (sAC) groups have been reported to increase the molecular rigidity and Θ‖ values of the emitters.22–25 These are also effective in lowering the HOMO energy level due to the relatively weak electron-donating ability caused by a weak hyper-conjugation effect.21 Particularly, when combined with boron-based acceptors, TADF emitters containing sAC donors have demonstrated outstanding performances in blue OLEDs that demand the emitters with high molecular stability.18,24,26 Furthermore, tri-spiral acridine (tsAC), which is a more structurally reinforced sAC derivative, has been recently employed in blue emitters. These emitters exhibited high molecular rigidity, an improved PLQY, and a high Θ‖ value of ∼90%.15,26 Meanwhile, TADF emitters incorporating spiro-type acceptor units have rarely been reported.18,27–29 A representative example of such acceptors is spiro-fluorenyl-B-heterotriangulene, which exhibits high structural stability due to the presence of fully tethered aryl groups around the boron center.30,31 The resulting D–A-type TADF emitters with the spiro-fluorenyl-B-heterotriangulene unit exhibited blue emissions with near-unity PLQYs and high Θ‖ values of ∼90%, irrespective of the presence of a spiro-donor unit.30
Taking these into account, we herein report two linearly expanded TADF emitters, O-tsAC-BAsBP (1) and S-tsAC-BAsBP (2), composed of a tri-spiral acridine (tsAC) donor and a spiro-fluorenyl-B-heterotriangulene (BAsBP) acceptor to enhance the light-outcoupling efficiency in blue OLEDs. The presence of bulky spiral D and A moieties in 1 and 2 is also expected to increase both the molecular rigidity and steric hindrance, thereby effectively reducing intermolecular interactions. We found that both emitters showed deep-blue emissions with excellent TADF characteristics in the doped host films. These emitters exhibited near-unity PLQYs, small singlet–triplet energy splitting (ΔEST < 0.05 eV), short delayed fluorescence lifetimes (τd < 2 μs), and fast RISC (kRISC ∼106 s−1). Remarkably, both emitters exhibited very high Θ‖ values of ∼93%, which is the highest among the emitters containing spiro-acridine donors. Thanks to their outstanding TADF characteristics and high Θ‖ values, the corresponding TADF-OLEDs displayed high maximum EQEs of 27%–31% in the deep-blue region.
Results and discussion
Synthesis and characterization
Two D–A compounds, O-tsAC-BAsBP (1) and S-tsAC-BAsBP (2), were synthesized following the procedures depicted in Scheme 1. The oxygen-bridged acridine donor (O-tsACH, 1e) was newly prepared using a modified reaction pathway based on the synthesis of the sulfur-bridged, tri-spiral acridine donor (S-tsACH, 2e).15 The final products (1 and 2) were obtained in high yields through Buchwald-Hartwig amination reactions between the X-tsACH (X = O, S) donors and a bromo-substituted spiro-fluorenyl B-heterotriangulene acceptor (Br-BAsBP).30 Both compounds were analyzed by 1H NMR spectroscopy and elemental analyses, while 11B and 13C NMR spectra of the compounds could not be obtained due to the poor solubility in organic solvents (Fig. S2–S7, ESI†). These compounds were chemically stable in solution and solid states under ambient conditions and also displayed high thermal stability evidenced by their elevated decomposition temperatures (Td5 = 466 °C for 1 and 464 °C for 2 at 5% weight loss). Notably, the Td5 values were superior to that of the reference compound, sAC-BAsBP (3, Td5 = 420 °C), which consisted of mono spiro-donor and spiro-acceptor units (Fig. S8, ESI†).30 This result indicates that the tri-spiral skeleton can greatly improve the thermal stability of boron-based D–A compounds.
|
| Scheme 1 Conditions: (i) n-BuLi, THF, −78 °C, then 1.0 M HCl, MeOH, and RT. (ii) c-HCl, AcOH, and reflux. (iii) n-BuLi, THF, −78 °C, then 1.0 M HCl, MeOH, and RT. (iv) c-HCl, AcOH, and reflux. (v) Pd(t-Bu3P)2, Br-BAsBP, t-BuONa, toluene, and reflux. | |
Photophysical properties
The UV/Vis absorption and photoluminescence (PL) spectra of 1 and 2 were first obtained in toluene at room temperature (Fig. 1 and Table 1). In addition, the absorption spectra of the donor (X-tsACH; X = O or S) and acceptor (HBAsBP) molecules were recorded to understand the electronic transition of 1 and 2 (Fig. S9, ESI†). The intense absorption in the high-energy region of 270–350 nm was attributable to the local π–π* states of the D and A units.32,33 The broad and weak absorption in the low-energy region of 350–450 nm is assigned to the intramolecular charge transfer (ICT) transition from the D to A units (Fig. 1b and Table 1). The similar absorption onset of both compounds resulted in a comparable HOMO–LUMO energy gap (Eg) of 2.93 eV, slightly higher in energy than that of sAC-BAsBP (3, 2.91 eV).30 This finding supports the blue-shifted emission of 1 and 2 compared to that of 3 (see below). Compounds 1 and 2 underwent X-tsAC (X = O, S)-centered irreversible oxidations with onset oxidation potentials of 0.54 V for 1 and 0.52 V for 2, respectively (Fig. S10, ESI†). Accordingly, the comparable HOMO energy levels were determined to be −5.34 eV for 1 and −5.32 eV for 2, respectively. In combination with the Eg values and HOMO levels, the LUMO energy levels of −2.41 eV for 1 and −2.39 eV for 2, respectively were deduced. These results indicate that the O- and S-containing tsAC donors have similar electronic effects on the HOMO and LUMO presumably due to substitution of the O and S atoms at a distal position. Both compounds displayed deep-blue emissions with a peak centered at 457 nm in their PL spectra, and their broad and structureless emissions originated from an ICT transition (Fig. 1b). These compounds exhibited decent photoluminescence quantum yields (PLQYs) of 70–74% in deoxygenated toluene, whereas the PLQYs were dramatically dropped to 31% with a decrease in the PL intensity in oxygen-saturated toluene, as a result of the triplet state quenching by oxygen (Fig. S11, ESI†). The transient PL decay traces at room temperature displayed characteristic prompt (τp) and delayed (τd) components, with a τp value of 20 ns and a τd value of 5.83–7.50 μs, respectively (Fig. 1c). Next, the photophysical properties of 20 wt%-doped films of 1 and 2 in a DPEPO host matrix were investigated (Fig. 1d). The PL spectra featured deep-blue emissions centered at 467 nm (1) and 469 nm (2), respectively, which were red-shifted compared to those obtained in toluene. The redshifts can be primarily attributed to the increased polarity of the host matrix, which stabilizes the CT excited state.34,35 The PLQYs and full width at half maximums (FWHMs) for the films were 100% and 63 nm for 1, and 84% and 66 nm for 2, respectively. The increased PLQY and narrower FWHM of the films compared with the results in toluene (PLQY = 70–74%, FWHM = 69 nm) can be attributed to the suppressed intramolecular vibrations and rotations in the rigid state.36 The fluorescence and phosphorescence spectra obtained at 77 K demonstrated an involvement of CT excited states in the emission, along with small ΔEST values of 0.035 eV for 1 and 0.050 eV for 2, respectively (Fig. 1e and Fig. S12, ESI†).
|
| Fig. 1 (a) Chemical structures of 1 and 2. (b) Absorption and PL spectra of 1 and 2 in toluene (c = 2.0 × 10−5 M, λex = 310 nm). (c) Transient PL decay of 1 and 2 in toluene at 298 K. (d) PL spectra of 20 wt% doped films of 1 and 2 in a bis[2-(diphenylphosphino)phenyl]ether oxide (DPEPO) host. (e) Fluorescence and phosphorescence spectra of 1 and 2 at 77 K. (f) Transient PL decay of 1 and 2 at 298 K. (g) Temperature-dependent PL decay of 1. (h) Arrhenius plots of kRISC for 1 and 2. | |
Table 1 Photophysical data and rate constants of 1 and 2
Compound |
|
λ
abs (nm) |
λ
PL (nm) |
Φ
PL
(%) |
τ
p
(ns) |
τ
d
(μs) |
E
S/ETe (eV) |
ΔESTf (meV) |
k
r
(107 s−1) |
k
ISC
(107 s−1) |
k
RISC
(105 s−1) |
E
a
(meV) |
In N2-filled toluene at 298 K (c = 2.0 × 10−5 M, λex = 310 nm).
In 20 wt% doped films in a DPEPO host.
Absolute PLQYs.
Prompt (τp) and delayed (τd) PL decay lifetimes.
Singlet (ES) and triplet (ET) energy deduced from the onset of fluorescence and phosphorescence spectra at 77 K.
ΔEST = ES − ET.
k
r, kISC, and kRISC are the fluorescence radiative decay, intersystem crossing, and RISC rate constants, respectively.
Activation energies of RISC.
|
O-tsAC-BAsBP (1) |
sola |
394 |
457 |
70 |
20 |
5.83 |
|
|
|
|
|
|
|
Filmb |
|
467 |
100 |
16 |
1.55 |
2.89/2.86 |
35 |
4.06 |
2.23 |
9.99 |
15 |
S-tsAC-BAsBP (2) |
sola |
395 |
457 |
74 |
20 |
7.50 |
|
|
|
|
|
|
|
Filmb |
|
469 |
84 |
14 |
1.98 |
2.95/2.90 |
50 |
4.68 |
1.57 |
6.86 |
13 |
Notably, the transient PL decays showed short-lived delayed fluorescence lifetimes (τd = 1.55–1.98 μs), which is in accordance with the very small ΔEST values (Fig. 1f). The delayed fluorescence intensities were gradually increased with an increase of temperature from 120 K to 290 K, confirming the TADF nature (Fig. 1g and Fig. S13, ESI†). The excited state dynamics of 1 and 2 were further understood by calculating the rate constants of intersystem crossing (kISC) and RISC (kRISC) (Table 1).37 The kISC and kRISC values were estimated to be in the orders of ∼107 and ∼106 s−1, respectively, for both compounds, indicating fast spin–flip processes.38,39 The higher kRISC of 1 than that of 2 was aligned with the shorter delayed fluorescence lifetime of 1. The Arrhenius plots of kRISC resulted in the very small activation energies of RISC (EaRISC), equal to 15 meV for 1 and 13 meV for 2 (Fig. 1h and Table 1). The similar tiny EaRISC values also supported the fast RISC process in 1 and 2. Moreover, the values were smaller than the corresponding ΔEST values, indicating the involvement of the higher-lying T2 state in the RISC process, accompanied by vibronic coupling between the T1 and T2 states.40–42
Theoretical studies
Density functional theory (DFT) and time-dependent DFT (TD-DFT) calculations were conducted using the PBE0 hybrid functional43 and the 6-31+G(d,p) basis set to elucidate the molecular geometries and electronic structures of 1 and 2 in the ground and excited states. The energy differences between S1 and T1 states were computed using the Tamm–Dancoff approximation (TDA).44,45 In the optimized molecular structures, the acridine donor and B-heterotriangulene acceptor fragments are connected in a highly twisted conformation with a large dihedral angle of ∼90° owing to the steric hindrance caused by the acridine rings (Fig. S14, ESI†). The HOMO and LUMO are mainly distributed on the acridine donor and the B-heterotriangulene acceptor, respectively. The well-separated HOMO and LUMO resulted in very small ΔEST values of 11–12 meV, which aligns with the experimental results. Overall, the numerical values for the optimized structures of 1 and 2, such as the dihedral angle, MO energy, HOMO–LUMO gap, ΔEST, and overlap integral (IH/L) between the HOMO and the LUMO, were comparable for both compounds, accounting for their similar photophysical properties. This result can be attributed to the negligible contributions from the O- and S-containing ring fragments of the tsAC donor to the HOMO. Natural transition orbitals (NTOs) of 1 and 2 were examined to analyze the nature of the excited states (Table 2). The hole and electron NTOs of the S1 and T1 states are predominantly localized in the D and A units, respectively, which is indicative of the CT excited states (1CT and 3CT). This result is in good accordance with the fluorescence and phosphorescence spectra of 1 and 2 at 77 K (Fig. S12, ESI†). Due to the same CT nature of the S1 and T1 states, spin–orbit coupling (SOC) between the two states could be weak according to the El-Sayed rule.41,46 Thus, we examined the NTOs of the next higher-lying triplet (T2) state of 1 and 2 and found that both the hole and electron NTOs of the T2 states are localized on the spiro-fluorenyl moiety in the BAsBP acceptor units, indicating an LE character (3LEA) of the T2 states. To support the finding, we first analyzed the NTOs of the pristine D and A molecules (Fig. S15, ESI†). The T1 states of X-tsACH (X = O, S) and HBAsBP are localized on the acridine ring and the spiro-fluorenyl moiety, respectively, with the lower computed T1 energy level of HBAsBP (ET(A) = 2.930 eV) compared to that of X-tsACH (ET(D) = 3.131 eV). Next, we recorded the phosphorescence spectra of the pristine donor molecules at 77 K (Fig. S16, ESI†).
Table 2 Natural transition orbitals (NTOs) for the excited states of 1 and 2 obtained using the TDDFT calculations at the PBE0/6-31+G(d,p) level of theory. The numerical values for spin–orbit coupling matrix elements and transition rates for the RISC processes are obtained using the PBE0/6-311G(d,p)//6-31+G(d,p) level of theory
1
|
Hole |
Electron |
2
|
Hole |
Electron |
T2 (3LEA) (3.111 eV) |
|
|
T2 (3LEA) (3.107 eV) |
|
|
T1 (3CT) (2.726 eV) |
|
|
T1 (3CT) (2.731 eV) |
|
|
S1 (1CT) (2.737 eV) |
|
|
S1 (1CT) (2.743 eV) |
|
|
〈S1|ĤSOC|T1〉 |
0.104 cm−1 |
|
〈S1|ĤSOC|T1〉 |
0.112 cm−1 |
|
〈S1|ĤSOC|T2〉 |
0.380 cm−1 |
|
〈S1|ĤSOC|T2〉 |
0.369 cm−1 |
|
k
T1→S1
|
5.86 × 105 s−1 |
|
k
T1→S1
|
6.00 × 105 s−1 |
|
k
T2→S1
|
1.85 × 107 s−1 |
|
k
T2→S1
|
2.27 × 107 s−1 |
|
Both the X-tsACH donors showed the identical T1 energy levels of 3.061 eV, higher than that of the HBAsBP acceptor molecule (3LEA = 2.877 eV).30 These theoretical and experimental results confirm the 3LEA character of the T2 states of 1 and 2. Accordingly, the significant SOC matrix elements (SOCMEs) between the S1 (1CT) and T2 (3LE) states (〈S1|ĤSOC|T2〉 = 0.369–0.380 cm−1) were comparably obtained for 1 and 2 as anticipated by the El-Sayed rule (Table 2). The values were also over three times greater than those between the S1 (1CT) and T1 (3CT) states (〈S1|ĤSOC|T1〉 = 0.104–0.112 cm−1). Furthermore, the calculated RISC rate constants between the T2 and S1 states (kT2→S1 = 1.85–2.27 × 107 s−1) were significantly higher than those between the T1 and S1 states (kT1→S1 = 5.86–6.00 × 105 s−1). Therefore, these results highlight that the SOC between the T2 and S1 states can boost the rate of RISC in 1 and 2, thereby supporting the observed high RISC rates.38,47,48
Electroluminescence properties
The electroluminescence (EL) performances of 1 and 2 as the TADF emitters were finally evaluated by fabricating blue OLEDs with the following device structures (Fig. 2a): glass/indium-tin-oxide (ITO, 70 nm)/molybdenum trioxide (MoO3, 5 nm)/1,1-bis[(di-4-tolylamino)phenyl]cyclohexane (TAPC, 40 nm)/tris(4-carbazoyl-9-ylphenyl)amine (TCTA, 10 nm)/1,3-bis(N-carbazolyl)benzene (mCP, 10 nm)/DPEPO:emitter (10, 20 wt%, 25 nm)/DPEPO (5 nm)/2,2′,2′′-(1,3,5-benzinetriyl)-tris(1-phenyl-1-H-benzimidazole) (TPBi, 35 nm)/lithium fluoride (LiF, 1 nm)/aluminum (Al, 100 nm). DPEPO was selected as the host material due to its high T1 level (∼3.0 eV) suitable for efficient energy transfer to the emitters.5,49 We employed two different emitter concentrations (10 and 20 wt%) in the emissive layer to optimize the performances of TADF-OLEDs. The EL characteristics of the devices are summarized in Table 3 and Fig. 2b–d and Fig. S18 and S19, ESI.†
|
| Fig. 2 (a) Device structure and energy level diagram (eV) of the TADF-OLEDs. (b) EL spectra of D1 an D4 and the photograph of the working D4 device. (c) Current density–voltage–luminance (J–V–L) characteristics of D1 and D4. (d) External quantum efficiency–luminance (ηEQE–L) characteristics of D1 and D4. (e) Angle-dependent PL intensity of the emitting layer with emitter 2. (f) The contour plot of the theoretical maximum EQEs for device D4 as a function of the TPBi and TAPC thicknesses. The star symbol indicates the maximum EQE value for D4. | |
Table 3 Device characteristics of TADF-OLEDs
Devicea |
Emitter (wt%) |
λ
EL (nm) |
λ
FWHM
(nm) |
CIE (x, y)c |
V
on
(V) |
EQEe (%) |
PEf (lm W−1) |
CEg (cd A−1) |
ITO (70 nm)/MoO3 (5 nm)/TAPC (40 nm)/TCTA (10 nm)/mCP (10 nm)/DPEPO:emitter(10, 20 wt%, 25 nm)/DPEPO (5 nm)/TPBi (35 nm)/LiF (1 nm)/Al (100 nm).
Full width at half maximum (FWHM).
Color coordinates (CIE 1931) at a maximum luminance.
Applied voltage at a luminance of 1 cd m−2.
External quantum efficiency: maximum, then the value at 1000 cd m−2.
Maximum power efficiency: maximum, then the value at 1000 cd m−2.
Maximum current efficiency: maximum, then the value at 1000 cd m−2.
|
D1
|
1 (20) |
469 |
58 |
(0.137, 0.147) |
3.7 |
27.4/18.4 |
32.3/11.8 |
43.2/29.0 |
D2
|
2 (20) |
467 |
58 |
(0.133, 0.140) |
3.8 |
24.7/16.6 |
25.0/9.6 |
32.7/22.0 |
D3
|
1 (10) |
465 |
57 |
(0.134, 0.108) |
3.8 |
22.5/15.4 |
23.5/9.1 |
22.8/15.6 |
D4
|
2 (10) |
466 |
55 |
(0.132, 0.117) |
4.0 |
31.5/17.6 |
30.2/8.4 |
44.0/24.6 |
At 20 wt% doping concentration, devices D1 and D2 with emitters 1 and 2, respectively, exhibited blue EL emissions centered at 469 and 467 nm, comparable to the PL spectra of the emitters doped in the host films. The CIEy values for the EL emissions of the two devices fell within 0.15. Notably, D1 and D2 exhibited high maximum EQEs (EQEmax) of 27.4% for D1 and 24.7% for D2, respectively, which are in accordance with the PLQYs of the emitters doped in the host films (Table 1). Meanwhile, for the 10 wt%-doped devices (D3 and D4), the EL spectra underwent slight blue-shifts, showing the EL peaks at 465 and 466 nm, respectively. Along with the narrow FWHMs of 55–57 nm, the EL spectra led to the CIEy values of ∼0.11, corresponding to the deep-blue emission of the devices. It is noticeable that the observed FWHMs are slightly narrower than those obtained with previous emitter 3 (FWHM = 57–58 nm), presumably due to the increased molecular rigidity offered by the tri-spiral donor structure.26 Remarkably, device D4 with emitter 2 exhibited a very high EQEmax of 31.5%, although the EQE of D3 based on 1 was somewhat reduced to 22.5% at the 10 wt% emitter concentration. To partly explain this result, we prepared 10 wt%-doped host films of 1 and 2 in a DPEPO host and measured their photophysical properties (Table S1, ESI†). Interestingly, the PLQY of the host film doped with 2 reached near-unity, while that with 1 exhibited 82%. Thus, the high EQE of D4 could be understood with the increased PLQY of 2 at 10 wt% doping. Although the EQEmax values for the devices with 1 and 2 showed an opposite trend depending on the doping concentration of the emitters, the observed efficiencies could be ranked among the highest value for the deep-blue devices with D–A-type emitters (CIEy < 0.12).26,50–52 In addition, since the ηout is one of the important factors governing the EQE of a device, we estimated the Θ‖ of the doped host films of 1 and 2 utilizing angle-dependent PL measurements. As shown in Fig. 2e and Fig. S20 (ESI†), both films exhibited very high Θ‖ values of 93.0% and 93.5%, respectively. The values are higher than that of previous emitter 3 containing sAC and BAsBP units (∼90%).30 Therefore, the increased molecular length and rigidity, endowed by the tri-spiral donor and spiro-acceptor units, can be regarded beneficial for attaining high Θ‖ values, leading to the improved ηout of device and thereby enhancing the EQE of the device over 30%. To the best of our knowledge, the Θ‖ value of ∼93% is the highest among the spiro,16,18,21,24 bi-spiral,24,50 or tri-spiral acridine donor-based emitters (Θ‖ = 88–90%).15,26 The high device efficiency of D4 was further elucidated by the optical simulations. Using the PLQY and Θ‖ of the emitter 2 and the OLED structure, the contour map of the theoretically achievable EQEmax values was obtained as illustrated in Fig. 2f. The resultant theoretical EQEmax was found to be 35.9% for the D4 device, accounting for the observed high efficiency of D4.
Conclusions
We have demonstrated that linear-shaped D–A-type compounds, O-tsAC-BAsBP (1) and S-tsAC-BAsBP (2), which consisted of rigid tri-spiral acridine donor and spiro-fluorenyl-B-heterotriangulene acceptor units, can act as highly efficient deep-blue TADF emitters in OLEDs. Both the emitters doped into host films exhibited deep-blue emissions with outstanding TADF characteristics, such as a high PLQY of ∼100%, a small ΔEST of less than 50 meV, and a short τd of ∼2 μs. The RISC process was found to be accelerated by effective SOC between the 1CT (S1) and 3LE (T2) excited states, resulting in a rate constant of ∼106 s−1. Above all, the emitters displayed a remarkably high horizontal dipole orientation ratio (Θ‖) of ∼93%. Thanks to their high PLQYs, Θ‖, and molecular rigidity, the optimized TADF-OLEDs incorporating emitters 1 and 2 achieved narrow deep-blue EL emissions with peak wavelengths of 465–469 nm, with EQEmax values as high as 27.4% (1) and 31.5% (2), respectively. The findings of this study are promising for the development of TADF emitters with a high horizontal dipole orientation, which can ultimately enhance the efficiency of OLEDs.
Conflicts of interest
There are no conflicts to declare.
Acknowledgements
This work was supported by the Basic Science Research Program funded by the Ministry of Science and ICT (MSIT) (NRF-2019R1A2C1084952 and NRF-2021R1A4A1027480 for M.H.L) and the Ministry of Education (NRF-2021R1A6A1A03038858) through the National Research Foundation of Korea (NRF). S. Yoo acknowledges the support from the Technology Innovation Program (20020408, Development of direct analytic methods for exciton dynamics in OLEDs and lifetime-enhancing technologies based thereon) funded by the Ministry of Trade, Industry & Energy (MOTIE, Korea) through the Korea Evaluation Institute of Industrial Technology (KEIT).
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Footnotes |
† Electronic supplementary information (ESI) available: Electronic Supplementary Information is available from the Royal Society of Chemistry or from the author. General information about the experimental, photophysical data, computational details, and electroluminescence results. See DOI: https://doi.org/10.1039/d3qm00653k |
‡ These authors contributed equally to this work. |
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