8 research outputs found
The Effect of Acceptor Structure on Emission Color Tuning in Organic Semiconductors with DâÏâAâÏâD Structures
A series of novel donor–acceptor D–π–A–π–D compounds were synthesized and characterized in order to determine the influence of different acceptor units on their properties. The introduction of acceptor moieties had a direct impact on the HOMO and LUMO energy levels. Fluorescence spectra of compounds can be changed by the choice of an appropriate acceptor and were shifted from the green to the near-infrared part of spectra. Due to observed concentration induced emission quenching, the green exciplex type host was used to evaluate the potential of synthesized molecules as emitters in organic light emitting diodes (OLEDs)
Effect of TADF Assistance on Performance Enhancement in Solution Processed Green Phosphorescent OLEDs
Many methods have been proposed to increase the efficiency of organic electroluminescent materials applied as an emissive layer in organic light emitting diodes (OLEDs). Herein, we demonstrate enhancement of electroluminescence efficiency and operational stability solution processed OLEDs by employing thermally activated delayed fluorescence (TADF) molecules as assistant dopants in host-guest systems. The TADF assistant dopant (SpiroACâTRZ) is used to facilitate efficient energy transfer from host material poly(Nâvinylcarbazole) (PVK) to a phosphorescent Ir(III) emitter. We present the analysis of energy transfer and charge trappingâtwo main processes playing a crucial role in light generation in hostâguest structure OLEDs. The investigation of photo-, electro- and thermoluminescence for the double-dopant layer revealed that assistant dopant does not only harvest and transfer the electrically generated excitons to phosphorescent emitter molecules but also creates exciplexes. The triplet states of formed PVK:SpiroACâTRZ exciplexes are involved in the transport process of charge carriers and promote longârange exciton energy transfer to the emitter, improving the efficiency of electroluminescence in a single emissive layer OLED, resulting in devices with luminance exceeding 18 000 cd/m2 with a luminous efficiency of 23 cd/A and external quantum efficiency (EQE) of 7.4%
Electronic Structure of Exciplexes and the Role of Local Triplet States on Efficiency of Thermally Activated Delayed Fluorescence
In this work, we present an investigation of the electronic states in a series of thermally activated delayed fluorescence (TADF) exciplexes formed with the popular electron-transport compound TpBpTa and hole-transporting TCTA, TAPC, TPD10, TPD, and NPB. We rationalize the photophysical behavior of exciplexes by using computational methods and demonstrate that the reason for the commonly observed temporal red shift in the time-resolved spectra is related to the distribution of molecular conformations, thus CT energy, in film. We also use spectrally resolved thermoluminescence (SRTL) measurements to give insight into the trapping phenomena in exciplex blends. The results demonstrate that trapped charge carriers in the majority of studied exciplexes recombine through the luminescent intermolecular CT state. In addition, we report OLED devices using the said exciplexes in the emissive layer. The best performance is obtained with the TCTA:TpBpTa and TAPC:TpBpTa exciplexes showing maximum external quantum efficiencies (EQEs) of 8.8% and 7.2%, respectively
Nine-ring angular fused biscarbazoloanthracene displaying a solid state based excimer emission suitable for OLED application
A new biscarbazoloanthracene consisting of nine fused aromatic rings, including two pyrrole units, has been obtained in a straightforward and convergent synthesis. Computational chemistry and conformational analysis revealed that the semiconductorâs molecule is not planar, the two carbazole moieties being helical twisted from the plane of the anthracene unit. Photophysical and electrochemical measurements showed that this angular fused heteroacene has a low lying HOMO energy level with a wide band gap despite its extended p-conjugated molecular framework. Based on its relatively low-lying HOMO level, the semiconductor promises a high environmental stability in comparison to other related linear fused acenes and heteroacenes. The biscarbazoloanthracene has been applied as the light emitting layer in a white light emitting diode (WOLED). It is proposed that the white OLED feature is due to dual light emission properties from the active semiconductor layer being based on both the molecular luminescence of the small molecule and a discrete excimer emission made possible by suitable aggregates in the solid state. Noteworthy, this is the first reported example of such a behavior observed in a small molecule heteroacene rather than an oligomer or a polymer
Structural, Spectroscopic, Electrochemical, and Electroluminescent Properties of Tetraalkoxydinaphthophenazines: New Solution-Processable Nonlinear Azaacenes
A series
of solution-processable tetraalkoxy-substituted dinaphthoÂ[2,3-<i>a</i>:2âČ,3âČ-<i>h</i>]Âphenazines were
synthesized by reductive functionalization of indanthrone (6,15-dihydrodinaphthoÂ[2,3-<i>a</i>:2âČ,3âČ-<i>h</i>]Âphenazine-5,9,14,18-tetraone),
an old intractable dye. The melting point of these new compounds was
found to decrease from 204 °C to 98 °C upon extension of
the number of carbons from 4 to 12 in the alkoxy substituent. All
derivatives show a strong tendency to self-organize in 2D as evidenced
by STM investigations of monolayers deposited on HOPG. The 2D structure
is less dense and shows different alkoxy group interdigitation pattern
as compared to the 3D structure determined from the X-ray diffraction
data obtained for the corresponding single crystals. Electrochemical,
absorption, and emission properties of tetraalkoxy-substituted dinaphthoÂ[2,3-<i>a</i>:2âČ,3âČ-<i>h</i>]Âphenazines, studied
in solution, are essentially independent of the length of the alkoxy
substituents. All derivatives exhibit high photoluminescence quantum
yield, approaching 60%. When molecularly dispersed in a solid matrix
consisting of polyÂ(9-vinylcarbazole) (PVK) (60 wt %) and (2-<i>tert</i>-butylphenyl-5-biphenyl-1,3,4-oxadiazole) (PBD) (40
wt %) (so-called âguest/host configurationâ), they show
green electroluminescence due to an effective energy transfer from
the matrix to the luminophore. The best light-emitting diodes were
obtained for the butoxy derivative showing a luminance approaching
1500 cd/m<sup>2</sup> and a luminous efficiency over 0.8 cd/A