Organic light-emitting diodes (OLEDs) are used in high-class displays for a number of applications. Despite great progress, it is still challenging to produce stable blue OLEDs with high efficiency and color purity.

In this paper, Prof. Adachi and collaborators are presenting a new OLED showing pure-blue emission with high efficiency and stability. Their optimized device consists of a 2-unit stacked tandem OLED with a hyperfluorescent emitting layer.

This research is not only important because of the high efficiency achieved with the fabricated OLEDs. This is also a proof-of-concept paper where the researchers used a blue/deep-blue and a sky-blue energy donor exhibiting TADF as an assistant dopant to sensitize a pure-blue emitter.

What Fluxim Tools Were Used :

The Setfos Emission module was used to fit angular photoluminescence data and determine the orientation of the dipoles of the TADF emitter.

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In this paper, you can learn a technique for obtaining solution-processed perovskite solar cells with a PCE of over 21%. The described method is suitable for the fabrication of large-area photovoltaics.

Generally, only spin-coating can give high-efficiency perovskite solar cells when the active layer is deposited via solution. However, this technique is not suitable for large-area manufacturing.

The group of Prof. Stefaan De Wolf at the KAUST Solar Center (KSC) demonstrated that by assisting Slot-Die Coating with potassium thiocyanate (KSCN), it is possible to obtain a perovskite film with carrier mobility, lifetime, and diffusion length comparable to single crystals. Slot-die coating is now suitable for the fabrication of large-area solar cells thanks to the proposed protocol, which brings the quality of the deposited perovskites to the level of the other deposition methods.

What Fluxim Tools Were Used :
The devices were put through a thorough characterization process. Several of the reported analyses, such as Transient Photovoltage (TPV), Transient Photocurrent (TPC), and Impedance Spectroscopy, have been performed with our all-in-one characterization tool Paios.

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Perovskite Quantum Dot (QD) Light-Emitting Electrochemical Cells (LECs) are easy to fabricate and could be a low-cost alternative to QD-LEDs.

Profs. Ludvig Edman and JIA WANG at Umeå University fabricated several types of light-emitting devices with a solution deposited perovskite QD emissive layer. They successfully demonstrated that ions are liberated from the PeQD structure during device operation. These ions are mobile and perform electrochemical doping, which makes the device functioning as a LEC even without an external electrolyte.

The best-performing PeQD-LEC delivered a peak luminance of 1090 cd/m2 at 6.8V.

What Fluxim Tools Were Used :
These researchers are simulating their LECs with Setfos. Their results demonstrate how a well-thought optical simulation can predict the behavior of the device before the actual fabrication. The simulation anticipated that by introducing a PVK spacer of a given thickness, the luminance would have increased by 28% with respect to the reference device. The actual experiment showed an improvement of 26%.

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Interpretation of the experimental Photoluminescence (PL) spectrum of a thin-film can be complicated because of several phenomena, such as optical interference and self-absorption. However, getting significant information from the PL spectrum of a molecule/material is fundamental for the advancement of optoelectronics.

In this study, the research team led by Prof. Stefan Meskers at the Eindhoven University of Technology analyzed the alteration of fluorescence spectral lineshape of a given molecule in a thin-film due to several factors, such as the film thickness, incident angle, bandgap, and Stokes shift. The simulation is highlighting conditions under which these factors lead to significant differences between the experimental PL and the intrinsic photoluminescence of the layer under study.

What Fluxim Tools Were Used :

Setfos was used to perform several optical simulations to get insights into both the absorption and emission properties of the films. For example, they found it useful that Setfos accounts for the Purcell effect. This is making Setfos well suited for investigating emission from thin films that form optical microcavities.

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