Perovskite solar cell

Perovskite diodes enable bidirectional optical signal transmission between two identical devices

LayTec’s new InspiRe in-situ tool used for monitoring perovskite formation

Germany-based in-situ metrology system maker LayTec has announced that its new InspiRe system applies high-speed in-situ reflectance measurements for monitoring perovskite thin-film formations during spin-coating and subsequent annealing. In collaboration with professor Norbert Nickel’s group at HZB, LayTec designed the InspiRe in-situ metrology system, which was applied to monitor both spin-coating and annealing. Gathering data at a time resolution on the millisecond scale allows resolving of the kinetics and phase formations during film formation. While spin-coating, the absorption behavior and the thinning of precursor solution is monitored. The absorption edge (i.e. band gap) of the deposited perovskite film is derived directly during annealing. Spectral changes during annealing indicate ‘over-annealing’ after the desired bandgap has been achieved. This methodology allows the systematic study of film formation during two crucial process steps…

Researchers at Linkæžšping University, in collaboration with colleagues in China, have developed a tiny unit that is both an optical transmitter and a receiver. “This is highly significant for the miniaturization of optoelectronic systems,” says LiU professor Feng Gao.

Chunxiong Bao, postdoc at Linkæžšping University, types in a sentence on a computer screen, and the same sentence immediately appears on the neighboring screen, optically transferred from one diode to another. The diode is made from perovskite.

Perovskites have the useful property of both detecting and emitting light. The team has now developed a diode that can be directed in two directions: it can receive optical signals and it can just as easily transmit them. This means that text and photographs can be wirelessly transmitted from one unit to the other and back again, using two identical units. And so rapidly that we experience it as happening in real time.

In the autumn of 2018, Chunxiong Bao discovered the most suitable perovskite to build a photodetector showing higher performance and longer lifetime, and described this in an article. The development of light-emitting diodes from perovskites has also made rapid progress. Weidong Xu, postdoc at Linkæžšping University, developed a perovskite light-emitting diode with an efficiency of 21% last year, which is among the best in the world. What the scientists have now achieved is the development of a perovskite that comprises a light-emitting diode and that at the same time is an excellent photodetector.

All optical communication requires rapid and reliable photodetectors – devices that capture light and convert it into an electrical signal. Current optical communication systems use photodetectors made from materials such as silicon and indium gallium arsenide. These are, however, expensive and they cannot be used in applications that require low weight, flexibility, or large surfaces.

“In order to demonstrate the potential of our diode with double function, we have built a monolithic sensor that detects heart beats in real time, and an optical, bidirectional communication system,” says Chunxiong Bao, researcher in the Division of Biomolecular and Organic Electronics.

This tiny unit that can both receive and transmit optical signals provides a unique opportunity to simplify and shrink the functionality of the current optical systems, in particular given that it can also be integrated with traditional electronic circuits.

“We have managed to integrate optical signal transmission and reception into one circuit, something that makes it possible to transmit optical signals in both directions between two identical circuits. This is valuable in the field of miniaturized and integrated optoelectronics,” says Feng Gao, professor and head of research at the Division of Biomolecular and Organic Electronics.

Nature ElectronicsSciencedailyPerovskite applicationsSensorsTechnical / research
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Arc Melting in Glovebox

Details Quantity: 5 – 20 g per charge Temperature: up to 3500°C, depending on quantity Generator: outside of glovebox Connection: 230 V / 50/60 Hz (different voltage on request) Crucible plate: standard crucible plate or customized crucible plates Options: Special cold crucible (suction casting), Vacuum pump, Turbomulecular pumping system HVT52/G, High vacuum gauge, Water flow control, Recirculating chiller Description For oxygen-sensitive samples to be handled and alloyed in inert gas atmosphere • Melting chamber and movable electrode inside of glovebox • Generator, vacuum pump and operating panel at the outside • Designed for melting samples of approx. 5-20 g up to 3500°C, sufficient for most laboratory purposes • Small melting chamber ensures fast evacuation and low gas consumption • Freely movable, water-cooled electrode • Dismountable, water-cooled copper crucible plate with…


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