An international group of researchers has developed a new technique that could be used to make more efficient low-cost light-emitting materials that are flexible and can be printed using ink-jet techniques.
An international group of researchers has developed a new technique that could be used to make more efficient low-cost light-emitting materials that are flexible and can be printed using ink-jet techniques.
探花直播researchers, led by the 探花直播 of Cambridge and the Technical 探花直播 of Munich, found that by swapping one out of every 1,000 atoms of one material for another, they were able to triple the luminescence of a new material class of light emitters known as halide perovskites. 听
This 鈥榓tom swapping鈥, or doping, causes the charge carriers to get stuck in a specific part of the material鈥檚 crystal structure, where they recombine and emit light. 探花直播, reported in the Journal of the American Chemical Society, could be useful for low-cost printable and flexible LED lighting, displays for smartphones or cheap lasers.
Many everyday applications now use light-emitting devices (LEDs), such as domestic and commercial lighting, TV screens, smartphones and laptops. 探花直播main advantage of LEDs is they consume far less energy than older technologies.
Ultimately, also the entirety of our worldwide communication via the internet is driven by optical signals from very bright light sources that within optical fibres carry information at the speed of light across the globe.
探花直播team studied a new class of semiconductors called halide perovskites in the form of nanocrystals which measure only about a ten-thousandth of the thickness of a human hair. These 鈥榪uantum dots鈥 are highly luminescent materials: the first high-brilliance QLED TVs incorporating quantum dots recently came onto the market.
探花直播Cambridge researchers, working with Daniel Congreve鈥檚 group at Harvard, who are experts in the fabrication of quantum dots, have now greatly improved the light emission from these nanocrystals. They substituted one out of every one thousand atoms with another 鈥 swapping lead for manganese ions 鈥 and found the luminescence of the quantum dots tripled.
A detailed investigation using laser spectroscopy revealed the origin of this observation. 鈥淲e found that the charges collect together in the regions of the crystals that we doped,鈥 said Sascha Feldmann from Cambridge鈥檚 Cavendish Laboratory, the study鈥檚 first author. 鈥淥nce localised, those energetic charges can meet each other and recombine to emit light in a very efficient manner.鈥
鈥淲e hope this fascinating discovery: that even smallest changes to the chemical composition can greatly enhance the material properties, will pave the way to cheap and ultrabright LED displays and lasers in the near future,鈥 said senior author Felix Deschler, who is jointly affiliated at the Cavendish and the Walter Schottky Institute at the Technical 探花直播 of Munich.
In the future, the researchers hope to identify even more efficient dopants which will help make听these advanced light technologies accessible to every part of the world.
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Reference:
Sascha Feldmann et al. 鈥.鈥, Journal of the American Chemical Society (2021). DOI: 10.1021/jacs.1c01567
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