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Friday, 04 August, 2017

Red, green, yellow, blue …

Nanocrystalline LEDs

Foto: Foto Ruhrgebiet / fotolia.com

Foto: Foto Ruhrgebiet / fotolia.com

The color of the light emitted by an LED can be tuned by altering the size of their semiconductor crystals. NIM researchers and colleagues from Linz have now found a clever and economical way of doing just that, which lends itself to industrial-scale production.

Unlike our old friend the incandescent lightbulb, light-emitting diodes (or LEDs) produce light of a defined color within the spectral range from the infrared to the ultraviolet. The exact wavelength of the emission is determined by the chemical composition of the semiconductor employed, which is the crucial component of these devices. In the case of some semi-conducting materials, the color can also be tuned by appropriately modifying the size of the crystals of which the light-emitting layer is composed. In crystals with dimensions on the order of a few nanometers, quantum mechanical effects begin to make themselves felt.


LMU researchers in collaboration with colleagues at the University of Linz (Austria) have now developed a method for the production of semi-conducting nanocrystals of defined size based on the cheap mineral oxide known as perovskite. These crystals are extremely stable, which ensures that the LEDs exhibit high color fidelity – an important criterion of quality. Moreover, the resulting semiconductors can be printed on suitable surfaces, and are thus predestined for the manufacture of LEDs for use in displays.


The crucial element in the new method is a thin wafer, only a few nanometers thick, which is patterned like a waffle. The depressions serve as tiny reaction vessels, whose shape and volume ultimately determine the final size of the nanocrystals. “Optimal measurements of the size of the crystals were obtained using a fine beam of high-energy X-radiation at the Deutsche Elektronen-Synchrotron (DESY) in Hamburg“, says LMU researcher Dr. Bert Nickel, member of the Nanosystems Initiative Munich (NIM), a Cluster of Excellence.


Moreover, the wafers are produced by means of an economical electrochemical process, and can be fashioned directly into LEDs. “Our nanostructure oxide layers also prevent contact between the semiconductor crystals and deleterious environmental factors such as free oxygen and water, which would otherwise limit the working lifetime of the LEDs,” as Dr. Martin Kaltenbrunner of the Johannes Kepler University in Linz explains. In the next step, we want to enhance the efficiency of these diodes further, and explore their potential for use in other applications, such as flexible displays.

 

Publication:

Confining Metal-Halide Perovskites in Nanoporous Thin Films. S. Demchyshyn, J. Roemer, H. Groiss, H. Heilbrunner, C. Ulbricht, D. Apaydin, A. Böhm, U. Ruett, F. Bertram, G. Hesser, M. Scharber, N.Serdar Sariciftci, B. Nickel, S. Bauer, E. D. Głowacki, M. Kaltenbrunner. Science Advances online (4 August 2017)

 

Contact:

PD Dr. Bert Nickel (Opens external link in new windowLink)

Ludwig-Maximilians-Universität
Fakultät für Physik
Lehrstuhl für Experimentalphysik (Prof. Rädler)
Geschwister-Scholl-Platz 1
80539 München

Phone: +49-(0)89-2180-1460

Mail: nickel(at)lmu.de

 


Universität Linz:

Assoz. Univ.-Prof. DI Dr. Martin Kaltenbrunner (Opens external link in new windowLink)

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