Nanotechnology Now - Press Release: Silicon nanoparticles instead of expensive semiconductors: Within an international collaboration, physicists of the Moscow State University replace expensive semiconductors with affordable silicon nanoparticles for display production

Home > Press > Silicon nanoparticles instead of expensive semiconductors: Within an international collaboration, physicists of the Moscow State University replace expensive semiconductors with affordable silicon nanoparticles for display production

The photoluminescence of silicon nanoparticles.

Source: Macmillan Publishers Limited

Abstract:
Lomonosov MSU physicists found a way to "force" silicon nanoparticles to glow in response to radiation strongly enough to replace expensive semiconductors used in display business. According to Maxim Shcherbakov, researcher at the Department of Quantum Electronics of the Moscow State University and one of the authors of the study, the developed method considerably enhances the efficiency of nanoparticle photoluminescence.

Silicon nanoparticles instead of expensive semiconductors: Within an international collaboration, physicists of the Moscow State University replace expensive semiconductors with affordable silicon nanoparticles for display production

Moscow, Russia | Posted on September 9th, 2016

The key term in the problem is photoluminescence -- the process, when materials irradiated by visible or ultraviolet radiation start to respond with their own light, but in a different spectral range. In the study, the material glows red.

In some of the modern displays, semiconductor nanoparticles, or the so-called quantum dots, are used. In quantum dots, electrons behave completely unlike those in the bulk semiconductor, and it has long been known that quantum dots possess excellent luminescent properties. Today, for the purposes of quantum-dot based displays various semiconductors are used, i.e. CdSe, etc. These materials are toxic and expensive, and, therefore, researchers have long been scrutinizing the far cheaper and much more studied silicon. It is also suitable for such use in all respects except one -- silicon nanoparticles vaguely respond to radiation, which is not appealing for optoelectronic industry.

Scientists all over the world were seeking to solve this problem since the beginning of the 1990's, but until now no significant success has been achieved in this direction. The breakthrough idea about how to "tame" silicon originated in Sweden, at the Royal Institute of Technology, Kista. A post-doctoral researcher Sergey Dyakov (a graduate of the MSU Faculty of Physics and the first author of the paper) suggested placing an array of silicon nanoparticles in a matrix with a non-homogeneous dielectric medium and cover it with golden nanostripes.

'The heterogeneity of the environment, as has been previously shown in other experiments, allows to increase the photoluminescence of silicon by several orders of magnitude due to the so-called quantum confinement,' says Maxim Shcherbakov. 'However, the efficiency of the light interaction with nanocrystals still remains insufficient. It has been proposed to enhance the efficiency by using plasmons (quasiparticle appearing from fluctuations of the electron gas in metals -- ed). Plasmon lattice formed by golden nanostripes allow to "hold" light on the nanoscale, and allow a more effective interaction with nanoparticles located nearby, bringing its luminescence to an increase.'

The MSU experiments with samples of "gold-plated" matrix with silicon nanoparticles made in Sweden brilliantly confirmed the theoretical predictions - the UV irradiated silicon for the first time shone bright enough to be used it in practice.

The first author of the paper Sergey Dyakov will present the findings on The 10th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics (September 17-22, Crete). The work was also published in the Physical Review B ("Optical properties of silicon nanocrystals covered by periodic array of gold nanowires").

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Contacts:
Vladimir Koryagin

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