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Author
Bernd Müller

New materials for the computer of the future

Milan Radovic ist wissenschaftlicher Mitarbeiter an der SIS-Beamline (Spectroscopy of Interfaces and Surfaces) der Synchrotron Lichtquelle Schweiz SLS. Er hat in Serbien an der Universität Belgrad studiert, wo er auch seine Forschungslaufbahn in der Abteilung für Atomphysik begonnen hat. Promoviert hat er an der Universität in Neapel. 2009 wurde Radovic eingeladen, eine gemeinsame Stelle an der EPFL Lausanne und am PSI anzutreten. Seit 2013 ist er wissenschaftlicher Mitarbeiter am PSI. (Foto: Paul Scherrer Institut/Mahir Dzambegovic) / Milan Radovic is a staff scientist at the Spectroscopy of Interfaces and Surfaces (SIS) Beam Line, Swiss Light Source. He studied Applied Physics at the University of Belgrade, Serbia, where he also started his research career at the Department of Atomic Physics. In 2009 he obtained his PhD from the University of Naples, Italy. In 2003 he was invited to take up a dual appointment with EPFL Lausanne and PSI, where he has been a staff scientist since 2013. (Photo: Paul Scherrer Institute/Mahir Dzambegovic)
Milan Radovic ist wissenschaftlicher Mitarbeiter an der SIS-Beamline (Spectroscopy of Interfaces and Surfaces) der Synchrotron Lichtquelle Schweiz SLS. Er hat in Serbien an der Universität Belgrad studiert, wo er auch seine Forschungslaufbahn in der Abteilung für Atomphysik begonnen hat. Promoviert hat er an der Universität in Neapel. 2009 wurde Radovic eingeladen, eine gemeinsame Stelle an der EPFL Lausanne und am PSI anzutreten. Seit 2013 ist er wissenschaftlicher Mitarbeiter am PSI. (Foto: Paul Scherrer Institut/Mahir Dzambegovic) / Milan Radovic is a staff scientist at the Spectroscopy of Interfaces and Surfaces (SIS) Beam Line, Swiss Light Source. He studied Applied Physics at the University of Belgrade, Serbia, where he also started his research career at the Department of Atomic Physics. In 2009 he obtained his PhD from the University of Naples, Italy. In 2003 he was invited to take up a dual appointment with EPFL Lausanne and PSI, where he has been a staff scientist since 2013. (Photo: Paul Scherrer Institute/Mahir Dzambegovic)
Milan Radovic und Eduardo Bonini Guedes (rechts) von der Forschungsgruppe Spektroskopie von Quantenmaterialien an der Strahllinie SIS der Synchrotron Lichtquelle Schweiz SLS. (Foto: Paul Scherrer Institut/Mahir Dzambegovic) / Milan Radovic and Eduardo Bonini Guedes from the Spectroscopy of Quantum Materials Group at the SIS beamline of the Swiss Light Source. (Photo: Paul Scherrer Institute/Mahir Dzambegovic)
Milan Radovic und Eduardo Bonini Guedes (rechts) von der Forschungsgruppe Spektroskopie von Quantenmaterialien an der Strahllinie SIS der Synchrotron Lichtquelle Schweiz SLS. (Foto: Paul Scherrer Institut/Mahir Dzambegovic) / Milan Radovic and Eduardo Bonini Guedes from the Spectroscopy of Quantum Materials Group at the SIS beamline of the Swiss Light Source. (Photo: Paul Scherrer Institute/Mahir Dzambegovic)

Novel materials could revolutionise computer technology. Research conducted by scientists at the Paul Scherrer Institute PSI using the Swiss Light Source SLS has reached an important milestone along this path.

Microchips are made from silicon and work on the physical principle of a semiconductor. Nothing has changed here since the first transistor was invented in 1947 in the Bell Labs in America. Ever since, researchers have repeatedly foretold the end of the silicon era – but have always been wrong. Silicon technology is very much alive, and continues to develop at a rapid pace. The IT giant IBM has just announced the first microprocessor whose transistor structures only measure two nanometres, equivalent to 20 adjacent atoms. So what’s next? Even tinier structures? Presumably so – for this decade, at least.

At the same time, new ideas are taking shape in research laboratories regarding a revolutionary technology that could turn everything we think we know about microelectronics on its head. One of the shining lights in this research field is given by Milan Radovic team. Milan Radovic works at the Paul Scherrer Institute and his team just published an article in the journal Communication Physics presenting sensational findings from cutting-edge research into transparent oxides (TOs) that could open up huge prospects for this novel technology.

Innovative microchips

Radovic and his co-authors Muntaser Naamneh and Eduardo Guedes, together with the Bharat Jalan research group from the University of Minnesota, USA, do not work with silicon, but with transition metal oxides (TMOs). These exhibit exotic properties and multifunctional phenomena such as high-temperature superconductivity, colossal magnetoresistance, metal-insulator transition and much more besides. What may initially sound bewildering to a lay person promises enormous advances for the chip technology of the future.

In their latest publication, the researchers focus on barium tin oxide (BaSnO3), a material that combines optical transparency with high electrical conductivity.

Scientists have been trying for some time to elicit semiconductor-like properties from transition metals as well as special transparent oxides such as BaSnO3 and strontium stannate (SrSnO3). Compared with silicon, they offer ground-breaking advantages for optoelectronic elements: these transparent, conductive perovskite oxides, would make it possible to create switching elements with directly linked electrical and optical properties. It may then be conceivable to produce transistors that can be switched with light.

Knowledge of interfaces is critical

All microchips are made from a combination of different substances. To understand their function, it is important to know what happens in the thin adjacent layers, or interfaces, between these materials, because the physical properties of many materials are completely different on the surface compared with their interior. “Exotic phases” can occur at the interfaces of materials – a discovery made by three British physicists who were awarded the Nobel Prize in 2016. The article just published describes significant advances in the understanding of the surface-state electronic properties of BaSnO3.

The researchers used angle-resolved photoemission spectroscopy at the beamline of the Swiss Light Source SLS to “discover the two-dimensional electronic state of BaSnO3 , which opens up new prospects for this class of materials,” stresses Eduardo Guedes.

Optimal facilities for spectroscopy at the SLS

It is no coincidence that these findings were made at PSI: researchers on the PSI campus have access to a laboratory specialising in designing, producing, modifying and thoroughly investigating new materials. In addition, the SLS at PSI offers the very best facilities for screening substances at high spatial and temporal resolution. These sophisticated spectroscopy methods are a speciality of PSI, Switzerland’s foremost research centre. There are only three locations worldwide that simultaneously meet all these requirements. The relevant know-how and advanced research infrastructure are also important prerequisites. “At PSI we explore and combine a knowledge with experimental facilities,” says Radovic. Now the researchers want to find out which other materials exhibit similar properties and could be potential candidates for the optical microchips of the future.

But silicon is far from being an outdated technology, Milan Radovic stresses. It is in fact highly developed and efficient. “However, technology based on transition metal oxides is much more powerful and versatile – its time will come.”


Paul Scherrer Institut
5232 Villigen PSI
Switzerland


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