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Plasma patterning technique forms new optical metasurfaces

Researchers from the University of Southampton have demonstrated a new patterning technology that can create high-quality nanostructured surfaces for infrared thermal control coatings and nonlinear optics.

The research was carried out through a close collaboration between physicists and Sustainable Electronic Technologies experts in Electronics and Computer Science (ECS).

Metasurfaces are man-made structures designed to control light and other forms of radiation using very small elements, typically with sub-micrometer dimensions.

Conventional methods of producing the advanced material coatings in specialist cleanroom facilities such as the Southampton Nanofabrication Centre etch patterns into materials or deposit separated structures on the surface by a process called lift-off lithography. However, the resulting surface topography is often undesirable and can strongly limit the device performance when embedded into a stack of many independent layers.

In their study, the researchers explored a completely new technology that locally and selectively modulates optical properties without changing the flatness of the material surface. The research team based their new technique on the discovery that an oxygen plasma can greatly reduce the electron concentration of certain metal oxides, which hold unique properties for integrated circuits, solar cells, chemical sensing and catalysis.

The plasma patterning technique has been demonstrated by fabricating two novel devices, a planar metasurface-based optical solar reflector for satellite radiant cooling and a multiband metasurface with different operation ranges.

The Southampton team, led by Physics and Astronomy's Professor Otto Muskens and ECS's Professor Kees De Groot, have published the research in Advanced Materials.

Dr Kai Sun,lead author, says: “Plasma patterning provides a completely new route to form electrical and optical devices with structures beyond existing manufacturing limitations. Here, we have shown for the first time that a planar metasurface, based on aluminum-doped zinc oxide, can be achieved with an optical metasurface function but physically flat.

The metasurface devices in this work are only a start of this new technique’s applications and its full potential impact is still to be seen.”

Transparent conductive oxides such as aluminium-doped zinc oxide (Al:ZnO) have a high electron density, making it dielectric in visible range but metallic in infrared (IR) range. This electron density of Al:ZnO is critical for its material electrical and optical properties. To achieve an optical property contrast, which is required for optical metasurface formations, parts of the Al:ZnO film need to be removed, leaving a non-planar structure.

The study found that oxygen plasma can reduce Al:ZnO electron density by up to five orders of magnitude. This led the team to propose the new fabrication technique that forms a metasurface by selectively modulating the electron density using oxygen plasma, made possible by accurate location control through a lithography definition.

The fabricated device achieves its metasurface function for its optical property contrast but maintains a planar topological surface profile. This metasurface is highly desirable for its compatibility with any added functional layers.

Southampton scientists have applied to file the plasma patterning technique as a UK patent. Research was funded by the Dstl MultiMeta project, which has currently entered its second phase of development.

Notes to editors

1.) Dr Kai Sun, from the University of Southampton and lead researcher of the study, is available for interview.

2.) The report titled ‘Embedded Metal Oxide Plasmonics Using Local Plasma Oxidation of AZO for Planar Metasurfaces’ is available online with an open-access.

3.) The University of Southampton drives original thinking, turns knowledge into action and impact, and creates solutions to the world’s challenges. We are among the top one per cent of institutions globally. Our academics are leaders in their fields, forging links with high-profile international businesses and organisations, and inspiring a 24,000-strong community of exceptional students, from over 135 countries worldwide. Through our high-quality education, the University helps students on a journey of discovery to realise their potential and join our global network of over 200,000 alumni.

Posted by on 10 Jul 2020.