Van den Hooven: “A former PhD student in our group, Guido de Haan, showed that a grating on the metal surface induces a plasmonic resonance that is very sensitive to changes in the reflection signal caused by laser-induced acoustic waves from a sample.” (see news item) The wavelength of the light and its angle of incidence are important, but so are the material properties and shape of the metal. When light hits a metal-semiconductor interface, it can transfer part of its energy to electrons that start to oscillate in the metal, forming a surface plasmon resonance, but only under very specific conditions. Van den Hooven and his colleagues use a layer of gold to induce a phenomenon called plasmonic resonance. That is why our group sought for ways to enhance them and thus improve our previous work.” “Unfortunately these signals are very weak. A second light pulse can diffract off the acoustic-wave copy of the grating, when the wave reaches the surface”, PhD student Thomas van den Hooven explains. “The sound waves coming from the surface, reflect off the hidden grating and copy their shape in the process. In 2020 group leader Paul Planken and his colleagues showed that they could detect a hidden nanostructure using very high frequency sound waves induced by light. The Light Matter Interaction group at ARCNL develops techniques to overcome this problem. Detecting these alignment gratings is not always straightforward, because they get buried under many layers of material, some of which can be opaque to light. To make sure consecutive layers are aligned accurately, wafers contain grating lines that act as markers. Nanolithography machines print several layers of nano-sized structures on a wafer to produce state-of-the art computer chips and components. The researchers have published their findings in Photoacoustics on May 9th 2023. The relative enhancement of the diffraction signal is even two to three times larger than the enhancement of the reflection signal. This amplifies reflection and diffraction changes caused by laser-induced acoustic waves in the sample. With a gold-covered segmented grating they can induce a so-called plasmonic resonance. ARCNL researchers Thomas van den Hooven and Paul Planken have found a way to enhance acoustic-wave-induced diffraction changes from a sample similar to those used for wafer alignment in nanolithography.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |