News

Ursula Keller wins “Swiss Nobel” Marcel Benoist Prize- for pioneering work in ultrafast lasers

Farewell: the NCCR MUST ended - on June 30, 2022

MUST2022 Conference- a great success!

New scientific highlights- by MUST PIs Wörner, Chergui, and Richardson

FELs of Europe prize for Jeremy Rouxel- “Development or innovative use of advanced instrumentation in the field of FELs”

Ruth Signorell wins Doron prizefor pioneering contributions to the field of fundamental aerosol science

New FAST-Fellow Uwe Thumm at ETH- lectures on Topics in Femto- and Attosecond Science

International Day of Women and Girls in Science- SSPh asked female scientists about their experiences

New scientific highlight- by MUST PIs Milne, Standfuss and Schertler

EU XFEL Young Scientist Award for Camila Bacellar,beamline scientist and group leader of the Alvra endstation at SwissFEL

Prizes for Giulia Mancini and Rebeca Gomez CastilloICO/IUPAP Young Scientist Prize in Optics & Ernst Haber 2021

Nobel Prize in Chemistry awarded to RESOLV Member Benjamin List- for the development of asymmetric organocatalysis

Hans Jakob Wörner invited to give the „New Horizons Solvay Lectures” - online, October 5, 12 and 19

Unusual keynote talk at an international scientific conference- Do photons show gender bias?

NCCR MUST at Scientifica 2021- Lightning, organic solar cells, and virtual molecules

Are the laws of optics still valid at the ultimate scaling limits of electronic and optoelectronic devices?

September 22, 2015

The laws of optics describing phenomena such as reflection or refraction are very well tested and established. However, they essentially describe the macroscopic and quasi-static response of matter to the electromagnetic light fields. While this view provides the correct description for most applications, the question arises whether the same optics laws can also be transferred to atomic length and time scales, which represent the ultimate scaling limits of electronic and optoelectronic devices.

In a joint experiment between the Hengsberger/Osterwalder group from the University of Zurich and the Keller group from ETH Zurich, the phase of an infrared field reflected from a metal surface was probed with atomic length and attosecond time resolution. It was found that the phase shift experienced upon reflection from the surface is still correctly described by Fresnel’s reflection law even on these extreme scales. In addition, the experiment showed very efficient screening of the light field at the vacuum-metal interface (Ångström scale screening depth), which confirms that the mathematically abrupt boundaries assumed in optics laws yield the correct macroscopic picture.

The paper was selected by PRL as an Editors' Choice.

Figure 1. Photoemission electron detection geometry using two angles of incidence for the infrared probe field with Θ_IR = 75º (a), and 15° (b). The contour plots show the intensity of the IR transient grating in V²/m² for the xz plane when the pulse maximum impinges on the surface. (c) Fermi surface map of Cu(111) recorded with He I_α (hv = 21.2 eV). The white hexagon indicates the borders of the surface Brillouin zone.

Lucchini, M., Castiglioni, L., Kasmi, L., Kliuiev, P., Ludwig, A., Greif, M., Osterwalder, J., Hengsberger, M., Gallmann, L., and Keller, U. (2015) Light-Matter Interaction at Surfaces in the Spatiotemporal Limit of Macroscopic Models. Phys Rev Lett 115, 137401 (10.1103/PhysRevLett.115.137401)

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