Zusammenfassung der Projektergebnisse

The goal of project was to further develop extreme UV (XUV) coherence tomography (XCT) in several directions and to apply it to achieve cross-sectional nano-scale imaging of samples relevant for nanotechnology and biology. An essential part of the project was the collaboration with colleagues from the Military University of Technology, Warsaw, Poland. The research was following two main threads, namely XUV imaging in the so-called silicon transmission window (30 to 100 eV) and in the water window (280 to 530 eV), respectively particular relevant for nanotechnology and biology. The main results of the project are as follows: 1. Based on succeeding to reconstruct amplitude and phase of the XUV radiation reflected from the sample, it became possible to determine the field reflectivity (i.e. amplitude and phase) of structures buried beneath the surface of the sample. It is even possible to determine properties such as thickness and roughness using a model-based approach. 2. The phase reconstruction is applied and helps in the investigation of 2D material (here graphene) embedded in bulk samples. We successfully characterized mono-, bi-, and tri-layers and verified our results by comparing with conventional imaging techniques. 3. We measured the near-edge X-ray absorption fine structure of the aluminum L2/3 absorption edge in α-Al2 O3 and compared our results to synchrotron data. The agreement proved to be almost perfect with the remarkable side aspect that the XCT measurement was considerably faster than the synchrotron measurement due to the broadband scheme of XCT. 4. A correlative water-window XUV / visible fluorescence microscope has been designed and built. To our knowledge, it is the first lab-based instrument of this type that incorporates both modalities in the same vacuum recipient, i.e. allows to switch both modalities without moving the sample. First correlative images proving an XUV resolution below 100 nm were obtained. Besides the above outlined scientific results, a number of technical advances were made. Particularly noteworthy is the development and commissioning of a versatile high-resolution XUV spectrometer. The project has also been instrumental in encouraging two graduate students to found a company for developing and marketing XUV instrumentation and services. In addition, we expect that XCT has a considerable potential for applications in both science and industry.

Projektbezogene Publikationen (Auswahl)

• A high resolution extreme ultraviolet spectrometer system optimized for harmonic spectroscopy and XUV beam analysis, Review of Scientific Instruments 90, 023108 (2019)
  M. Wünsche, S. Fuchs, T. Weber, J. Nathanael, J. J. Abel, J. Reinhard, F. Wiesner, U. Hübner, S. J. Skruszewicz, G. G. Paulus, C. Rödel
  (Siehe online unter https://doi.org/10.1063/1.5054116)
• Laboratory setup for extreme ultraviolet coherence tomography driven by a high-harmonic source, Review of Scientific Instruments 90, 113702 (2019)
  J. Nathanael, M. Wünsche, S. Fuchs, T. Weber, J. J. Abel, J. Reinhard, F. Wiesner, U. Hübner, S. J. Skruszewicz, G. G. Paulus, C. Rödel
  (Siehe online unter https://doi.org/10.1063/1.5102129)
• Coherence tomography with broad bandwidth extreme ultraviolet and soft X-ray radiation, Applied Physics B 127, 55 (2021)
  S. J. Skruszewicz, S. Fuchs, J. J. Abel, J. Nathanael, J. Reinhard, C. Rödel, F. Wiesner, M. Wünsche, P. Wachulak, A. Bartnik, K. Janulewicz, H. Fiedorowicz, G. G. Paulus
  (Siehe online unter https://doi.org/10.1007/s00340-021-07586-w)
• Material-specific imaging of nanolayers using extreme ultraviolet coherence tomography, Optica 8, 230 (2021)
  F. Wiesner, M. Wünsche, J. Reinhard, J. J. Abel, J. Nathanael, S. J. Skruszewicz, C. Rödel, S. Yulin, A. Gawlik, G. Schmidl, U. Hübner, J. Plentz, G. G. Paulus
  (Siehe online unter https://doi.org/10.1364/OPTICA.412036)
• Absolute EUV reflectivity measurements using a broadband high-harmonic source and an in situ single exposure reference scheme, Optics Express 30, 35671 (2022)
  J. J. Abel, F. Wiesner, J. Nathanael, J. Reinhard, M. Wünsche, G. Schmidl, A. Gawlik, U. Hübner, J. Plentz, C. Rödel, G. G. Paulus, S. Fuchs
  (Siehe online unter https://doi.org/10.1364/oe.463216)
• Characterization of encapsulated graphene layers using extreme ultraviolet coherence tomography, Optics Express 30, 32267 (2022)
  F. Wiesner, S. Skruszewicz, C. Rödel, J. J. Abel, J. Reinhard, M. Wünsche, J. Nathanael, M. Grünewald, U. Hübner, G. G. Paulus, S. Fuchs
  (Siehe online unter https://doi.org/10.1364/oe.464378)