Abstract
Nanometer-sized structures, surfaces and sub-surface phenomena have played an enormous role in science and
technological applications and represent a driving-force of current interdisciplinary science. Recent developments
include the atomic-scale characterization of nanoparticles, molecular reactions at surfaces, magnetism at
the atomic scale, photoelectric characterization of nanostructures as well as two-dimensional solids. Research
and development of smart nanostructured materials governed by their surface properties is a rapidly growing
field. The main challenge is to develop an accurate and robust electronic structure description. The density of
surface-related trap states is analyzed by transient UV photoconductivity and temperature-dependent admittance
spectroscopy. An advanced application of thin films on shaped substrates is the deposition of catalytic layers on
hollow glass microspheres for hydrogen storage controlled exothermal hydrolytic release. Surface properties of
thin films including dissolution and corrosion, fouling resistance, and hydrophilicity/hydrophobicity are explored to improve materials response in biological environments and medicine. Trends in surface biofunctionalization
routes based on vacuum techniques, together with advances in surface analysis of biomaterials,
are discussed. Pioneering advances in the application of X-ray nanodiffraction of thin film cross-sections for
characterizing nanostructure and local strain including in-situ experiments during nanoindentation are described.
Precise measurements and control of plasma properties are important for fundamental investigations
and the development of next generation plasma-based technologies. Critical control parameters are the flux and
energy distribution of incident ions at reactive surfaces; it is also crucial to control the dynamics of electrons
initiating non-equilibrium chemical reactions. The most promising approach involves the exploitation of complementary
advantages in direct measurements combined with specifically designed numerical simulations.
Exciting new developments in vacuum science and technology have focused on forward-looking and next
generation standards and sensors that take advantage of photonics based measurements. These measurements
are inherently fast, frequency based, easily transferrable to sensors based on photonics and hold promise of being
disruptive and transformative. Realization of Pascal, the SI unit for pressure, a cold-atom trap based ultra-high
and extreme high vacuum (UHV and XHV) standard, dynamic pressure measurements and a photonic based
thermometer are three key examples that are presented.
Originalsprache | Englisch |
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Seiten (von - bis) | 120-160 |
Seitenumfang | 41 |
Fachzeitschrift | Thin Solid Films |
Volume | 660 |
DOIs | |
Publikationsstatus | Veröffentlicht - 2018 |
Research Field
- Efficiency in Industrial Processes and Systems