Projects
Studying the surface properties of organic modified transition metal oxides. University of Antwerp
How electron correlations determine the magnetism and electronic excited states of transition metal oxide clusters KU Leuven
Electron, spin, and atom dynamics in excited transition metal oxide clusters KU Leuven
This research project deals with the study of electron, spin, and atom dynamics of excited transition metal oxide (TMO) clusters. The clusters will be driven out of equilibrium by short laser pulses and the position of the atoms, the electronic and magnetic states, as well as their dynamic interplay will be studied at any point in time thereafter. Hereto, different static and dynamic experimental techniques will be used such as magnetic ...
Silicon CMOS compatible transition metal oxide technology for boosting highly integrated photonic devices with disruptive performance. KU Leuven
The SITOGA project will address for the first time the integration of transition metal oxides (TMO) materials in silicon photonics and CMOS electronics. TMOs have unique electro-optical properties that will offer unprecedented and novel capabilities to the silicon platform. SITOGA will focus on two disruptive TMO materials, barium titanate (BaTiO3) and vanadium oxide (VO2), for developing advanced photonic integrated devices for a wide range ...
Transition metal catalyzed transformation of amides. University of Antwerp
Transition metal catalyzed transformation of amides. University of Antwerp
Chemical synthesis of nano(hetero)structured metal oxides with remarkable physical properties Hasselt University
Understanding Charge Behaviour in a 2D Transition Metal Dichalcogenide MOS System KU Leuven
Advancements in technology are driven by downscaling the channel length and
the thickness of semiconductor that improve performance of a MOSFET. 2D
semiconductors, like transition metal dichalcogenides (MX2), are van der Waals
(vdW) layered structures with one layer approx. 0.7 nm thick and self-terminated
surfaces with no dangling bonds. They offer the promise of ultrathin channels
with high mobility for future ...
Contact to Semiconducting Transition Metal Dichalcogenides KU Leuven
The CMOS industry has made great strides in achieving enormous computational power by downscaling the metal oxide semiconductor field-effect transistors
(MOSFETs). Various technological innovations have been instrumental in achieving this transistor miniaturization. This scaling is reaching its limits
as short channel effects (SCE) significantly degrade the device performance. To enhance the electrostatic control and overcome SCE, ...