Projects
Organic spintronics based on intrinsically paramagnetic polymers. University of Antwerp
Magnetoacoustic wave devices for ultralow power spintronics KU Leuven
Among the technologies that may lead to a paradigm shift with respect to current CMOS technology, spintronics presents several advantages to achieve area and power reduction. The possibility to perform multifrequency processing and the non-volatility of the magnetic materials could provide new functionalities to circuit designers for various applications. However, a major limitation for the realization of spintronic devices is the lack of a ...
Spintronics with Transition metal Dichalcogenides. University of Antwerp
Superconductor/ferromagnet hybrids, and spintronics in hybrid materials. University of Antwerp
Magnetoelectric compounds for spintronic applications KU Leuven
Spintronica-apparaten hebben potentieel in toekomstige toepassingen met ultralaag vermogen. Momenteel heeft de besturing van magneten door spin-transfer of spin-orbit-koppels een hoog energieverbruik. Multiferroïsche magneto-elektrische materialen en laminaatcomposieten met een laag piëzo-elektrisch materiaal en een laag magnetostrictief materiaal zouden transducers met lage energie mogelijk kunnen maken voor de besturing van magneten. Het ...
A heterostructure spintronic device based on topological insulators and low-dimensional magnets KU Leuven
Two-dimensional materials and van der Waals heterostructures for next generation spintronic applications KU Leuven
Finite-Difference Time-Domain (FDTD) Modelling Algorithms for Transition Metal Dichalcogenides (TMDCs) in Nanoelectronic, Spintronic and Valleytronic Devices Ghent University
Two-dimensional (2D) materials attract a lot of interest for the development of novel nanoelectronic devices, owing to their monolayer nature, which allows for integration in planar devices. The most well-known example of such a material is graphene. Another class of 2D materials are transition metal dichalcogenides (TMDCs), which exhibit similar properties as graphene (superior carrier mobility, high cut-off frequency, etc), but are still ...
Electrically controlled ferromagnitism in two-dimensional semiconductors. KU Leuven
The DIMAG project is dedicated to establishing a new type of 2D magnetic materials, which not only exhibits a fundamentally new type of ferromagnetic behavior, but also has optimal characteristics for spintronics applications. This 3-years project, brings together five academic laboratories: (1) the Laboratory for Semiconductor Physics (KU Leuven, Belgium), (2) the Institute for Nuclear and Radiation Physics (KU Leuven, Belgium), (3) the ...