Research projects in 2DPHYS
We have many ongoing research projects, some of which will be looking for people in 2025. Check them out below.
| Funding agency and type | Name | Aim | PI's |
| ERC Synergy | METRIQS - Metamaterial Interfaces for Quantum Electronics | The aim of the METRIQS proposal is to develop a new class of hybrid materials by combining freestanding transition metal oxides and two-dimensional materials into precisely engineered moiré heterostructures, in order to explore and control emergent electronic, magnetic, and structural phenomena at their interfaces. Collaborators: CSIC (Mar Garcia Hernandez and UCM (Jacobo Santamaria) | Peter Bøggild and Mads Brandbyge |
| NNF Synergy Grant |
BioNWire - Self-Assembly of a Bio-Nano-Wire Device on a Microelectronic Chip
for Single-Molecule Biosensing and Conductance Analysis
|
Create a scalable nanotechnology platform where DNA self-assembly is used to position conductive nanowires and biomolecules with nanometer precision on microchips, enabling ultrasensitive single-molecule biosensors and advancing our ability to electrically probe individual biomolecules. Collaborators: Århus University (Kurt Gotthelf) and Harvard (William Shih) | Peter Bøggild and Mads Brandbyge |
| NNF Project Grant | MOTIFS - Moiré Oxide-graphene Twisted InterFaces for Sensing | Develop a new class of biosensors by stacking freestanding oxide membranes with graphene at controlled twist angles to create moiré superstructures that serve as tunable templates for molecular binding, enabling highly sensitive, all-electrical, label-free detection of biomolecules. Collaborators: DTU Energy (Nini Pryds) | Mads Brandbyge and Peter Bøggild |
| NNF Challenge Program | BIOMAG - Ultra-sensitive Bio-Magnetometers with Macro to Nano Resolution | The aim of the BIO-MAG project is to develop ultra-sensitive magnetic sensors based on engineered two-dimensional materials that can operate at room temperature and provide high spatial and temporal resolution, enabling non-invasive, real-time mapping of neuronal activity from single cells to entire brain networks. Collaborators: DTU Energy (Nini Pryds) and DTU Physics sections QPIT and CAMD. | Tim Booth and Peter Bøggild |