Graphene multilayers: from unconventional superconductors to quantum devices

Event Date:
2024-05-14T13:00:00
2024-05-14T14:00:00
Event Location:
BRIM 311
Speaker:
Étienne Lantagne-Hurtubise – Caltech
Related Upcoming Events:
Intended Audience:
Graduate
Local Contact:

Aditi Adhikari, aditi.adhikari@ubc.ca

Event Information:

Abstract: Crystalline graphene multilayers present a rich playground to explore correlated electronic phenomena in a tunable and ultra-clean setting. For instance, Bernal bilayer graphene and rhombohedral trilayer graphene host multiple symmetry-broken metallic phases at low temperature, as well as unconventional superconductors with different pairing symmetries. The rich phase diagram of these systems can further be tuned through proximity to WSe2, which induces spin-orbit coupling in the graphene layers and leads to a dramatic enhancement of superconductivity that remains poorly understood. I will first discuss the lessons learned from our theoretical exploration of graphene multilayers with induced spin-orbit coupling, focusing on various types of magnetic and inter-valley coherent ground states and their possible connections to superconductivity. I will then outline a recipe to engineer topological superconductivity in graphene multilayers using gate-defined Josephson junctions. Such a platform provides a promising alternative to traditional architectures for Majorana zero-modes due to its purity, gate tunability and atomically thin nature.
 

Speaker Bio: Étienne Lantagne-Hurtubise completed his PhD at UBC, and worked at QMI with Professor Marcel Franz. He is currently a postdoctoral fellow at Caltech.

Add to Calendar 2024-05-14T13:00:00 2024-05-14T14:00:00 Graphene multilayers: from unconventional superconductors to quantum devices Event Information: Abstract: Crystalline graphene multilayers present a rich playground to explore correlated electronic phenomena in a tunable and ultra-clean setting. For instance, Bernal bilayer graphene and rhombohedral trilayer graphene host multiple symmetry-broken metallic phases at low temperature, as well as unconventional superconductors with different pairing symmetries. The rich phase diagram of these systems can further be tuned through proximity to WSe2, which induces spin-orbit coupling in the graphene layers and leads to a dramatic enhancement of superconductivity that remains poorly understood. I will first discuss the lessons learned from our theoretical exploration of graphene multilayers with induced spin-orbit coupling, focusing on various types of magnetic and inter-valley coherent ground states and their possible connections to superconductivity. I will then outline a recipe to engineer topological superconductivity in graphene multilayers using gate-defined Josephson junctions. Such a platform provides a promising alternative to traditional architectures for Majorana zero-modes due to its purity, gate tunability and atomically thin nature.  Speaker Bio: Étienne Lantagne-Hurtubise completed his PhD at UBC, and worked at QMI with Professor Marcel Franz. He is currently a postdoctoral fellow at Caltech. Event Location: BRIM 311