Electrically-Driven Light Emitting Devices
At the intersection of low-dimensional materials and photonics, we're on a mission to create electrically excited single-photon emitters. Imagine ultra-efficient displays, secure communication, and quantum networks.
Defects in low-dimensional materials
To unlock the potential of low-dimensional materials we aim to comprehensively understand their intrinsic defects and explore methods to intentionally introduce active sites in those materials. Controllable defects are crucial for quantum technologies.
Strongly Correlated Exciton-Magnetization Systems
Investigating materials like CrBr3 and CrI3, we're uncovering the hidden potentials of exciton-magnetization interactions. This research could pave the way for next-gen data storage and quantum computing devices.
Quantum Material Design
Our research is dedicated to the exploration and engineering of novel 2D materials, meticulously designed to exhibit custom-tailored properties. We aim to unravel the rich spectrum of quantum phenomena, including excitonic insulators and superconductors, in the search for next-generation quantum materials.
Exciton Transport and Dynamics
In the realm of exciton transport and dynamics, our research explores the intriguing behavior of excitonic populations. Our quest for the microscopic understanding of ultrafast exciton flow may help in the advancements in materials science and photonics, shaping the future of technology.
Magneto-Optical Interactions in Layered Magnets
Our research focuses on investigating the intricate coupling between magnetic orders and excitations such as phonons, magnons, and excitons in layered magnets. We aim to unravel the underlying principles governing magnetic behavior at the nanoscale. This approach not only offers insights into fundamental aspects of magnetism but also holds promise for the development of novel techniques for probing and manipulating magnetic orders.