Advanced Nanofabrication
Advanced nanofabrication enables the creation of precise, complex nanostructures for photonic, electronic, and quantum devices. By integrating novel materials and architectures, this research supports reconfigurable metamaterials, MEMS platforms, and quantum photonic systems, advancing applications in nonlinear optics, quantum information, and adaptive photonics.
Research in advanced nanofabrication focuses on developing innovative techniques to realize complex, high-precision nanostructures for photonic, electronic, and quantum devices. By combining state-of-the-art lithography, etching, and material processing methods, this work enables the fabrication of metamaterials, quantum material heterostructures, MEMS-integrated platforms, and reconfigurable nanophotonic devices with nanoscale control. The aim is to push the limits of device functionality, integrating novel materials and architectures to support emerging applications in nonlinear optics, quantum information, and adaptive photonics. Advanced nanofabrication also provides a versatile platform for prototyping and exploring fundamental light–matter interactions at the nanoscale.
Published Works
An adaptive moiré sensor for spectro-polarimetric hyperimaging
A Van der Waals Moiré Bilayer Photonic Crystal Cavity
Fabrication methodology for GaN-based twisted bilayer photonic crystal lasers
On-chip multi-degree-of-freedom control of two-dimensional materials
GaN Magic Angle Laser in a Merged Moiré Photonic