We develop world’s first scanning millimeter wave impedance microscopy (MMIM), and next-generation quantum probes (RFlexiScope) to map nanoscale conductivity, magnetism, and excitations. These tools allow us to see how superconductivity, correlated states, and topological phases emerge at the nanoscale.

Two-dimensional semiconductors and moiré heterostructures offer new ways to engineer excitons and light–matter interactions. By combining microwave with optical spectroscopy, we aim to harness those excitations for quantum science.

Topological order represents a new class of quantum matter that cannot be described by traditional symmetry-breaking. Instead, it emerges through global patterns of quantum entanglement, giving rise to exotic excitations such as anyons that carry fractional charge or statistics. Our lab seeks to probe these states, uncover how topological states form, evolve, and interact, to lay the groundwork for potential applications in fault-tolerant quantum computation and robust quantum devices.