Research

Our Research Directions

Sector 01

Quantum Simulation

Simulation Platform

Active

Utilizing ultra-cold atoms and Rydberg states to simulate complex many-body quantum dynamics and magnetism. Our platform enables the study of quantum phase transitions, entanglement dynamics, and non-equilibrium phenomena in controlled atomic environments.

Sector 02

Atom-Based Sensing

Quantum Sensing

Active

Engineering next-generation electric field sensors using Rydberg-atom-based microwave detection. These sensors offer unprecedented sensitivity for electromagnetic field measurements, with applications in communications, imaging, and fundamental physics.

Methodology

Core Techniques

Optical Tweezers

Single-atom trapping and rearrangement using focused laser beams for programmable quantum matter.

Rydberg Excitation

Laser excitation to high-lying Rydberg states for strong, tunable interactions and quantum sensing.

Cavity QED

Strong coupling between atoms and optical cavities for quantum non-demolition measurements.

Laser Cooling

Doppler and sub-Doppler cooling techniques to reach microkelvin temperatures for quantum degeneracy.

EIT Spectroscopy

Electromagnetically induced transparency for precision measurement of Rydberg states and electric fields.

Time Crystals

Observation and characterization of time-translation symmetry breaking in driven quantum systems.