Recently, superlattice structures in two-dimensional materials, such as Moire patterns, have drawn wide interests. While most of the pre-existing methods create superlattice in passive ways, we proposed an optical method of shining circularly polarized and spatially periodic laser fields
Recent advances in nanophotonic devices have enabled a variety of new technologies, including light-based classical information processing as a promising alternative to electronic signals in future circuits, non-classical light generation, and potential avenues for quantum information sciences. Our group aims to theoretically AND experimentally investigate various quantum properties of light-matter interaction for applications in future optoelectronic devices, quantum information processing, and sensing. Moreover, we explore associated fundamental phenomena, such as many-body physics, that could emerge in such physical systems. Our research is at the interface of quantum optics, condensed matter physics, quantum information sciences, and more recently, machine learning.
October 07, 2020
June 19, 2020
We proposed a new method for enhancing superconductivity in cuprates via melting the collective fluctuations of the competing orders.
February 27, 2020
From 2017, Google has been giving the award called the Google Noisy Intermediate-Scale Quantum (NISQ) award for the academic researchers who collaborated with Google's quantum computing development teams.
September 30, 2019
The mechanism by which thermodynamics sets the direction of time’s arrow has long fascinated scientists.
August 21, 2019
Dissipation induces decoherence in a quantum system which is usually detrimental for quantum state engineering and quantum information processing. However, by engineering dissipation properly, it can actually be a useful resource for preparing exotic quantum strongly-correlated states.