Members

My research focuses on strongly correlated few-body quantum systems, with particular emphasis on ultracold systems in one dimension. In the past, I worked on designs of quantum simulators built of ultracold Rydberg atoms. My current research focuses on exploring the properties of Hubbard models, with applications in condensed matter physics.

My research focus is on quantum correlations in interacting cold atom systems. I mainly confine myself to one dimension and continuous systems, trying to unravel how interaction effects can be used to enhance the operation of quantum machines, in and out of equillibrium. Also I ocassionally partake in some quantum control, but only on Fridays.   

I am particularly interested in quantum many-body systems, using tensor network methods to explore their properties. My research focuses on characterizing superfluidity in the spin-1 Bose-Hubbard model through Matrix Product States implemented in low-level programming language. My work bridges condensed matter theory, quantum simulations, and computational physics.

My research interests include the quantum droplet and phase separation state in quantum mixture, as well as quantum phase transition. I aim to understand the exotic ground state and excited state of quantum matter. Ultimately, I hope to apply this knowledge to applications such as quantum control and metrology.

My research interests lie in quantum thermodynamics, particularly using ultracold atomic systems in one-dimensional traps. Previously, I worked on hybrid classical-quantum algorithms for work extraction in spin-chain models. My current research focuses on nonequilibrium thermodynamics and the interplay between quantum correlations and work extraction in quantum batteries based on 1D ultracold gases.

My research explores light-matter interactions in hybrid quantum systems, particularly in optical nanofiber waveguides and cavity QED platforms for emerging quantum technologies. I have previously investigated spontaneous emission in quantum dot–metal nanoparticle systems. My current interest lies in superradiance and subradiance within waveguides, and in developing high-fidelity remote quantum gates in coupled-cavity architectures to support scalable, distributed quantum computing.

No matter how patiently the researchers explain their work to me, the moment I try to grasp it, it collapses.
It feels like I'm somewhere between understanding and not quite—both at the same time.  Still, I do my best to keep things running smoothly behind the scenes.
What I enjoy most in this role is watching researchers grow, glimpsing cutting-edge science, and meeting fascinating visitors from around the world.

My interest lies in ultracold quantum gases, specifically Bose-Einstein condensates (BEC). I have worked in dipolar BEC for a long time, studying interesting solutions like solitons, droplets and supersolids etc. I have explored a few interesting topics that can be probed with BECs such as light-matter interaction and shortcuts to adiabaticity. My newest research interest is polarons in BEC.

My interests range from computational quantum mechanics and numerical simulations to quantum thermodynamics and quantum computation. In the past, I worked on simulating decoherence in crystal systems and entanglement in spin chains. I look forward to using analytical and computational methods to explore various quantum systems and their applications.

My research interests focus on exploring quantum phenomena in ultracold atomic gases confined within precisely controlled traps. I am particularly interested in topological phases of matter, Floquet engineering, and time crystals. Additionally, I aim to apply machine learning techniques to address low-energy physics problems. Ultimately, my objective is to advance our understanding of the fundamental nature of quantum matter and investigate its potential applications in quantum computation and simulation.