2D Materials Research

Research

We investigate unconventional superconductivity, Kagome materials, van der Waals heterostructures, and microfabricated quantum devices through low-temperature transport and device engineering.

Active

Quantum Phases

Unconventional Superconductivity

Symmetry breaking and nonreciprocal superconducting transport in RbV3Sb5, CsV3Sb5, and Td-MoTe2, including magnetic hysteresis, half-quantum flux states, and superconducting diode effects.

TRS breaking | half flux
Active

Frustrated Lattices

Kagome Materials

Thin-flake RbV3Sb5 and CsV3Sb5 devices reveal how kagome geometry, topology, and electronic correlations generate nematicity, unconventional pairing, and switchable quantum states.

RbV3Sb5 | CsV3Sb5
Active

Layered Materials

van der Waals Heterostructures

Layered systems such as MnBi2Te4/Cr2Ge2Te6 and Td-MoTe2 provide tunable interfaces for engineering magnetic exchange, inversion asymmetry, and interfacial superconducting transport.

Magnetism | interfaces
Active

Device Physics

Microfabrication and Quantum Devices

Nanowires, nanoplates, thin-flake rings, and multi-terminal devices enable gate-tunable studies of Fermi-arc spin transport, quantum interference, Hall states, and superconducting circuits.

Nanowires | rings | gates

Methods & Infrastructure

Dilution refrigerator
Sub-10 mK
Vector magnetic field
14 T
Nanofabrication
EBL / vdW assembly
Measurement
Transport + RF