Discovering pathways to experimentally realize quantum phases of matter and exert control over their properties is one of the central goals of modern physics, which holds promise for a new generation of electronic devices with currently inaccessible and likely unimaginable functionalities. With the explosion in the field of quantum materials in the past decade, it is conceivable that a vast number of new materials with unprecedented quantum states and properties are yet to be discovered. This is exactly what Dr. Ran’s research lab is dedicated to: discovery, synthesis, characterization and control of novel quantum materials with emergent electronic and magnetic states.
Of particular interest are topological quantum materials showing the coexistence of topology and other quantum phases, e.g., superconductivity, magnetism, charge density wave and ferroelectricity. Interplay of topology and these quantum phases gives rise to a variety of exotic quantum states, including the quantum anomalous Hall effect, topological axion states, Majorana fermions, some of which have potential applications for quantum computing and spintronics. Even though topological revolution has been the central theme in condensed matter physics in the past decade, theoretical prediction and experimental realization of such composite topological quantum materials has just started, and extensive experimental efforts to discover and characterize new systems are desperately in need.
The techniques we use to study these quantum materials include: crystal synthesis, nano or micro fabrication, extreme temperature, magnetic field and pressure condition, and quantum transport.
