Our research spans from exploring basic Physics in reduced dimensionality systems to building novel devices for applications.

From a fundamental Physics standpoint, small is often different. A prime example of this is the difference between the quantum and the classical worlds. We seek to gain fundamental understanding of quantum effects and other novel Physics at nanoscales. Charge, spin and thermal transport measurements performed at low-temperatures in our lab offer a versatile probe into these properties.

The unique insights uncovered by these studies are used to guide device design for different applications. We are especially interested in exploring materials and devices that can aid in developing alternative computing paradigms in a post-Moore, post-Dennard world.

Our research spans from exploring basic Physics in reduced dimensionality systems to building novel devices for applications.

From a fundamental Physics standpoint, small is often different. A prime example of this is the difference between the quantum and the classical worlds. We seek to gain fundamental understanding of quantum effects and other novel Physics at nanoscales. Charge, spin and thermal transport measurements performed at low-temperatures in our lab offer a versatile probe into these properties.

The unique insights uncovered by these studies are used to guide device design for different applications. We are especially interested in exploring materials and devices that can aid in developing alternative computing paradigms in a post-Moore, post-Dennard world.