Our research spans a broad range of topics in quantum materials, including topological phases, high-temperature superconductors, frustrated magnets, multiferroics, and thermoelectric materials. In particular, we are interested in tuning materials properties by chemistry, pressure, and magnetic field. To study the electrical properties of materials, we use a complete array of transport measurements including electrical resistivity, Hall effect, thermal conductivity, thermal Hall effect, Seebeck and Nernst effect. 

Materials

Pressure

Pressure is a clean tuning parameter which can be used to tune the lattice parameters, band structures, orbital overlaps, electron-lattice coupling, and magnetic interactions. Hydrostatic pressure is applied by placing a sample inside a pressure cell which is typically a piston-cylinder assembly that confines a hydrostatic pressure medium, the sample, and the leads. Two common types of pressure cells are Diamond anvil cells and clamp cells.

Transport

Transport coefficients are linear responses of charge or heat carriers to external electric or thermal potentials. They come in two basic flavors: longitudinal and transverse. The latter is when the response is perpendicular to the external potential and is measured in the presence of a magnetic field. There are three types of transport coefficients: electrical, thermal, and thermo-electric as summarized in the figure.

Electrical resistivity (ρ) is when we apply an electric current through the material and measure the longitudinal electrical voltage. Hall effect is when we measure the transverse electric voltage in the presence of a magnetic field. 

Thermal conductivity (κ) is when we apply a thermal current through the material and measure the longitudinal temperature difference. Thermal Hall effect is when we measure the transverse temperature difference in the presence of a magnetic field. Seebeck effect (S) is when we apply a thermal current through the material and measure the longitudinal electric voltage. Nernst effect is when we measure the transverse thermo-electric voltage in the presence of a magnetic field.

Typically, we perform these transport measurements at very low temperatures, near zero Kelvin in order to probe the true ground state of a material. For example, measurements of thermal conductivity need to be done at milliKelvin temperature range to reliably extract the residual linear term. Therefore, all the transport measurements above are usually mounted on either a dilution refrigerator or an adiabatic demagnetization fridge.

transport

Facilities

Mag Lab in Tallahassee

Our group regularly performs experiments at intense magnetic fields in the National High Magnetic Field Laboratory (MagLab) in Tallahassee. Specifically, we study the quantum oscillations of topological semimetals by measuring both the resistivity and torque magnetometry.