Record High Thermoelectric Powerfactor in Single and Few-Layer MoS$_2$

The quest for high-efficiency heat-to-electricity conversion has been one of the major driving forces towards renewable energy production for the future. Efficient thermoelectric devices require careful material engineering such as high voltage generation from a temperature gradient, and high electrical conductivity while maintaining a low thermal conductivity. Significant progress in the thermoelectric performance of materials has been made by exploring the ultralow thermal conductivity at high temperature, reducing the thermal conductivity by nanostructuring, resonant doping and energy-dependent scattering. For a given thermal conductivity and temperature, thermoelectric powerfactor is determined by the electronic structure of the material. Low dimensionality (1D and 2D) opens new routes to high powerfactor due to their unique density of states of confined electrons and holes. Emerging 2D transition metal dichalcogenide (TMDC) semiconductors represent a new class of thermoelectric materials not only from their discretized density of states, but especially due to their large effective masses and high carrier mobilities, different from gapless semi-metallic graphene. Here we report a measured powerfactor of $MoS_2$ as large as $8.5 mWm^{-1}K^{-2}$ at room temperature, the highest among all thermoelectric materials and twice that of commercial thermoelectric material $Bi_2Te_3$. For the first time, the measurement of the thermoelectric properties of monolayer $MoS_2$ allows us to determine the quantum confined 2D density of states near the conduction band edge, which cannot be measured by electrical conductivity alone. The demonstrated record high powerfactor in 2D TMDCs holds promise for efficient thermoelectric energy conversion.