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Mitigating the Effect of Nanoscale Porosity on Thermoelectric Power Factor of Si

S. Aria Hosseini, Giuseppe Romano, P. Alex Greaney

2021ACS Applied Energy Materials14 citationsDOIOpen Access PDF

Abstract

The addition of porosity to thermoelectric (TE) materials can significantly increase the figure of merit, ZT, by reducing the thermal conductivity. Unfortunately, porosity is also detrimental to the TE power factor (PF) in the numerator of the figure of merit, ZT. In this manuscript, we derive strategies to recoup electrical performance in nanoporous Si by fine tuning the carrier concentration and through judicious design of the pore size and shape so as to provide energy-selective electron filtering. In this study, we considered phosphorus-doped silicon containing discrete pores that are either spheres, cylinders, cubes, or triangular prisms. The effects from these pores are compared with those from extended pores with circular, square, and triangular cross-sectional shape and infinite length perpendicular to the electrical current. A semiclassical Boltzmann transport equation is used to model Si TE PF. This model reveals three key results: the largest enhancement in Seebeck coefficient occurs with cubic pores. The fractional improvement is about 15% at low carrier concentration (<1020 1/cm3) and up to 60% at high carrier population with characteristic length around ∼1 nm. To obtain the best energy filtering effect at room temperature, nanoporous Si needs to be doped to higher carrier concentration than is optimal for bulk Si. Finally, in n-type Si TEs, the electron filtering effect that can be generated with nanoscale porosity is significantly lower than the ideal filtering effect; nevertheless, the enhancement in the Seebeck coefficient that can be obtained is large enough to offset the reduction in electrical conductivity caused by porosity.

Topics & Concepts

Materials sciencePorosityNanoscopic scaleThermoelectric effectPower factorEngineering physicsNanotechnologyPower (physics)Composite materialEngineeringPhysicsThermodynamicsAdvanced Thermoelectric Materials and DevicesThermal properties of materialsSemiconductor materials and interfaces