High thermoelectric figure of merit of porous Si nanowires from 300 to 700K

Abstract

Thermoelectrics operating at high temperature can cost-effectively convert waste heat and compete with other zero-carbon technologies. Among different high-temperature thermoelectrics materials, silicon nanowires possess the combined attributes of cost effectiveness and mature manufacturing infrastructures. Despite significant breakthroughs in silicon nanowires based thermoelectrics for waste heat conversion, the figure of merit (ZT) or operating temperature has remained low. Here, we report the synthesis of large-area, wafer-scale arrays of porous silicon nanowires with ultra-thin Si crystallite size of similar to 4nm. Concurrent measurements of thermal conductivity (kappa), electrical conductivity (sigma), and Seebeck coefficient (S) on the same nanowire show a ZT of 0.71 at 700K, which is more than similar to 18 times higher than bulk Si. This ZT value is more than two times higher than any nanostructured Si-based thermoelectrics reported in the literature at 700K. Experimental data and theoretical modeling demonstrate that this work has the potential to achieve a ZT of similar to 1 at 1000K. Performance of Si nanowires as thermoelectrics are evaluated only from cryogenic to ambient temperatures and ZT has remained low. Here, the authors systematically optimized the synthesis method and improved the suspended microdevice platform to achieve high-performance thermoelectrics up to 700K.