Optimization of thermoelectric properties of carbon nanotube veils by defect engineering

Carbon nanotubes (CNTs), with their combination of excellent electrical conductivity, Seebeck coefficient, mechanical robustness and environmental stability are highly desired as thermoelectric (TE) materials for a wide range of fields including Internet of Things, health monitoring and environmental remediation solutions. However, their high thermal conductivity (kappa) is an obstacle to practical TE applications. Herein, we present a novel method to reduce the kappa of CNT veils, by introducing defects, while preserving their Seebeck coefficient and electrical conductivity. Solid-state drawing of a CNT veil embedded within two polycarbonate films generates CNT veil fragments of reducing size with increasing draw ratio. A successive heat treatment, at above the polycarbonate glass-to-rubber transition temperature, spontaneously reconnects the CNT veils fragments electrically but not thermally. Stretching to a draw ratio of 1.5 and heat repairing at 170 degrees C leads to a dramatic 3.5-fold decrease in kappa (from 46 to 13 W m(-1) K-1), in contrast with a decrease in electrical conductivity of only 26% and an increase in Seebeck coefficient of 10%. To clarify the mechanism of reduction in thermal conductivity, a large-scale mesoscopic simulation of CNT veils under uniaxial stretching has also been used. This work shows that defect engineering can be a valuable strategy to optimize TE properties of CNT veils and, potentially, other thermoelectric materials.

Automated summary

Carbon nanotubes (CNTs) have excellent properties such as electrical conductivity, Seebeck coefficient, mechanical strength, and environmental stability, making them highly desirable for thermoelectric applications. However, their high thermal conductivity poses a challenge. This study presents a novel method to reduce the thermal conductivity of CNT veils by introducing defects while preserving their other properties.