3D extruded composite thermoelectric threads for flexible energy harvesting

Peng, J.; Witting, I.; Geisendorfer, N.; Wang, M.; Chang, M.; Jakus, A.; Kenel, C.; Yan, X.; Shah, R.; Snyder, G. J.; Grayson, M.

3D extruded composite thermoelectric threads for flexible energy harvesting

J. Peng (), I. Witting, N. Geisendorfer, M. Wang, M. Chang, A. Jakus, C. Kenel, X. Yan, R. Shah (), G. J. Snyder and M. Grayson ()
Additional contact information
J. Peng: Northwestern University
I. Witting: Northwestern University
N. Geisendorfer: Northwestern University
M. Wang: Northwestern University
M. Chang: Northwestern University
A. Jakus: Dimension Inx, LLC
C. Kenel: Northwestern University
X. Yan: Northwestern University
R. Shah: Dimension Inx, LLC
G. J. Snyder: Northwestern University
M. Grayson: Northwestern University

Nature Communications, 2019, vol. 10, issue 1, 1-8

Abstract: Abstract Whereas the rigid nature of standard thermoelectrics limits their use, flexible thermoelectric platforms can find much broader applications, for example, in low-power, wearable energy harvesting for internet-of-things applications. Here we realize continuous, flexible thermoelectric threads via a rapid extrusion of 3D-printable composite inks (Bi2Te3 n- or p-type micrograins within a non-conducting polymer as a binder) followed by compression through a roller-pair, and we demonstrate their applications in flexible, low-power energy harvesting. The thermoelectric power factors of these threads are enhanced up to 7 orders-of-magnitude after lateral compression, principally due to improved conductivity resulting from reduced void volume fraction and partial alignment of thermoelectric micrograins. This dependence is quantified using a conductivity/Seebeck vise for pressure-controlled studies. The resulting grain-to-grain conductivity is well explained with a modified percolation theory to model a pressure-dependent conductivity. Flexible thermoelectric modules are demonstrated to utilize thermal gradients either parallel or transverse to the thread direction.

Date: 2019
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DOI: 10.1038/s41467-019-13461-2

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