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Computationally Modelling the Use of Nanotechnology to Enhance the Performance of Thermoelectric Materials

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  • Peter Spriggs

    (Department of Engineering, Durham University, Durham DH1 3LE, UK)

  • Qing Wang

    (Department of Engineering, Durham University, Durham DH1 3LE, UK)

Abstract

The increased focus on global climate change has meant that the thermoelectric market has received considerably more attention. There are many processes producing large amounts of waste heat that can be utilised to generate electrical energy. Thermoelectric devices have long suffered with low efficiencies, but this can be addressed in principle by improving the performance of the thermoelectric materials these devices are manufactured with. This paper investigates the thermoelectric performance of market standard thermoelectric materials before analysing how this performance can be improved through the adoption of various nanotechnology techniques. This analysis is carried out through the computational simulation of the materials over low-, mid- and high-temperature ranges. In the low-temperature range, through the use of nanopores and full frequency phonon scattering, Mg 0.97 Zn 0.03 Ag 0.9 Sb 0.95 performed best with a ZT value of 1.45 at 433 K. Across the mid-temperature range a potentially industry leading ZT value of 2.08 was reached by AgSbTe 1.85 Se 0.15 . This was carried out by simulating the effect of band engineering and the introduction of dense stacking faults due to the addition of Se into AgSbTe 2 . AgSbTe 1.85 Se 0.15 cannot be implemented in devices operating above 673 K because it degrades too quickly. Therefore, for the top 200 K of the mid-temperature range a PbBi 0.002 Te–15% Ag 2 Te nanocomposite performed best with a maximum ZT of 2.04 at 753 K and maximum efficiency of 23.27 at 813 K. In the high-temperature range, through the doping of hafnium (Hf) the nanostructured FeNb 0.88 Hf 0.12 Sb recorded the highest ZT value of 1.49 at 1273 K. This was closely followed by Fe 1.05 Nb 0.75 Ti 0.25 Sb, which recorded a ZT value of 1.31 at 1133 K. This makes Fe 1.05 Nb 0.75 Ti 0.25 Sb an attractive substitute for FeNb 0.88 Hf 0.12 Sb due to the much lower cost and far greater abundance of titanium (Ti) compared with hafnium.

Suggested Citation

  • Peter Spriggs & Qing Wang, 2020. "Computationally Modelling the Use of Nanotechnology to Enhance the Performance of Thermoelectric Materials," Energies, MDPI, vol. 13(19), pages 1-21, September.
    • Handle: RePEc:gam:jeners:v:13:y:2020:i:19:p:5096-:d:421943
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    References listed on IDEAS

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    1. Marian Von Lukowicz & Elisabeth Abbe & Tino Schmiel & Martin Tajmar, 2016. "Thermoelectric Generators on Satellites—An Approach for Waste Heat Recovery in Space," Energies, MDPI, vol. 9(7), pages 1-14, July.
    2. Zheng, X.F. & Liu, C.X. & Yan, Y.Y. & Wang, Q., 2014. "A review of thermoelectrics research – Recent developments and potentials for sustainable and renewable energy applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 32(C), pages 486-503.
    3. Fitriani, & Ovik, R. & Long, B.D. & Barma, M.C. & Riaz, M. & Sabri, M.F.M. & Said, S.M. & Saidur, R., 2016. "A review on nanostructures of high-temperature thermoelectric materials for waste heat recovery," Renewable and Sustainable Energy Reviews, Elsevier, vol. 64(C), pages 635-659.
    4. Twaha, Ssennoga & Zhu, Jie & Yan, Yuying & Li, Bo, 2016. "A comprehensive review of thermoelectric technology: Materials, applications, modelling and performance improvement," Renewable and Sustainable Energy Reviews, Elsevier, vol. 65(C), pages 698-726.
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    Cited by:

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