Tellurium-Free, Sustainable Thermoelectric Device for Mid-Temperature Waste Heat Recovery

Vaskuri C. S. Theja , Vaithinathan Karthikeyan , Sanjib Nayak , Gopalan Saianand , Vellaisamy A. L. Roy

Carbon Energy ›› 2025, Vol. 7 ›› Issue (5) : e689

PDF
Carbon Energy ›› 2025, Vol. 7 ›› Issue (5) : e689 DOI: 10.1002/cey2.689
RESEARCH ARTICLE

Tellurium-Free, Sustainable Thermoelectric Device for Mid-Temperature Waste Heat Recovery

Author information +
History +
PDF

Abstract

Famatinite (Cu3SbS4, p-type) and chalcopyrite (CuFeS2, n-type) are well-recognized sustainable minerals with good intermediate-temperature thermoelectric performance. In this article, we utilize the inherent thermoelectric properties of these compounds to demonstrate real-time operational performance as a coupled thermoelectric generator (TEG) for waste heat recovery applications. First, we synthesized the polycrystalline and nano-grained famatinite and chalcopyrite materials with high purity through a sustainable synthesis process of mechanical alloying followed by hot pressing. A maximum output power of ~5 mW by the developed TEG was demonstrated while harvesting from a waste heat source of 723 K. Furthermore, the TEG performance via computational simulations for varied thermal gradients was validated. Our results highlight the sustainable development of thermoelectric power generator from earth-abundant minerals having strong stability and capacity to convert waste heat to electricity, which opens a new direction for fabricating a low-cost TEG for intermediate-temperature applications.

Keywords

chalcopyrite / device / famatinite / TEG / thermoelectric

Cite this article

Download citation ▾
Vaskuri C. S. Theja, Vaithinathan Karthikeyan, Sanjib Nayak, Gopalan Saianand, Vellaisamy A. L. Roy. Tellurium-Free, Sustainable Thermoelectric Device for Mid-Temperature Waste Heat Recovery. Carbon Energy, 2025, 7(5): e689 DOI:10.1002/cey2.689

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

H. L. van Soest, M. G. J. den Elzen, and D. P. van Vuuren, “Net-Zero Emission Targets for Major Emitting Countries Consistent With the Paris Agreement,” Nature Communications 12, no. 1 (2021): 2140-2148.
[2]

J. Rogelj, O. Geden, A. Cowie, and A. Reisinger, “Net-Zero Emissions Targets Are Vague: Three Ways to Fix,” Nature. 591 (2021): 365-368.
[3]

S. Choo, F. Ejaz, H. Ju, et al., “Cu2Se-Based Thermoelectric Cellular Architectures for Efficient and Durable Power Generation,” Nature Communications 12, no. 1 (2021): 3550-3560.
[4]

Z. Bu, X. Zhang, Y. Hu, et al., “A Record Thermoelectric Efficiency in Tellurium-Free Modules for Low-Grade Waste Heat Recovery,” Nature Communications 13, no. 1 (2022): 237-244.
[5]

R. Freer and A. V. Powell, “Realising the Potential of Thermoelectric Technology: A Roadmap,” Journal of Materials Chemistry C 8, no. 2 (2020): 441-463.
[6]

P. Fan, Z. Zheng, Y. Li, et al., “Low-Cost Flexible Thin Film Thermoelectric Generator on Zinc Based Thermoelectric Materials,” Applied Physics Letters 106, no. 7 (2015): 073901.
[7]

Z. Zhou, Y. Huang, B. Wei, et al., “Compositing Effects for High Thermoelectric Performance of Cu2Se-Based Materials,” Nature Communications 14, no. 1 (2023): 2410-2418.
[8]

M. R. Burton, T. Liu, J. McGettrick, et al., “Thin Film Tin Selenide (SnSe) Thermoelectric Generators Exhibiting Ultralow Thermal Conductivity,” Advanced Materials 30, no. 31 (2018): 1801357.
[9]

L. Yin, X. Li, X. Bao, et al., “CALPHAD Accelerated Design of Advanced Full-Zintl Thermoelectric Device,” Nature Communications 15, no. 1 (2024): 1468-1476.
[10]

P. Ying, L. Wilkens, H. Reith, et al., “A Robust Thermoelectric Module Based on MgAgSb/Mg3(Sb,Bi)2 With a Conversion Efficiency of 8.5% and a Maximum Cooling of 72 K,” Energy & Environmental Science 15, no. 6 (2022): 2557-2566.
[11]

P. Qiu, T. Mao, Z. Huang, et al., “High-Efficiency and Stable Thermoelectric Module Based on Liquid-Like,” Joule 3, no. 6 (2019): 1538-1548.
[12]

V. C. S. Theja, V. Karthikeyan, C. C. Yeung, S. Venkatesh, S. Nayak, and V. A. L. Roy, “Amorphous Carbon Nano-Inclusions for Strategical Enhancement of Thermoelectric Performance in Earth-Abundant Cu3SbS4,” Journal of Alloys and Compounds 900 (2022): 163433.
[13]

T. Tanishita, K. Suekuni, H. Nishiate, C. H. Lee, and M. Ohtaki, “A Strategy for Boosting the Thermoelectric Performance of Famatinite Cu3SbS4,” Physical Chemistry Chemical Physics 22, no. 4 (2020): 2081-2086.
[14]

K. Chen, C. Di Paola, B. Du, et al., “Enhanced Thermoelectric Performance of Sn-Doped Cu3SbS4,” Journal of Materials Chemistry C 6, no. 31 (2018): 8546-8552.
[15]

B. Lu, M. Wang, J. Yang, et al., “Dense Twin and Domain Boundaries Lead to High Thermoelectric Performance in Sn-Doped Cu3SbS4,” Applied Physics Letters 120, no. 17 (2022): 173901.
[16]

V. C. S. Theja, V. Karthikeyan, D. S. Assi, S. Gopalan, and V. A. L. Roy, “Probing the Effect of MWCNT Nanoinclusions on the Thermoelectric Performance of Cu3SbS4 Composites,” ACS Omega 7, no. 51 (2022): 48484-48492.
[17]

V. C. S. Theja, V. Karthikeyan, D. S. Assi, H. Huang, C. H. Shek, and V. A. L. Roy, “Dispersion of InSb Nanoinclusions in Cu3SbS4 for Improved Stability and Thermoelectric Efficiency,” Advanced Energy and Sustainability Research 4, no. 11 (2023): 2300125.
[18]

J. Yang, X. L. Shi, Q. Yang, et al., “Approaching High Thermoelectric Performance in p-type Cu3SbS4-Based Materials by Rational Electronic and Nano/Microstructural Engineering,” Chemical Engineering Journal 469 (2023): 143965.
[19]

D. Zhang, X. Wang, H. Wu, et al., “High Thermoelectric Performance in Earth-Abundant Cu3SbS4 by Promoting Doping Efficiency via Rational Vacancy Design,” Advanced Functional Materials 33, no. 15 (2023): 2214163.
[20]

P. Zhang, Y. X. Zhang, H. Lai, J. Deng, J. Feng, and Z. H. Ge, “Enhanced Thermoelectric Properties of Natural Chalcopyrite by Vacuum Annealing,” Materials Letters 253 (2019): 430-433.
[21]

H. Xie, X. Su, Y. Yan, et al., “Thermoelectric Performance of CuFeS2+2X Composites Prepared By Rapid Thermal Explosion,” NPG Asia Materials 9, no. 6 (2017): e390.
[22]

H. Xie, X. Su, T. P. Bailey, et al., “Anomalously Large Seebeck Coefficient of CuFeS2 Derives From Large Asymmetry in the Energy Dependence of Carrier Relaxation Time,” Chemistry of Materials 32, no. 6 (2020): 2639-2646.
[23]

S. Tippireddy, F. Azough, K. Vikram, et al., “Tin-Substituted Chalcopyrite: An n-Type Sulfide With Enhanced Thermoelectric Performance,” Chemistry of Materials 34, no. 13 (2022): 5860-5873.
[24]

H. Pang, C. Bourgès, R. Jha, et al., “Revealing an Elusive Metastable Wurtzite CuFes2 and the Phase Switching Between Wurtzite and Chalcopyrite for Thermoelectric Thin Films,” Acta Materialia 235 (2022): 118090.
[25]

S. Tippireddy, F. Azough, A. Bhui, et al., “Enhancement of Thermoelectric Properties of CuFeS2 Through Formation of Spinel-Type Microprecipitates,” Journal of Materials Chemistry A 11, no. 42 (2023): 22960-22970.
[26]

B. Ge, H. Lee, C. Zhou, et al., “Exceptionally Low Thermal Conductivity Realized in the Chalcopyrite CuFeS2 via Atomic-Level Lattice Engineering,” Nano Energy 94 (2022): 106941.
[27]

Y. Li, T. Zhang, Y. Qin, et al., “Thermoelectric Transport Properties of Diamond-Like Cu1-xFe1+xS2 Tetrahedral Compounds,” Journal of Applied Physics 116, no. 20 (2014): 203705.
[28]

H. R. Williams, R. M. Ambrosi, K. Chen, et al., “Spark Plasma Sintered Bismuth Telluride-Based Thermoelectric Materials Incorporating Dispersed Boron Carbide,” Journal of Alloys and Compounds 626 (2015): 368-374.
[29]

H. S. Kim, Z. M. Gibbs, Y. Tang, H. Wang, and G. J. Snyder, “Characterization of Lorenz Number With Seebeck Coefficient Measurement,” APL Materials 3, no. 4 (2015): 1-6.
[30]

N. K. Singh, S. Bathula, B. Gahtori, K. Tyagi, D. Haranath, and A. Dhar, “The Effect of Doping on Thermoelectric Performance of p-Type SnSe: Promising Thermoelectric Material,” Journal of Alloys and Compounds 668 (2016): 152-158.
[31]

N. M. Yatim, N. Z. I. M. Sallehin, S. Suhaimi, and M. A. Hashim, “A Review of ZT Measurement for Bulk Thermoelectric Material,” AIP Conference Proceedings 1972, no. 1 (2018): 030002.
[32]

S. He, Y. Li, L. Liu, et al., “Semiconductor Glass With Superior Flexibility and High Room Temperature Thermoelectric Performance,” Science Advances 6, no. 15 (2020): eaaz8423.
[33]

V. C. S. Theja, V. Karthikeyan, S. Nayak, et al., “Facile Composite Engineering to Boost Thermoelectric Power Conversion in ZnSb Device,” Journal of Physics and Chemistry of Solids 178 (2023): 111329.
[34]

S. Perumal, S. Roychowdhury, and K. Biswas, “Reduction of Thermal Conductivity Through Nanostructuring Enhances the Thermoelectric Figure of Merit in Ge1-xBixTe,” Inorganic Chemistry Frontiers 3, no. 1 (2016): 125-132.
[35]

A. Banik, B. Vishal, S. Perumal, R. Datta, and K. Biswas, “The Origin of Low Thermal Conductivity in Sn1-xSbxTe: Phonon Scattering via Layered Intergrowth Nanostructures,” Energy & Environmental Science 9, no. 6 (2016): 2011-2019.
[36]

J. Zhang, C. Zhang, T. Zhu, Y. Yan, X. Su, and X. Tang, “Mechanical Properties and Thermal Stability of the High-Thermoelectric-Performance Cu2Se Compound,” ACS Applied Materials & Interfaces 13, no. 38 (2021): 45736-45743.
[37]

M. Hong, J. Zou, and Z. G. Chen, “Thermoelectric GeTe With Diverse Degrees of Freedom Having Secured Superhigh Performance,” Advanced Materials 31, no. 14 (2019): 1807071.
[38]

B. Chen, J. Li, M. Wu, et al., “Simultaneous Enhancement of the Thermoelectric and Mechanical Performance in One-Step Sintered n-Type Bi2Te3-Based Alloys via a Facile MgB2 Doping Strategy,” ACS Applied Materials & Interfaces 11, no. 49 (2019): 45746-45754.
[39]

X. Y. Mao, X. L. Shi, L. C. Zhai, et al., “High Thermoelectric and Mechanical Performance in the n-Type Polycrystalline Snse Incorporated With Multi-Walled Carbon Nanotubes,” Journal of Materials Science & Technology 114 (2022): 55-61.
[40]

S. Duan, N. Man, J. Xu, et al., “Thermoelectric (Bi,Sb)2Te3-Ge0.5Mn0.5Te Composites With Excellent Mechanical Properties,” Journal of Materials Chemistry A 7, no. 15 (2019): 9241-9246.
[41]

S. Ahmad, A. Singh, S. Bhattacharya, et al., “Band Convergence and Phonon Scattering Mediated Improved Thermoelectric Performance of SnTe-PbTe Nanocomposites,” ACS Applied Energy Materials 3, no. 9 (2020): 8882-8891.
[42]

M. Zebarjadi, “Heat Management in Thermoelectric Power Generators,” Scientific Reports 6, no. 1 (2016): 20951.
[43]

W. Li, B. Poudel, R. A. Kishore, et al., “Toward High Conversion Efficiency of Thermoelectric Modules Through Synergistical Optimization of Layered Materials,” Advanced Materials 35, no. 20 (2023): 2210407.
[44]

J. Qiu, Y. Yan, T. Luo, et al., “3D Printing of Highly Textured Bulk Thermoelectric Materials: Mechanically Robust BiSbTe Alloys With Superior Performance,” Energy & Environmental Science 12, no. 10 (2019): 3106-3117.
[45]

Z. H. Ge, L. D. Zhao, D. Wu, et al., “Low-Cost, Abundant Binary Sulfides as Promising Thermoelectric Materials,” Materials Today 19, no. 4 (2016): 227-239.
[46]

A. Nozariasbmarz, B. Poudel, W. Li, H. B. Kang, H. Zhu, and S. Priya, “Bismuth Telluride Thermoelectrics With 8% Module Efficiency for Waste Heat Recovery Application,” iScience 23, no. 7 (2020): 101340.

RIGHTS & PERMISSIONS

2025 The Author(s). Carbon Energy published by Wenzhou University and John Wiley & Sons Australia, Ltd.

AI Summary AI Mindmap
PDF

15

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/