Reclaim of Wrecked Bi-Te Based Materials In Peltier Modules In Thermopower Properties By Mechanical Milling
Year 2023,
, 209 - 217, 26.03.2023
Mehmet Çetin
,
Gizem Durak Yüzüak
,
Ercüment Yüzüak
Abstract
We thoroughly evaluated the effects of various treatments on the structural and electrical properties of the two as-cast materials, “Sb-doping Bi-Te (p-type)” and “Se-doping Bi-Te (n-type)” which are frequently present in abandoned Peltier modules. To investigate the thermoelectric properties of Bi2Te3-based materials, waste alloys characterized by electrical conductivity using the hot-end method. Alloys were purified by performing arc melting on a water-cooled copper crucible in a vacuum of at least 10-3 mbar, with five times melting sessions to assure homogeneity. A single and long milling period of 144 hours is applied. After the compressing operation, the resulting discs with nanostructures were annealed for an hour at 600 K under vacuum conditions. The discs' structural properties were characterized using X-ray diffraction (XRD) and their surfaces and stoichiometries were determined using scanning electron microscopy with an energy dispersive feature. The Seebeck coefficient of the nanoparticle formed n-type Bi-Te based sample is -35.3 µV.K-1 and p-type Bi-Te based sample is 100 µV.K-1 (15% of mean error margin). It was found that a notable improvement was attained in comparison to the initial state with the addition of nanoparticles.We thoroughly evaluated the effects of various treatments on the structural and electrical properties of the two as-cast materials, “Sb-doping Bi-Te (p-type)” and “Se-doping Bi-Te (n-type)”, which are frequently present in abandoned Peltier modules. To investigate the thermoelectric properties of Bi2Te3-based materials, waste alloys were produced and separated by electrical conductivity using the hot-end method. The alloys were purified by performing arc melting on a water-cooled copper crucible in a vacuum of at least 10-3 mbar, with 5 times melting sessions to assure homogeneity. A ball-milled procedure was used to reduce the obtained mass-scale materials to nano sizes. Single and long milling period of 144 hours is applied. After the compressing operation, the resulting discs with nano-structures were annealed for an hour at 600 K in a vacuum. X-ray diffraction was used to characterize the discs' structures, while scanning electron microscopy and energy dispersive X-ray spectroscopy were used to examine the discs' surfaces and determine their morphologies. Based on thermal imaging camera scans and Si-diode, we know that the Seebeck coefficient of the nanoparticle formed n-type Bi-Te based sample is -35.37 V.K-1, while that of the nanoparticle formed p-type Bi-Te based sample is 100.05 V.K-1 (15% of mean error margin). It was found that a notable improvement was attained in comparison to the initial state with the addition of nanoparticles.
Project Number
Scientific and Technological Research Council of Turkey-TÜBİTAK, 2209-A Research Project Support Program for Undergraduate Students
Thanks
The authors would like to thank Sedanur Baltacı and Gaye Dülger for their helpful contribution.
References
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- [23]Barako M.T., Park W., Marconnet A.M., Asheghi M., Goodson K.E., Thermal Cycling, Mechanical Degradation, and the Effective Figure of Merit of a Thermoelectric Module, Journal of Electronic Materials, 42 (3) (2013) 372–381.
- [24]Karri N.K., Mo C., Geometry optimization for structural reliability and performance of a thermoelectric generator, SN Applied Sciences, 1 (9) (2019) 1097.
- [25]Anandan P., Omprakash M., Azhagurajan M., Arivanandhan M., Rajan Babu D., Koyama T., Hayakawa Y., Tailoring bismuth telluride nanostructures using a scalable sintering process and their thermoelectric properties, Cryst.Eng.Comm., 16 (34) (2014) 7956-7962.
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Year 2023,
, 209 - 217, 26.03.2023
Mehmet Çetin
,
Gizem Durak Yüzüak
,
Ercüment Yüzüak
Project Number
Scientific and Technological Research Council of Turkey-TÜBİTAK, 2209-A Research Project Support Program for Undergraduate Students
References
- [1] Shi X.-L., Zou J., and Chen Z.-G., Advanced Thermoelectric Design: From Materials and Structures to Devices, Chemical Reviews, 120 (2020) 7399-7515.
- [2] Finn P.A., Asker C., Wan K., Bilotti E., Fenwick O., Nielsen C.B., Thermoelectric Materials: Current Status and Future Challenges, Frontiers in Electronic Materials, 1 (2021) 677845.
- [3] Rojas J.P., Singh D., Inayat S.B., Sevilla G.A.T., Fahad H.M., Hussain M.M., Micro and nano-engineering enabled new generation of thermoelectric generator devices and applications, ECS Journal of Solid-State Science and Technology, 6 (3) (2017) N3036.
- [4] Pan Y., Li J.F., Thermoelectric performance enhancement in n-type Bi2(TeSe)3 alloys owing to nanoscale inhomogeneity combined with a spark plasma-textured microstructure, NPG Asia Materials, 8 (6) (2016) e275-e275.
- [5] Boukai A.I., Bunimovich Y., Tahir-Kheli J., Yu J.-K., Goddard III W.A., Heath J.R., Silicon nanowires as efficient thermoelectric materials, Nature, 451 (7175) (2008) 168-171.
- [6] Yüzüak G.D., Çiçek M.M., Elerman Y., Yüzüak E., Enhancing the power factor of p-type BiSbTe films via deposited with/without Cr seed layer, Journal of Alloys and Compounds, 886 (2021) 161263.
- [7] Li C.W., Hong J., May A.F., Bansal D., Chi S., Hong T., Ehlers G., Delaire O., Orbitally driven giant phonon anharmonicity in SnSe, Nature Physics, 11 (12) (2015) 1063-1069.
- [8] Pei Y., Wang H., Snyder G.J., Band engineering of thermoelectric materials, Advanced Materials, 24 (46) (2012) 6125-6135.
- [9] Zhao L.D., Wu H.J., Hao S.Q., Wu C.I., Zhou X.Y., Biswas K., He J.Q., Hogan T.P., Uher C., Wolverton C., Dravid V.P., Kanatzidis M.G., All-scale hierarchical thermoelectrics: MgTe in PbTe facilitates valence band convergence and suppresses bipolar thermal transport for high performance, Energy & Environmental Science, 6 (11) (2013) 3346-3355.
- [10] Goncalves L.M., Couto C., Alpuim P., Rolo A.G., Völklein F., Correia J.H., Optimization of thermoelectric properties on Bi2Te3 thin films deposited by thermal co-evaporation, Thin Solid Films, 518 (10) (2010) 2816-2821.
- [11] Nuthongkum P., Sakdanuphab R., Horprathum M., Sakulkalavek A., [Bi]:[Te] Control, Structural and Thermoelectric Properties of Flexible BixTey Thin Films Prepared by RF Magnetron Sputtering at Different Sputtering Pressures, Journal of Electronic Materials, 46 (11), (2017), 6444-6450.
- [12] Wang X., He H., Wang N., Miao L., Effects of annealing temperature on thermoelectric properties of Bi2Te3 films prepared by co-sputtering, Applied Surface Science, 276 (2013) 539-542.
- [13] Kurokawa T., Mori R., Norimasa O., Chiba T., Eguchi R., Takashiri M., Influences of substrate types and heat treatment conditions on structural and thermoelectric properties of nanocrystalline Bi2Te3 thin films formed by DC magnetron sputtering, Vacuum, 179 (2020) 109535.
- [14] Lee C.W., Kim G.H., Choi J.W., An K.-S., Kim J.-S., Kim H., Lee Y.K., Improvement of thermoelectric properties of Bi2Te3 and Sb2Te3 films grown on graphene substrate, Physica Status Solidi (RRL)–Rapid Research Letters, 11 (6) (2017) 1700029.
- [15] Budnik A.V., Rogacheva E.I., Pinegin V.I., Sipatov A.Y., Fedorov A.G., Effect of initial bulk material composition on thermoelectric properties of Bi2Te3 thin films, Journal of Electronic Materials, 42 (7) (2013) 1324-1329.
- [16] Ahiska R., Mamur H., Uliş M., Termoelektrik modülün jeneratör olarak modellenmesi ve deneysel çalışması, Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi, 26 (4) (2011) 889-896.
- [17] Hayati M., Bhuiyan M.R.A., Korkmaz F., Nil M., A review on bismuth telluride (Bi2Te3) nanostructure for thermoelectric applications, Renewable and Sustainable Energy Reviews, 82 (2018) 4159-4169.
- [18] Yüzüak G.D., Özkan S., Yüzüak E., Unraveling energy consumption by using low-cost and reevaluated thermoelectric Thin Films, Turkish Journal of Physics, 44 (5) (2020) 442-449.
- [19] Rocha Liborio Tenorio H.C., Vieira D.A., De Souza C.P., Measurement of parameters and degradation of thermoelectric modules, IEEE Instrumentation & Measurement Magazine, 20(2) (2017) 13-19.
- [20]Zebarjadi M., Esfarjani K., Dresselhaus M.S., Ren Z.F., Chen G., Perspectives on thermoelectrics: from fundamentals to device applications, Energy & Environmental Science, 5 (1) (2012) 5147-5162.
- [21] He J., Tritt T.M., Advances in thermoelectric materials research: Looking back and moving forward, Science, 357 (6358) (2017) 1-9.
- [22] Shilpa M.K., Raheman M.A., Aabid A., Baig M., Veeresha R.K., Kudva N., A Systematic Review of Thermoelectric Peltier Devices: Applications and Limitations, FDMP-Fluid Dynamics & Materials Processing, 19 (1) (2023) 187–206.
- [23]Barako M.T., Park W., Marconnet A.M., Asheghi M., Goodson K.E., Thermal Cycling, Mechanical Degradation, and the Effective Figure of Merit of a Thermoelectric Module, Journal of Electronic Materials, 42 (3) (2013) 372–381.
- [24]Karri N.K., Mo C., Geometry optimization for structural reliability and performance of a thermoelectric generator, SN Applied Sciences, 1 (9) (2019) 1097.
- [25]Anandan P., Omprakash M., Azhagurajan M., Arivanandhan M., Rajan Babu D., Koyama T., Hayakawa Y., Tailoring bismuth telluride nanostructures using a scalable sintering process and their thermoelectric properties, Cryst.Eng.Comm., 16 (34) (2014) 7956-7962.
- [26]Kim C., Kim D.H., Han Y.S., Chung J.S., Park S.H., Him H., Fabrication of bismuth telluride nanoparticles using a chemical synthetic process and their thermoelectric evaluations, Powder technology, 214 (3) (2011) 463-468.
- [27] Zou P., Xu G., Wang S., Thermoelectric Properties of Nanocrystalline Bi2(Te1−xSex)3 Prepared by High-Pressure Sintering, Journal of Electronic Materials, 44 (6) (2015) 1592-1598.