Nanophase oxalate precursors of thermoelectric CoSb3 by controlled coprecipitation predicted by thermodynamic modeling

[Display omitted] •CoSb3 nanoparticles were synthesized by thermodynamic modeling.•Highly monodispersed precursors of CoSb3 nanoparticles were coprecipitated.•Method to synthesized nanoparticle with complex composition was established.•The ZT of coprecipitated CoSb3 shows twice higher than the ball...

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Published inAdvanced powder technology : the international journal of the Society of Powder Technology, Japan Vol. 27; no. 2; pp. 773 - 778
Main Authors Kim, Se-Hoon, Kim, Min Cheol, Kim, Min-Suk, Ahn, Jong Pil, Moon, Kyoung-Sook, Koo, Sang Mo, Tafti, Mohsen Y., Park, Joo-Seok, Toprak, Muhammet S., Lee, Byung-Ha, Kim, Do Kyung
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.03.2016
Subjects
Co-precipitation
CoSb3
Thermodynamic modeling
Thermoelectric
Thermodynamic modeling
Thermoelectric
CoSb3
Co-precipitation
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Abstract [Display omitted] •CoSb3 nanoparticles were synthesized by thermodynamic modeling.•Highly monodispersed precursors of CoSb3 nanoparticles were coprecipitated.•Method to synthesized nanoparticle with complex composition was established.•The ZT of coprecipitated CoSb3 shows twice higher than the ball milled one. The precursors for the formation of thermoelectric skutterudite CoSb3 nanoparticles are predicted by thermodynamic modeling of the complex chemical species. Based on the results, equimolar mixture of CoC2O4·2H2O and Sb(C2O4)OH are successively co-precipitated under controlled conditions of pH=2.7 and concentration of reactants. The as synthesized powder was decomposed at 350°C to remove the organic molecules and further reduced to CoSb3 phase by heating at 530°C under hydrogen flow. The obtained powder was consolidated by spark plasma sintering (SPS). CoSb3 prepared by controlled chemical co-precipitation has p-type behavior with a positive sign of the Seebeck coefficient. TE transport properties were measured, which revealed that the Seebeck coefficient increased 2.5 times with increasing the temperature and it is lower than the ball milled CoSb3. Thermal conductivity of sintered CoSb3 at 773K starts from 0.06W/cmK at room temperature and decreases to 0.04W/cmK at 700K, which is lower than the bulk counterpart. The ZT of coprecipitated CoSb3 and SPS consolidated at 773K shows 2 times higher than the ball milled one.
AbstractList The precursors for the formation of thermoelectric skutterudite CoSb3 nanoparticles are predicted by thermodynamic modeling of the complex chemical species. Based on the results, equimolar mixture of CoC2O4 center dot 2H(2)O and Sb(C2O4) OH are successively co-precipitated under controlled conditions of pH = 2.7 and concentration of reactants. The as synthesized powder was decomposed at 350 degrees C to remove the organic molecules and further reduced to CoSb3 phase by heating at 530 degrees C under hydrogen flow. The obtained powder was consolidated by spark plasma sintering (SPS). CoSb3 prepared by controlled chemical co-precipitation has p-type behavior with a positive sign of the Seebeck coefficient. TE transport properties were measured, which revealed that the Seebeck coefficient increased 2.5 times with increasing the temperature and it is lower than the ball milled CoSb3. Thermal conductivity of sintered CoSb3 at 773 K starts from 0.06 W/cm K at room temperature and decreases to 0.04 W/cm K at 700 K, which is lower than the bulk counterpart. The ZT of coprecipitated CoSb3 and SPS consolidated at 773 K shows 2 times higher than the ball milled one. (C) 2016 The Society of Powder Technology Japan. Published by Elsevier B.V. and The Society of Powder Technology Japan. All rights reserved.
[Display omitted] •CoSb3 nanoparticles were synthesized by thermodynamic modeling.•Highly monodispersed precursors of CoSb3 nanoparticles were coprecipitated.•Method to synthesized nanoparticle with complex composition was established.•The ZT of coprecipitated CoSb3 shows twice higher than the ball milled one. The precursors for the formation of thermoelectric skutterudite CoSb3 nanoparticles are predicted by thermodynamic modeling of the complex chemical species. Based on the results, equimolar mixture of CoC2O4·2H2O and Sb(C2O4)OH are successively co-precipitated under controlled conditions of pH=2.7 and concentration of reactants. The as synthesized powder was decomposed at 350°C to remove the organic molecules and further reduced to CoSb3 phase by heating at 530°C under hydrogen flow. The obtained powder was consolidated by spark plasma sintering (SPS). CoSb3 prepared by controlled chemical co-precipitation has p-type behavior with a positive sign of the Seebeck coefficient. TE transport properties were measured, which revealed that the Seebeck coefficient increased 2.5 times with increasing the temperature and it is lower than the ball milled CoSb3. Thermal conductivity of sintered CoSb3 at 773K starts from 0.06W/cmK at room temperature and decreases to 0.04W/cmK at 700K, which is lower than the bulk counterpart. The ZT of coprecipitated CoSb3 and SPS consolidated at 773K shows 2 times higher than the ball milled one.
Author Ahn, Jong Pil
Koo, Sang Mo
Toprak, Muhammet S.
Park, Joo-Seok
Lee, Byung-Ha
Tafti, Mohsen Y.
Kim, Do Kyung
Kim, Min-Suk
Moon, Kyoung-Sook
Kim, Min Cheol
Kim, Se-Hoon
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Snippet [Display omitted] •CoSb3 nanoparticles were synthesized by thermodynamic modeling.•Highly monodispersed precursors of CoSb3 nanoparticles were...
The precursors for the formation of thermoelectric skutterudite CoSb3 nanoparticles are predicted by thermodynamic modeling of the complex chemical species....
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SubjectTerms Co-precipitation
CoSb3
Thermodynamic modeling
Thermoelectric
Title Nanophase oxalate precursors of thermoelectric CoSb3 by controlled coprecipitation predicted by thermodynamic modeling
URI https://dx.doi.org/10.1016/j.apt.2016.03.006
https://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-186005
Volume 27
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