Enhanced thermoelectric performance of heavy-metals (M: Ba, Pb) doped misfit-layered ceramics: (Ca2−xMxCoO3)0.62 (CoO2)

[Display omitted] •A sol–gel processing of (Ca2−xMxCoO3)0.62 (CoO2); (M: Ba and Pb), followed by SPS.•XRD confirmed the substitution of Ba and Pb into lattice at the Ca site.•The Pb-doped specimen exhibited a larger ZT value of ∼0.27at 1000K.•The Ba-doped specimen exhibited a largest ZT value of ∼0....

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Bibliographic Details
Published in:Energy conversion and management 2014-07, Vol.83, p.35-41
Main Authors: Butt, Sajid, Ren, Yaoyu, Farooq, Muhammad Umer, Zhan, Bin, Sagar, Rizwan Ur Rahman, Lin, Yuanhua, Nan, Ce-Wen
Format: Article
Language:English
Subjects:
(Ca2CoO3)0.62 (CoO2)
Applied sciences
Energy
Exact sciences and technology
Layered ceramic
SPS
Thermoelectric
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Summary:[Display omitted] •A sol–gel processing of (Ca2−xMxCoO3)0.62 (CoO2); (M: Ba and Pb), followed by SPS.•XRD confirmed the substitution of Ba and Pb into lattice at the Ca site.•The Pb-doped specimen exhibited a larger ZT value of ∼0.27at 1000K.•The Ba-doped specimen exhibited a largest ZT value of ∼0.33 at 1000K.•The highest ZT value is about 2 times of that of un-doped specimen. We present the temperature dependent thermoelectric properties of polycrystalline misfit-layered ceramics; (Ca2−xMxCoO3)0.62 (CoO2), (M: Ba and Pb, x=0, 0.1, 0.2), fabricated by sol–gel method followed by spark plasma sintering technique. The X-ray diffraction results confirmed the substitution of Ba and Pb in the lattice of (Ca2CoO3)0.62 (CoO2) at Ca-site. An improved grain-alignment was observed at small scale with Ba-doping, which helped increasing the electrical conductivity but for the Pb-doped specimens, the electrical conductivity was suppressed by catastrophic grain-alignment. The bivalent metallic-doping induced a spin-entropy enhancement which resulted in an enhanced thermopower. For Ba-doped specimens, the simultaneous increase in the electrical conductivity and the thermopower resulted in an increased power factor exhibiting the highest value of 527μW/mK2. On the other hand, Pb-doping increased the thermopower but on the expense of electrical conductivity. Although, Pb-doping decreased the electrical conductivity but on the other hand, the enhanced thermopower and the suppressed thermal conductivity were sufficient for achieving ZT value higher than that of pure (Ca2CoO3)0.62 (CoO2). Among all the pure and doped samples, the highest ZT value of ∼0.33 at 1000K was achieved by Ba-doping which is about 100% higher than that of the pure (Ca2CoO3)0.62 (CoO2).
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2014.03.048