説明
<jats:title>Abstract</jats:title><jats:p>PbS shares several features with the other lead chalcogenides PbX (X: Te, Se), which are good thermoelectric materials. PbS has a potential advantage in that it is quite earth abundant and inexpensive. In this work we tune the transport properties in n‐type, single‐phase polycrystalline PbS<jats:sub>1‐x</jats:sub>Cl<jats:sub>x</jats:sub> (x ≤ 0.008) with different carrier densities. Lead chloride provides a nearly 100% efficient doping control up to 1.2 × 10<jats:sup>20</jats:sup> cm<jats:sup>−3</jats:sup>. The maximum <jats:italic>zT</jats:italic> achieved at 850 K is 0.7 with a predicted <jats:italic>zT</jats:italic> ∼ 1 at 1000 K. This is about twice as high as what was previously reported (∼0.4) for binary PbS. Compared with the other lead chalcogenides the higher effective mass and higher lattice thermal conductivity makes binary PbS an inferior thermoelectric material. However this study also predicts greater potential of <jats:italic>zT</jats:italic> improvement in PbS by material engineering such as alloying or nanostructuring compared to PbSe or PbTe. Considering their abundance and low cost, PbS based materials are quite competitive among the lead chalcogenides for thermoelectric applications.</jats:p>
収録刊行物
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- Advanced Energy Materials
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Advanced Energy Materials 3 (4), 488-495, 2012-11-07
Wiley