Keng Fu Hsu scite author profile

The conversion of heat to electricity by thermoelectric devices may play a key role in the future for energy production and utilization. However, in order to meet that role, more efficient thermoelectric materials are needed that are suitable for high-temperature applications. We show that the material system AgPb(m)SbTe(2+m) may be suitable for this purpose. With m = 10 and 18 and doped appropriately, n-type semiconductors can be produced that exhibit a high thermoelectric figure of merit material ZTmax of approximately 2.2 at 800 kelvin. In the temperature range 600 to 900 kelvin, the AgPb(m)SbTe(2+m) material is expected to outperform all reported bulk thermoelectrics, thereby earmarking it as a material system for potential use in efficient thermoelectric power generation from heat sources.

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Cubic AgPb_mSbTe_2+m: Bulk Thermoelectric Materials with High Figure of Merit.

Hsu¹,

Loo²,

Guo³

et al. 2004

ChemInform

586

782

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Energy conversion Energy conversion V 1650Cubic AgPb m SbTe 2+m : Bulk Thermoelectric Materials with High Figure of Merit.-The title materials with m = 10 and 18 are n-type semiconductors exhibiting a high thermoelectric figure of merit of about 2.2 at 800 K. They are expected to outperform all reported bulk thermoelectrics in the temperature range 600-900 K and to find applications in thermoelectric power generation from heat sources, such as vehicle exhaust, coal-burning installations, or electric power utilities. With a hot source of 900 K and a temperature difference of about 500 K, a conversion efficiency of more than 18% may be achieved. -(HSU, K. F.; LOO, S.; GUO, F.; CHEN, W.; DYCK, J. S.; UHER, C.; HOGAN, T.; POLYCHRONIADIS, E. K.; KANATZIDIS*, M. G.;

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Nanostructuring, Compositional Fluctuations, and Atomic Ordering in the Thermoelectric Materials AgPb_mSbTe₂₊_m. The Myth of Solid Solutions

et al. 2005

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The nature of the thermoelectric materials Ag(1-x)Pb(m)SbTe(m+2) or LAST-m materials (LAST for Lead Antimony Silver Tellurium) with different m values at the atomic as well as nanoscale was studied with powder/single-crystal X-ray diffraction, electron diffraction, and high-resolution transmission electron microscopy. Powder diffraction patterns of different members (m = 0, 6, 12, 18, infinity) are consistent with pure phases crystallizing in the NaCl-structure-type (Fmm) and the proposition that the LAST family behaved as solid solutions between the PbTe and AgSbTe2 compounds. However, electron diffraction and high resolution transmission electron microscopy studies suggest the LAST phases are inhomogeneous at the nanoscale with at least two coexisting sets of well-defined phases. The minority phase which is richer in Ag and Sb is on the nanosized length scale, and it is endotaxially embedded in the majority phase which is poorer in Ag and Sb. Moreover, within each nanodomain we observe extensive long range ordering of Ag, Pb, and Sb atoms. The long range ordering can be confirmed by single crystal X-ray diffraction studies. Indeed, data collections of five different single crystals were successfully refined in space groups of lower symmetry than Fmm including P4/mmm and Rm. The results reported here provide experimental evidence for a conceptual basis that could be employed when designing high performance thermoelectric materials and dispel the decades long belief that the systems (AgSbTe2)(1-x)(PbTe)x are solid solutions.

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Keng Fu Hsu

Cubic AgPb _m SbTe ₂₊ _m : Bulk Thermoelectric Materials with High Figure of Merit

Cubic AgPb_mSbTe_2+m: Bulk Thermoelectric Materials with High Figure of Merit.

Nanostructuring, Compositional Fluctuations, and Atomic Ordering in the Thermoelectric Materials AgPb_mSbTe₂₊_m. The Myth of Solid Solutions

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Keng Fu Hsu

Cubic AgPb m SbTe 2+ m : Bulk Thermoelectric Materials with High Figure of Merit

Cubic AgPbmSbTe2+m: Bulk Thermoelectric Materials with High Figure of Merit.

Nanostructuring, Compositional Fluctuations, and Atomic Ordering in the Thermoelectric Materials AgPbmSbTe2+m. The Myth of Solid Solutions

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Product

Resources

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Cubic AgPb _m SbTe ₂₊ _m : Bulk Thermoelectric Materials with High Figure of Merit

Cubic AgPb_mSbTe_2+m: Bulk Thermoelectric Materials with High Figure of Merit.

Nanostructuring, Compositional Fluctuations, and Atomic Ordering in the Thermoelectric Materials AgPb_mSbTe₂₊_m. The Myth of Solid Solutions