Srinivasa R. Popuri scite author profile

The introduction of A-site vacancies in SrTiO 3 results in a glass-like thermal conductivity while Nb substituted samples maintain good electrical conductivity. This unexpected result brings SrTiO 3 one step closer to being a high-performing phonon-glass electron-crystal thermoelectric material.Thermoelectric waste heat recovery is widely expected to be an important component of a sustainable energy future. 1 However, affordable and relatively high-performance materials are lacking. Metal oxides are good candidates because of their abundance, low toxicity, and stability at high temperatures. 2 In addition, metal oxides are used in multilayer capacitors and the infrastructure for large scale device production exists. 3 SrTiO 3 is among the most promising n-type materials because it has the unusual combination (for an oxide) of good electrical conduction (s) and a high Seebeck coefficient (S), yielding power factors S 2 s # 3.5 mW m À1 K À2 in single crystals and epitaxial lms. 4,5 Unfortunately, the overall performance is compromised by a large thermal conductivity k ¼ 12-6 W m À1 K À1 for undoped SrTiO 3 (Fig. 1), 6 which reduces the thermoelectric gure of merit, ZT ¼ (S 2 s/k)T, where T is the absolute temperature. Outstanding thermoelectric materials generally have phononglass and electron-crystal (PGEC) properties, 7 meaning that the electronic transport is characteristic of a crystalline solid, while the k is low and resembles that of a glass. The main focus in the optimisation of SrTiO 3 has therefore been on the reduction of k, which consists of a large lattice contribution (k lat ) and a small electronic component (k el ¼ sLT; L is the Lorenz number). One approach to reduce k lat is to introduce point defects within the perovskite structure. This is for example used in Sr 1Àx La x TiO 3Àd (0 # x # 0.15) and SrTi 1Ày Nb y O 3Àd (0 # y # 0.2) and results in k lat z 3 W m À1 K À1 at 1073 K and a maximum ZT ¼ 0.35 at 1073 K. 5 However, to achieve ZT ¼ 1, a much more substantial reduction to k ¼ 1-2 W m À1 K À1 is needed. One drawback of La 3+ and Nb 4+ substitution is that the conicting requirements of charge carrier doping limit x, y # 0.2. However, even for Sr 1Àx Eu x Ti 0.8 Nb 0.2 O 3Àd with Sr 2+ /Eu 2+ mixtures (0 # x # 1), k was not reduced below $3 W m À1 K À1 for x ¼ 0.5 at 1000 K. 8 Recently, perovskites with A-site vacancies have started to generate attention. Promising S 2 s values and low k were reported in A-site and oxygen decient Sr 1Àx Pr 0.67x TiO 3Àd and Sr 1Àx Ti 0.8 Nb 0.2 O 3Àd , 9 while reductions in k were also observed in Ca 1Àx Nd 0.67x MnO 3Àd perovskites. 10 Here, we report a systematic investigation of the A-site decient Sr 1Àx La 0.67x , 0.33x Ti 1Ày Nb y O 3Àd perovskites. In order to separate the impact of A-site vacancies from oxygen defects we rst prepared the electrically insulating oxygen stoichiometric Sr 1Àx La 0.67x , 0.33x TiO 3 series and measured its thermal conductivity. ‡ Compositions with x ¼ 0, 0.4 and 0.8 were synthesised using standard solid state reactions...

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Structural changes in thermoelectric SnSe at high pressures

Loa

Husband

Downie

et al. 2015

J. Phys.: Condens. Matter

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Abstract. The crystal structure of the thermoelectric material tin selenide has been investigated with angle-dispersive synchrotron x-ray powder diffraction under hydrostatic pressure up to 27 GPa. With increasing pressure, a continuous evolution of the crystal structure from the GeS type to the higher-symmetry TlI type was observed, with a critical pressure of 10.5(3) GPa. The orthorhombic high-pressure modification, β -SnSe, is closely related to the pseudo-tetragonal high-temperature modification at ambient pressure. The similarity between the changes of the crystal structure at elevated temperatures and at high pressures suggests the possibility that strained thin films of SnSe may provide a route to overcoming the problem of the limited thermal stability of β-SnSe at high temperatures.

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Rapid Hydrothermal Synthesis of VO₂ (B) and Its Conversion to Thermochromic VO₂ (M1)

et al. 2013

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The present study provides a rapid way to obtain VO2 (B) under economical and environmentally friendly conditions. VO2 (B) is one of the well-known polymorphs of vanadium dioxide and is a promising cathode material for aqueous lithium ion batteries. VO2 (B) was successfully synthesized by rapid single-step hydrothermal process using V2O5 and citric acid as precursors. The present study shows that phase-pure VO2 (B) polytype can be easily obtained at 180 °C for 2 h and 220 °C for 1 h, that is, the lowest combination of temperature and duration reported so far. The obtained VO2 (B) is characterized by X-ray powder diffraction, high-resolution scanning electron microscopy, and Fourier transform infrared spectroscopy. In addition, we present an indirect way to obtain VO2 (M1) by annealing VO2 (B) under vacuum for 1 h.

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