Mikhail G. Lavrentev, Mikhail V. Voronov, Aleksey A. Ivanov, Viktoriya P. Panchenko, N. Tabachkova, Maksim K. Tapero, Ivan Yu. Yarkov
{"title":"Mechanical properties of medium-temperature thermoelectric materials based on tin and lead tellurides","authors":"Mikhail G. Lavrentev, Mikhail V. Voronov, Aleksey A. Ivanov, Viktoriya P. Panchenko, N. Tabachkova, Maksim K. Tapero, Ivan Yu. Yarkov","doi":"10.3897/j.moem.9.4.116423","DOIUrl":null,"url":null,"abstract":"The strength and thermoelectric properties of PbTe and Sn0.9Pb0.1Te medium-temperature polycrystalline specimens with p and n conductivity types, respectively, have been studied. The specimens have been produced using extrusion and spark plasma sintering. The strength parameters of the materials were studied using uniaxial compression at 20 to 500 °C. The structure of the materials was studied using X-ray diffraction and electron microscopy. The electrical conductivity and the Seebeck coefficient were measured simultaneously using the four-probe and differential methods. The temperature conductivity and the specific heat capacity were measured using the laser flash and differential scanning calorimetry methods.\n The PbTe and Sn0.9Pb0.1Te materials produced using extrusion and spark plasma sintering prove to be single-phase and have homogeneous compositions. For comparable synthesis methods, the dislocation density in the Sn0.9Pb0.1Te specimens is by an order of magnitude lower than in the PbTe ones.\n Study of the mechanical properties of n and p conductivity type specimens over a wide temperature range from 20 to 500 °C has shown that their deformation is plastic and has no traces of brittle fracture. For these plastic materials, the strength criterion has been accepted to be the arbitrary yield stress corresponding to the stress at a 0.2% deformation. The 20 °C yield stress of PbTe and Sn0.9Pb0.1Te is far higher for the specimens produced by extrusion. For all the test temperatures and synthesis methods the Sn0.9Pb0.1Te specimens have a higher strength than the PbTe ones.\n The PbTe and Sn0.9Pb0.1Te specimens produced by extrusion have better thermoelectric properties than the spark plasma sintered ones. The heat conductivity of the PbTe and Sn0.9Pb0.1Te specimens is almost the same regardless of compaction method.","PeriodicalId":18610,"journal":{"name":"Modern Electronic Materials","volume":"9 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2023-12-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Modern Electronic Materials","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3897/j.moem.9.4.116423","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
The strength and thermoelectric properties of PbTe and Sn0.9Pb0.1Te medium-temperature polycrystalline specimens with p and n conductivity types, respectively, have been studied. The specimens have been produced using extrusion and spark plasma sintering. The strength parameters of the materials were studied using uniaxial compression at 20 to 500 °C. The structure of the materials was studied using X-ray diffraction and electron microscopy. The electrical conductivity and the Seebeck coefficient were measured simultaneously using the four-probe and differential methods. The temperature conductivity and the specific heat capacity were measured using the laser flash and differential scanning calorimetry methods.
The PbTe and Sn0.9Pb0.1Te materials produced using extrusion and spark plasma sintering prove to be single-phase and have homogeneous compositions. For comparable synthesis methods, the dislocation density in the Sn0.9Pb0.1Te specimens is by an order of magnitude lower than in the PbTe ones.
Study of the mechanical properties of n and p conductivity type specimens over a wide temperature range from 20 to 500 °C has shown that their deformation is plastic and has no traces of brittle fracture. For these plastic materials, the strength criterion has been accepted to be the arbitrary yield stress corresponding to the stress at a 0.2% deformation. The 20 °C yield stress of PbTe and Sn0.9Pb0.1Te is far higher for the specimens produced by extrusion. For all the test temperatures and synthesis methods the Sn0.9Pb0.1Te specimens have a higher strength than the PbTe ones.
The PbTe and Sn0.9Pb0.1Te specimens produced by extrusion have better thermoelectric properties than the spark plasma sintered ones. The heat conductivity of the PbTe and Sn0.9Pb0.1Te specimens is almost the same regardless of compaction method.
研究了导电率分别为 p 和 n 的铅碲和锡 0.9Pb0.1Te 中温多晶试样的强度和热电性能。这些试样是通过挤压和火花等离子烧结工艺制成的。在 20 至 500 °C 的温度条件下,利用单轴压缩对材料的强度参数进行了研究。使用 X 射线衍射和电子显微镜研究了材料的结构。使用四探针法和差分法同时测量了电导率和塞贝克系数。温度传导性和比热容是用激光闪光法和差示扫描量热法测量的。使用挤压和火花等离子烧结法生产的铅碲和锡 0.9Pb0.1Te 材料被证明是单相的,并且具有均匀的成分。在合成方法可比的情况下,Sn0.9Pb0.1Te 试样的位错密度比 PbTe 试样低一个数量级。对 n 型和 p 型导电试样在 20 至 500 °C 宽温度范围内的机械性能研究表明,它们的变形是塑性的,没有脆性断裂的痕迹。对于这些塑性材料,强度标准被认为是任意屈服应力,相当于 0.2% 变形时的应力。对于挤压法生产的试样,碲化铋和碲化锡的 20 °C 屈服应力要高得多。在所有测试温度和合成方法下,Sn0.9Pb0.1Te 试样的强度都高于 PbTe 试样。挤压法生产的铅碲和锡 0.9Pb0.1Te 试样比火花等离子烧结法生产的试样具有更好的热电特性。无论采用哪种压制方法,铅碲和锡 0.9Pb0.1Te 试样的热传导率几乎相同。