Thermal and thermoelectric properties of zinc oxide ceramics alloyed with metals

IF 0.2 Q4 FORESTRY
A. Pashkevich, A. Fedotov, E. N. Poddenezhny, L. Bliznyuk, V. Khovaylo, V. Fedotova, A. A. Kharchanko
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Abstract

The paper studies the thermal, electrical and thermoelectric properties of ZnO–MexOy ceramics with 1 ≤ x, y ≤ 3, where Me = Al, Co, Fe, Ni, Ti. The samples were made on the basis of ceramic sintering technology of powder mixtures of two or more oxides in an open atmosphere with variations in temperature and duration of annealing. Structural and phase studies of ceramics indicate that the addition of powders of MexOy alloying agents to ZnO powder with a wurtzite structure after the synthesis process leads to the release of secondary phases such as Znx(Me)yO4 spinels and a 4-fold increase in the porosity of the resulting ceramics. Studies of thermal conductivity at room temperature indicate the predominance of the lattice contribution. The decrease in thermal conductivity during doping is due to an increase in phonon scattering due to the influence of the following factors: (1) the size factor when replacing zinc ions in the ZnO (wurtzite) crystal lattice with metal ions from the added MexOy oxides; (2) the formation of defects – point, grain boundaries (microstructure grinding); (3) increase in porosity (decrease in density); and (4) formation of additional phase particles (such as spinels Znx(Mе)yO4). The effect of these factors in the substitution of zinc ions with metals (Co, Al, Ti, Ni, Fe) leads to an increase in the thermoelectric Q-factor of ZT by 4 orders of magnitude (due to a decrease in electrical resistivity and thermal conductivity with a relatively small decrease in the coefficient of thermal EMF). The reason for the decrease in electrical resistance is the more uniform redistribution of alloying metal ions in the wurtzite lattice, resulting in an increase in the number of donor centers, formed with an increase in the duration of annealing.
金属合金氧化锌陶瓷的热电性能
本文研究了1≤x, y≤3,其中Me = Al, Co, Fe, Ni, Ti的ZnO-MexOy陶瓷的热学、电学和热电性能。样品是基于陶瓷烧结技术,由两种或两种以上氧化物的粉末混合物在开放气氛中,随温度和退火时间的变化而制成的。陶瓷的结构和物相研究表明,在合成过程后,在纤锌矿结构的ZnO粉末中加入MexOy合金剂粉末,导致Znx(Me)yO4尖晶石等次生相的释放,并使陶瓷的孔隙率提高了4倍。室温下的热导率研究表明晶格的贡献占主导地位。掺杂过程中导热系数的降低是由于以下因素的影响导致声子散射的增加:(1)用添加的MexOy氧化物中的金属离子取代ZnO(纤锌矿)晶格中的锌离子时的尺寸因素;(2)形成缺陷——点、晶界(微结构磨削);(3)孔隙度增加(密度降低);(4)形成附加相粒子(如尖晶石Znx(m_) y4)。这些因素对金属(Co, Al, Ti, Ni, Fe)取代锌离子的影响导致ZT的热电q因子增加了4个数量级(由于电阻率和导热系数的降低而热电动势系数的降低相对较小)。电阻降低的原因是合金金属离子在纤锌矿晶格中的再分布更加均匀,导致施主中心数量增加,这是随着退火时间的延长而形成的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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