Spray Solution Combustion Synthesis of In-Doped ZnO: The Fuel Effect on Microstructure and Thermoelectric Properties

IF 0.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY International Journal of Self-Propagating High-Temperature Synthesis Pub Date : 2024-09-06 DOI:10.3103/S1061386224700171

Zh. S. Yermekova, E. V. Chernyshova, S. S. Yurlov, S. N. Yudin

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Abstract

ZnO is an earth abundant, safe, environmentally friendly, and relatively inexpensive resource for the application in the manufacturing of thermoelectric materials. In this work hollow spherical particles of Zn_0.995In_0.005O produced by the spray solution combustion synthesis (SSCS) with the stochiometric (φ₁) and excessive (φ₃) amount of glycine fuel were sintered at 900°C by the spark plasma sintering technique and thermoelectric properties of sintered Sφ₁ and Sφ₃ materials was measured. The best thermoelectric figure of merit zT ∼ 0.08 at 1050 K obtained for the materials produced at stoichiometric amount of fuel (φ₁). It was shown that lower amount of fuel (φ₁) used during the synthesis favors formation of porous and less textured structure which exhibits better thermoelectrical properties. The Lotgering factor (LF) calculated from the intensities of XRD (002) peaks was 0.65 for Sφ₃ sample, whereas for Sφ₁ sample LF (002) = 0.08. The average pore size of sintered Sφ₁ and Sφ₃ materials was around 200 nm. The total porosity was about 5–8% for Sφ₁ and 2–3% for Sφ₃ material.

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喷雾溶液燃烧合成掺杂氧化锌：燃料对微观结构和热电特性的影响

摘要氧化锌是一种资源丰富、安全、环保且价格相对低廉的热电材料。本研究采用火花等离子体烧结技术，在 900°C 温度下烧结了喷射溶液燃烧合成法（SSCS）制备的Zn0.995In0.005O空心球形颗粒，并测量了烧结的Sφ1和Sφ3材料的热电性能。在 1050 K 时，以燃料的化学计量（φ1）生产的材料获得了最佳热电特性 zT ∼ 0.08。结果表明，在合成过程中使用较低的燃料量（φ1）有利于形成多孔和纹理较少的结构，从而表现出更好的热电特性。根据 XRD (002) 峰的强度计算得出，Sφ3 样品的 LF (002) = 0.65，而 Sφ1 样品的 LF (002) = 0.08。烧结 Sφ1 和 Sφ3 材料的平均孔径约为 200 nm。Sφ1 材料的总孔隙率约为 5-8%，Sφ3 材料的总孔隙率约为 2-3%。

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来源期刊

International Journal of Self-Propagating High-Temperature Synthesis MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

1.00

自引率

33.30%

发文量

期刊介绍： International Journal of Self-Propagating High-Temperature Synthesis is an international journal covering a wide range of topics concerned with self-propagating high-temperature synthesis (SHS), the process for the production of advanced materials based on solid-state combustion utilizing internally generated chemical energy. Subjects range from the fundamentals of SHS processes, chemistry and technology of SHS products and advanced materials to problems concerned with related fields, such as the kinetics and thermodynamics of high-temperature chemical reactions, combustion theory, macroscopic kinetics of nonisothermic processes, etc. The journal is intended to provide a wide-ranging exchange of research results and a better understanding of developmental and innovative trends in SHS science and applications.