稀有金属材料与工程
稀有金屬材料與工程
희유금속재료여공정
RARE METAL MATERIALS AND ENGINEERNG
2009年
z2期
1055-1059
,共5页
杨梅君%罗卫军%沈强%张联盟
楊梅君%囉衛軍%瀋彊%張聯盟
양매군%라위군%침강%장련맹
Mg_2Si%纳微米复合材料%热电性能
Mg_2Si%納微米複閤材料%熱電性能
Mg_2Si%납미미복합재료%열전성능
Mg_2Si%nanocomposites%thermoelectric properties
以平均晶粒尺寸约3μm及20 nm的Mg_2Si粉末为原料,采用放电等离子体烧结方法制备出不同纳米、微米含量的Mg_2Si纳微米复合块体材料,系统研究了纳微米结构对材料热电性能的影响.结果表明:随复合材料中纳米颗粒含量的增加,晶界散射增强,导致材料晶格热导率κ_p有明显降低;同时晶界势垒散射的增强也导致Seebeck系数α显著增加,电导率σ有一定程度的降低;综合Seebeck系数α、电导率σ、热导率κ的影响,在纳米颗粒含量为50%(质量分数,下同)、823 K时,获得最大热电优值达0.45,分别是未掺杂纳米相和完全纳米相Mg_2Si材料的1.5及1.1倍.纳微米复合结构的引入,可以获得性能更好的Mg_2Si热电材料.
以平均晶粒呎吋約3μm及20 nm的Mg_2Si粉末為原料,採用放電等離子體燒結方法製備齣不同納米、微米含量的Mg_2Si納微米複閤塊體材料,繫統研究瞭納微米結構對材料熱電性能的影響.結果錶明:隨複閤材料中納米顆粒含量的增加,晶界散射增彊,導緻材料晶格熱導率κ_p有明顯降低;同時晶界勢壘散射的增彊也導緻Seebeck繫數α顯著增加,電導率σ有一定程度的降低;綜閤Seebeck繫數α、電導率σ、熱導率κ的影響,在納米顆粒含量為50%(質量分數,下同)、823 K時,穫得最大熱電優值達0.45,分彆是未摻雜納米相和完全納米相Mg_2Si材料的1.5及1.1倍.納微米複閤結構的引入,可以穫得性能更好的Mg_2Si熱電材料.
이평균정립척촌약3μm급20 nm적Mg_2Si분말위원료,채용방전등리자체소결방법제비출불동납미、미미함량적Mg_2Si납미미복합괴체재료,계통연구료납미미결구대재료열전성능적영향.결과표명:수복합재료중납미과립함량적증가,정계산사증강,도치재료정격열도솔κ_p유명현강저;동시정계세루산사적증강야도치Seebeck계수α현저증가,전도솔σ유일정정도적강저;종합Seebeck계수α、전도솔σ、열도솔κ적영향,재납미과립함량위50%(질량분수,하동)、823 K시,획득최대열전우치체0.45,분별시미참잡납미상화완전납미상Mg_2Si재료적1.5급1.1배.납미미복합결구적인입,가이획득성능경호적Mg_2Si열전재료.
Mg_2Si nanocomposites were prepared by spark plasma sintering (SPS) of the mixture of nanoscale and microsized Mg_2Si powder obtained by mechanical milling and solid-state reaction, respectively. Microstructure analysis shows that the bulk materials are composed of nano- and micrograins. The increase of nanosized powders is effective in reducing thermal conductivity, electrical conductivity and increasing Seebeck coefficient α. Taking the thermal conductivity, Seebeck coefficient and electrical conductivity into consideration, a maximum dimensionless figure of merit of 0.45 is obtained for the nanocomposite with 50wt % nanopowder inclusions at 823 K, about 1.5 times and 1.1 times higher than that of samples with 0wt% and 100wt% nanopowder inclusions, respectively. It could be expected that the properties of the nanocomposites could be further improved by doping optimization.
