1) Ag-Ni alloy
Ag-50Ni合金
2) Al-Ag alloy
Al-Ag合金
1.
The kinetic Monte Carlo method based on the Multi-States Ising Model,was applied to simulate the effect of microelements on the microstructural evolution of Al-Ag alloys during initial aging stage.
采用基于Multi-States Ising Model的Kinetic Monte Carlo算法,模拟研究了添加微量元素对Al-Ag合金时效初期微观结构的演变过程的影响。
2.
Taking into account the influence on the lattice constant from temperature,the valence electronic structures of GP zones of η-form in the Al-Ag alloy,and the interfacial energy between GP zones of η-form and matrix were calculated by using empirical electron theory in solid and molecules(EET) and the extension of Becker model.
考虑温度对晶格常数的影响,运用固体与分子经验电子理论,对Al-Ag合金的η型GP区的价电子结构进行计算;在此基础上,运用Becker推广模型,对该体系的η型GP区与基体之间的界面能进行预测。
3.
The valence electron structure of GP zone ? phase in Al-Ag alloy was calculated according to the “empirical electronic theory in solid”(EET), and the interface energy based on the information of the valence electron structure was calculated also.
运用固体经验电子理论,对Al-Ag合金GP区?相的价电子结构进行计算,并且在此基础上计算了GP区和基体的界面能。
3) Ag-C alloy
Ag-C合金
4) Cu-Ag alloy
Cu-Ag合金
1.
Strain strengthening of Cu-Ag alloy in situ filamentary composites;
Cu-Ag合金原位纤维复合材料的应变强化效应
2.
Effects of annealing and cold-working on properties of continually-unidirectionally solidified Cu-Ag alloy;
热处理和冷变形对连续定向凝固Cu-Ag合金性能的影响
3.
The Cu-Ag alloy in situ filamentary composites with different Ag contents were prepared.
制备了具有不同Ag含量的Cu-Ag合金及其原位纤维复合材料,增加Ag含量可以细化铸态组织和Ag纤维尺寸,增大合金的极限拉伸强度和电阻率。
5) Sn/Ag/alloy
Sn-Ag合金
6) Ag-Cr alloy
Ag-Cr合金
1.
Oxidation of Ag-Cr alloys prepared by powder metallurgy in 0.1 MPa O_2;
粉末冶金Ag-Cr合金在纯氧气中的氧化
2.
This scale structure is different from the mixed oxide structure of the Ag-Cr alloy with coarse grain sizes prepared by powder metallurgy, which is attributed to the large decrease in the alloy grain size, the rapid dissolution of the Cr-rich.
采用机械合金化方法制备了Cr含量为30%(质量分数)的两相颗粒极细的Ag-Cr合金,在700℃,800℃及0。
补充资料:Ni3Al基金属间化合物高温合金
Ni3Al基金属间化合物高温合金
Ni_(3)Al-base intermetallic compound superalloy
N一3AIJ一J旧shuJ一an huahewu goowen heJ一nNi3AI基金属间化合物高温合金(Ni3AI一baseintermetallie eompound superalloy)以Ni3AI相为基体的金属间化合物高温合金。Ni3AI作为高温合金材料中的强化相口)早已被人们所熟知。单晶Ni3AI有较好的室温塑性和加工性,但多晶Ni3AI在室温的塑性儿乎为零。1979年,日本和泉修等发现,添加微量硼可使Ni3AI韧化。硼强烈地偏聚于晶界,从而提高晶界的结合强度并使晶界区无序化,因此提高了晶界区塑性变形能力,使Ni3AI的室温拉伸伸长率可达50%以上。纯净N珠AI的室温、高温强度偏低,与高温合金相比需要进一步提高。固溶强化(见高温合金固溶强化)是提高强度的一条有效途径。Ni3AI可以固溶很多元素,其中以错和铅的强化效果最显著。美国橡树岭国家试验室已发展了一系列含铬、错、错等元素的Ni3AI基金属间化合物高温合金,具有良好的强度、塑性和高温抗氧化性。中国也对Ni3AI基合金进行了深入研究,并添加微量镁显著改善了热加工塑性。Ni3AI基合金可能是最先在工业上得到使用的金属间化合物高温合金之一,已制成各种部件在试用,如汽轮机和柴油机的耐热部件、高温模具、加热元件以及航空用的紧固件等。 〔邹敦叙)
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