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S.V. Gnedenkov A.G. Zavidnaya V.S. Egorkin A. Yerokhin A. Matthews 《Surface & coatings technology》2010,204(14):2316-1997
Protective surface layers with high corrosion resistance (Rp = 3.3·105 ohm cm2) and significant microhardness (H = 4.8 GPa), as compared to the substrate material, were obtained on MA8 magnesium alloy by bipolar Plasma Electrolytic Oxidation (PEO) in a silicate-fluoride electrolyte. The phase and elemental composition and morphology of the coatings were investigated. It was found that the application of the bipolar PEO mode enables one to synthesise on the alloy's surface a high-temperature phase of magnesium silicate, forsterite (Mg2SiO4) having good anticorrosion and mechanical properties. 相似文献
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为了提高氢化态Mg-Mn复合物的水反应性能,采用改变反应水溶液pH值和在水溶液中加入不同助剂的方法,通过测量反应过程中不同时刻产生的氢气量对助剂在水反应中的作用进行表征,利用SEM和XRD等测试手段对反应产物进行表征和测试,对反应机理进行分析。结果表明:改变反应溶液的pH值对反应程度及放氢速率的影响不大,且pH值越大,越不利于反应的进行;在溶液中添加助剂焦磷酸钾、六偏磷酸钠、羟基乙叉二膦酸(HEDP)对提高氢化态Mg-Mn复合物的放氢速率有显著促进作用;相比之下,应采用添加磷酸盐助剂的方法来改善氢化态Mg-Mn复合物水反应性能。 相似文献
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采用普通纯镁为原料制备了Mg-Mn牺牲阳极,探讨了水淬温度和时间对镁合金牺牲阳极的电化学性能和晶粒大小的影响。结果表明,在30℃的水中水淬4分钟后,得到的镁合金牺牲阳极的晶粒相对较小且电流效率相对较高。 相似文献
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真空硅热同步还原制备镁锰研究 总被引:1,自引:1,他引:0
阐述锰在镁合金中的作用以及镁锰合金的性能、应用与制备.为了提高镁锰合金中的含锰量,制备新型镁合金及南含锰量Mg - Mn中间合金,分析富锰渣硅热还原的基本原理,提出真空硅热还原制备镁锰合金的新方法.通过热力学分析真空硅热同步还原MgO、MnO,其平衡蒸汽压关系是:Mn的平衡蒸汽压>Mg的平衡蒸汽压>系统压强;同步还原条件是:P系≤102 Pa,T还≥1517K;还原温度为1550K时,同步固化冷凝温度T<922K.研究设计了真空熔融及热还原设备用于实验研究真空硅热同步还原制备镁锰. 相似文献
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A series of nano-sized particles of Mn1−xMgxFe2O4 (x = 0.0, 0.1, 0.2 and 0.25) have been synthesized by co-precipitation method. The effect of Mg-substitution on structural and dielectric properties is reported in this paper. X-ray diffraction analysis for both nanosize and bulk samples revealed the nanocrystalline nature in the prepared ferrite samples. The crystallite size increases from 3-6 nm in nanosamples to 63.9-85.5 nm in bulk samples. The dielectric properties for all the samples have been studied as a function of frequency in the range 10-105 Hz at different temperatures. Dielectric properties such as dielectric constant (?′) dielectric loss (?″), dielectric loss tangent (tan δ) and ac conductivity have been studied for the investigated samples as a function of frequency. The data indicated that, the dielectric constant and the loss factor values of our former are ten orders of magnitude than those of the later. The low dielectric behavior makes ferrite materials useful in high frequency applications. 相似文献
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