Er-Ba复合变质对Mg-2.5Si-4Zn铸造合金组织及性能的影响

镁合金中的强化相Mg₂Si可以显著提高合金的硬度、耐磨性，特别是耐高温蠕变性。但铸态过共晶Mg-Si合金中初生Mg₂Si棱角粗糙，共晶Mg₂Si具有复杂的汉字形态，会严重割裂合金基体。为了改善Mg-2.5Si-4Zn合金的性能，进行了添加Er/Er-Ba的变质实验，并通过光学显微镜（OM）、扫描电子显微镜（SEM）、能量色散光谱仪（EDS）和X射线衍射仪（XRD）研究了Er/Er-Ba对合金组织和Mg₂Si相的影响。利用计算机辅助电子加载拉伸试验机对力学性能进行了测试和分析。结果表明，在Mg-2.5Si-4Zn合金中加入0.6%（质量分数）的Er，其组织中的初生Mg₂Si从粗大的树枝状转变为规则的四方块状，而共晶Mg₂Si则从粗大的汉字状转变为更复杂的短棒状。随后加入0.8%的Ba后，初生Mg₂Si从规则的四边形块状进一步转变为带有沟槽和孔洞的不规则细小块状，共晶Mg₂Si在尺寸上细化效果显著，呈点线状弥散分布在合金基体中。当加入0.6%Er和0.8%Ba时，变质效果最佳。经Er-Ba复合变质的Mg-2.5Si-4Zn合金的力学性能得到显著改善，抗拉强度σ_b和伸长率δ分别提高到168 MPa和5.04%。     

Ca和Mn添加对铸态及热处理态Al-Mg-Si合金的微观组织、力学性能和导电性能影响

制备了Al-0.59Mg-0.54Si-X (X=0, 0.253Ca, 0.253Mn)合金来探究微量Ca、Mn添加对铸态、固溶态及时效态Al-0.59Mg-0.54Si-X合金的微观组织、力学性能及导电性能的影响。研究发现,Ca和Mn添加都显著细化了α-Al的晶粒尺寸。Ca能够诱导高密度的Mg₂Si和Al₂Ca颗粒在铸态α-Al晶粒中析出,使合金在铸态下具有最优的力学性能。固溶和时效处理会导致颗粒粗化并且偏聚在晶界,使合金的力学性能急剧下降,但其电导率却增加到了52.44%IACS。Mn添加使得晶界上的粗大β-Al₅FeSi杂质相转化成α-Al(FeMn)Si颗粒,并且诱导Mg₂Si和AlMn颗粒在铸态合金中析出。因此经过固溶和时效处理后的Al-0.59Mg-0.54Si-0.253Mn合金表现出最优的力学性能以及可接受的电导率。     

激光热喷涂Co30Cr8W1.6C3Ni1.4Si涂层在PAO+2.5%MoDTC油中摩擦学特性

为了提高TC4合金的耐磨性能,采用激光热喷涂技术在其表面制备了Co₃₀Cr₈W_1.6C₃Ni_1.4Si涂层。通过扫描电子显微镜（SEM）和X射线衍射（XRD）分析了涂层的形貌和物相,并通过摩擦磨损实验研究了涂层在PAO+2.5% MoDTC（质量分数）油中的磨损行为。结果表明,激光热喷涂的Co₃₀Cr₈W_1.6C₃Ni_1.4Si涂层主要由Ti、WC_1-x、CoO、Co₂Ti₄O和CoAl相组成,在涂层界面形成冶金结合。在激光功率为1000、1200和1400 W时所制备的涂层平均摩擦因数分别为0.151、0.120和0.171,其对应的磨损率分别为1.17×10^-6、1.33×10^-6和2.80×10^-6 mm³?N^-1?m^-1,磨损机理为磨粒磨损,其枝晶尺寸对降磨起主要作用。     

从吸附角度观察Mg-Ca合金中Mg2Ca和 α-Mg的氧化：DFT研究

基于DFT计算O₂在α-Mg（0001）和Mg₂Ca（0001）上的吸附过程,以探明Mg-Ca合金中的α-Mg和Mg₂Ca氧化机理。结果表明,在吸附过程中,O₂与α-Mg和Mg₂Ca有很强的相互作用,且均为化学吸附,但Mg₂Ca的吸附结构不如α-Mg的吸附结构稳定。在氧化过程中,O₂与α-Mg和Mg₂Ca中的Ca和Mg原子发生反应,形成Mg-Ca-O氧化膜,从而提高Mg-Ca合金的抗氧化性。但Mg₂Ca的吸附结构稳定性比α-Mg差,因此Mg₂Ca形成的氧化膜对基体的保护作用比α-Mg弱。     

离心铸造和热轧对Mg-10Gd-3Y-1Sn合金组织和机械性能的影响

采用离心铸造及热轧工艺制备Mg-10Gd-3Y-1Sn合金,利用X射线衍射、光学显微镜、扫描电子显微镜和拉伸试验对该合金的组织和力学性能进行了研究。结果表明：离心铸造Mg-10Gd-3Y-1Sn合金由α-Mg、Mg₂₄(Gd, Y)₅、Mg₂(Sn, Y)₃Gd₂和Mg₃(Gd, Y)相组成。随着离心半径和离心转速的增大,Mg-10Gd-3Y-1Sn合金的晶粒尺寸逐渐减小,抗拉伸强度逐渐增大。在700 r/min下制备的热轧试样在室温下极限抗拉伸强度为304 MPa,在300 ℃下极限抗拉伸强度为296 MPa。Mg₂₄(Gd, Y)₅、Mg₂(Sn, Y)₃Gd₂和Mg₃(Gd, Y)相具有优异的热稳定性,因而Mg-10Gd-3Y-1Sn合金具有优异的高温抗拉伸强度。     

铸态Mg-Li-Al-xSi合金微观组织和力学性能

本文通过真空熔炼炉在氩气保护下制备了Mg-9Li-3Al-xSi(x=0,0.1,0.5,1.0 wt%)合金。实验使用光学显微镜(OM),扫描电子显微镜(SEM),力学性能测试和X射线衍射(XRD)研究合金的微观组织和力学性能。实验结果表明：铸态Mg-9Li-3Al合金组织中主要由α-Mg、β-Li、Mg₁₇Al₁₂相组成。加入Si后,合金中出现了新相Mg₂Si,晶粒得到了明显细化;当合金中的Si含量过高时,α-Mg相粗化,且会在相界处出现块状和汉字状的Mg₂Si相。合金的强度随着Si含量的增加呈现先增加后降低的趋势,合金的延伸率随着Si含量的增加呈现逐渐降低的趋势。当合金中Si含量为0.1%时,抗拉强度达到最大值182.5MPa,延伸率为12.1%,相比未添加Si的Mg-9Li-3Al合金,抗拉强度提高了59.6%。     

长期时效N10276合金在CO2/H2S/Cl- 环境中的腐蚀行为

通过电化学阻抗与循环动电位极化的方法研究了在CO₂/Cl^-以及CO₂/H₂S/Cl^-溶液体系中、长期时效前后N10276合金的腐蚀机理。结果表明,阻抗弧的低频区间出现了一个不完整的容抗弧,并且随H₂S浓度的增加（10~100 μL/L）转变为Warburg阻抗,其主要原因是高含量H₂S相关吸附物。H₂S可以增加合金腐蚀速率。相比较而言,长期时效处理主要作用于合金点蚀的形成,其中,经过长期时效处理的奥氏体组织内存在大量的第二相（富含Mo与Ni的μ相）,而析出物周围的区域成为优先腐蚀区域,进而导致了N10276合金点蚀的发生。     

Al-15wt.%Mg2Si复合材料中二元相的研究

原位内生法制备Al-15wt%Mg₂Si复合材料,其中二元相成分的研究很少,本文通过XRD测试方法,定性和定量的分析材料中的相成分和相含量。利用Reflex模拟Al-Mg-Si系合金的XRD衍射图谱,并与XRD测试结果对比。利用CASTEP中基于密度泛函理论的第一性原理方法,对Al-Mg₂Si复合材料中的Mg₂Si相和Mg₁₇Al₁₂相的平衡晶格常数,热力学参数和弹性性质做了系统的研究,分析两相的稳定性和力学性能。XRD分析结果显示,Al-15wt%Mg₂Si复合材料中仅含有α-Al相和Mg₂Si相,且Mg₂Si相的质量分数为14.9wt.%。模拟与实验中,相同晶面指数的XRD标定值相差很小,实验值验证了模拟值的可靠性。模拟值证实Al-Mg₂Si复合材料中,理论上只形成α-Al相和Mg₂Si相。CASTEP计算结果表明,Al-Mg₂Si复合材料中的Mg₂Si相较Mg₁₇Al₁₂相易于形成,且稳定性较好。Mg₂Si相的弹性模量E,剪切模量G,体模量B均大于Mg₁₇Al₁₂相,Mg₂Si相的力学性能较好,但脆性较大,且塑性较差。     

微量Gd添加对Mg-8Zn-1Mn-3Sn合金组织转变及性能的影响

研究了微量Gd的添加对Mg-8Zn-1Mn-3Sn合金显微组织及性能的影响。结果表明,Mg-8Zn-1Mn-3Sn-xGd主要由α-Mg基体、MgZn₂、Mg₇Zn₃、Mg₂Sn相、MgSnGd相组成。MgSnGd相为高温相,在合金凝固过程中最先形成,改变了凝固过程,使晶界处半连续第二相转变为断网状。MgSnGd相与α-Mg基体存在共格位向关系,能作为异质形核核心细化合金晶粒。Mg-8Zn-1Mn-3Sn-0.5Gd合金的综合力学性能最佳,合金力学性能得到显著提高的机制为通过添加Gd元素细化晶粒组织、MgSnGd相钉扎晶界阻碍位错运动以及晶界第二相形貌转变。     

Ca-Y复合变质对高硅Mg-Si-Zn合金组织与性能的影响

为提高高硅Mg-Si-Zn合金的性能,实验通过调整Ca、Y变质剂的含量,研究在Ca变质、Ca-Y复合变质作用下高硅Mg-Si-Zn合金的凝固组织与性能。结果表明:在Mg-4Si-4Zn合金中加入Ca,可使合金凝固组织中初生Mg2Si相由粗大的枝晶形貌转变为细小的矩形块状形貌,共晶组织由粗大的汉字状转变为点棒状;当Ca加入量为0.7%时(质量分数)变质效果最为明显;当Ca加入量超过0.7%后,合金中会形成CaMgSi棒状相,这是Ca变质效果下降的一个主要原因。当合金中Ca加入量为0.7%时,再加入Y会将初生Mg_2Si相由规则平整形貌转变为带有沟壑孔洞的复杂形貌,而相的尺寸基本不发生改变,这使得经Ca-Y复合变质的Mg-4Si-4Zn合金的硬度显著高于Ca单一变质合金的,硬度提高超过10%。     

废旧锂离子电池中Li, Fe和V的回收及xLiFePO4-yLi3V2(PO4)3的制备

由于LiFePO_4和Li_3V_2(PO_4)_3材料的特征相近,制备方法类似,提供了一种从废旧LiFePO_4和Li_3V_2(PO_4)_3混合电池中回收Li、Fe和V,再制备xLiFePO_4-yLi_3V_2(PO_4)_3的方法。在空气气氛中600℃热处理1h后,去除粘结剂PVDF使活性物质与集流体分离。调节Li、Fe、V和P摩尔比,球磨、锻烧,配制不同比例的xLiFePO_4-yLi_3V_2(PO_4)_3(x:y=5:1,7:1,9:1)复合电极材料。表征了其形貌、结构和电化学性能,结果表明,回收制备的复合材料将同时具备LiFePO_4和Li_3V_2(PO_4)_3两种材料的电化学性能,能显著改善LiFePO_4的倍率性能。     

Synthesis of lanthanum carbonate nanoparticles via sonochemical method for preparation of lanthanum hydroxide and lanthanum oxide nanoparticles

Lanthanum carbonate nanoparticles were synthesized from the reaction of lanthanum acetate and Na₂CO₃ under sonication via sonochemical method. Lanthanum hydroxide nanoparticles were prepared by facial hydrothermal processing from the resulted product at 110 °C for 24 h. The role of surfactant, calcination temperature and sonication time were investigated on the morphology and particle size of the products. Products were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray photoelectron spectrum (XPS), and Fourier transform infrared (FT-IR) spectra. La₂O₃ nanoparticles were obtained by calcinations of the nanoparticles of lanthanum carbonate at 600 °C.     

LaSrCuO4粉体微结构对Ag/LSCO电接触材料性能的影响

以硝酸镧、硝酸铜、硝酸锶等为原料,分别采用固相法、溶胶-凝胶法和共沉淀法合成了不规则颗粒状(LSCO_g)、介孔状(LSCOm)和片层状(LSCOl)的LaSrCuO_4(LSCO)粉体。采用高能球磨并结合初压-初烧-热压工艺制备出Ag/LSCO电接触材料。利用X射线衍射(XRD)、扫描电镜(SEM)、金属电导率仪、维氏硬度计和电寿命试验机等对粉体形貌及电接触材料的物理和电学性能进行了表征。结果表明:与Ag/LSCO_(m)、Ag/LSCO_l材料相比,Ag/LSCO_(g)电接触材料表现出更加优异的物理性能,其电阻率为2.37μΩ·cm,硬度为800MPa,密度为9.32g/cm~3;但电学性能差异较小,其在AC220V12A开断状态下的燃弧能量为400 mJ、燃弧时间为23 ms,关合状态下的燃弧能量为1500 mJ,燃弧时间为68ms。Ag/LSCO电接触材料的主要失效形式是液滴喷溅,微裂纹和孔洞。     

Effects of Mo and Al Additions on the Sulfidation Behavior of 310 Stainless Steel

The high-temperature sulfidation behavior of 310stainless steel (310SS) with Mo and Al additions (up to10 at.%) was studied over the temperature range700-900°C in pure-sulfur vapor over the range of 10^-3 to 10^-1 atm. Thecorrosion kinetics followed the parabolic rate law inall cases and the sulfidation rates increased withincreasing temperature and sulfur pressure. Thesulfidation rates decreased with increasing Mo and Al contents and it wasfound that the addition of 10 at.% Mo resulted in themost pronounced reduction among the alloys studied. Thescales formed on 310SS with Mo additions were complex, consisting of an outer layer of ironsulfide (with dissolved Cr), (Fe,Ni)₉S₈, andCr₂S₃/Cr₃S₄(with dissolved Fe), and an inner heterophasic layer ofFe_1-xS,Cr₂S₃/Cr₃S₄,NiCr₂S₄,Fe_1.25Mo₆S_7.7, FeMo₂S₄, andMoS₂. The scales formed on 310SS with Mo andAl additions had a similar mixture as above, except thatAl_0.55Mo₂S₄ was alsoobserved in the inner layer. The formation ofMoS₂ andAl_0.55Mo₂S₄ partly blocked the transport of cations throughthe inner scale, resulting in the reduction of thesulfidation rates compared to 310SS.     

Effects of sulfur pressure on the sulfidation behavior of 310 stainless steel

High-temperature sulfidation behavior of 310 stainless steel was studied over the temperature range of 700–900°C above a pure sulfur pool with the sulfurvapor range of 10^–4–10^–1 atm. The corrosion kinetics followed the parabolic rate law in all cases. The corrosion rates increased with increasing temperature and sulfur pressure. The scales formed on 310 stainless steel were complex and multilayered. The outer scale consisted of iron sulfide (with dissolved Cr), (Fe, Ni)₉S₈ and chromium sulfides (Cr₂S₃ and Cr₃S₄ with dissolved Fe), while the inner layer was a heterophasic mixture of Cr₂S₃, Cr₃S₄, NiCr₂S₄, and Fe₁–_xS. Platinum markers were found to be located at the interface between the inner and outer scales, suggesting that the outer scale grew by the outward transport of cations (Fe, Ni, and Cr), and the inner scale grew by the inward transport of sulfur. The formation of Cr₂S₃, Cr₃S₄, and NiCr₂S₄ partly blocked the transport of iron through the inner scale, resulting in a reduction of the corrosion rates as compared with the results in the literature.     

The high-temperature corrosion behavior of Co-Nb alloys in mixed-gas atmospheres

The corrosion of Co-Nb alloys containing up to 30 wt.% Nb in H₂-H₂S-H₂O gas mixtures was studied over the temperature range of 600–800°C. The gas composition falls in the stability region of cobalt sulfide and Nb₂O₅ in the phase diagrams of the Co-O-S and Nb-O-S systems at all temperatures studied. Duplex scales, consisting of an outer layer of cobalt sulfide and a complex, heterophasic inner layer, were formed at all temperatures studied. In addition to cobalt sulfide and CoNb₃S₆, a small amount of NbO₂ was found in the inner layer. The reason for the formation of NbO₂ over that of Nb₂O₅ in the scale is that the outer sulfide scale lowers the oxygen activity within the scale into the NbO₂-stability region. Two-stage kinetics were observed for all alloys, including an initial irregular stage usually followed by a steady-state parabolic stage. The steady-state parabolic rate constants decreased with increasing amounts of Nb, except for Co-20Nb corroded at 700°C. Nearly identical kinetics were observed for Co-20Nb corroded at 600°C and 700°C. The presence of NbO₂ particles leads only to a limited decrease of the available cross-section area for the outward-diffusing metal ions. The activation energies for all alloys are similar and are in agreement with those obtained in a study of the sulfidation of the same alloys. The primary corrosion mechanism involves an outward Co transport.     

Effects of K2O-Li2O doping on surface and catalytic properties of Fe2O3/Cr2O3 system

The effects of K₂O and Li₂O-doping (0.5, 0.75 and 1.5 mol%) of Fe₂O₃/Cr₂O₃ system on its surface and the catalytic properties were investigated. Pure and differently doped solids were calcined in air at 400-600 °C. The formula of the un-doped calcined solid was 0.85Fe₂O₃:0.15Cr₂O₃. The techniques employed were TGA, DTA, XRD, N₂ adsorption at −196 °C and catalytic oxidation of CO oxidation by O₂ at 200-300 °C. The results revealed that DTA curves of pure mixed solids consisted of one endothermic peak and two exothermic peaks. Pure and doped mixed solids calcined at 400 °C are amorphous in nature and turned to α-Fe₂O₃ upon heating at 500 and 600 °C. K₂O and Li₂O doping conducted at 500 or 600 °C modified the degree of crystallinity and crystallite size of all phases present which consisted of a mixture of nanocrystalline α- and γ-Fe₂O₃ together with K₂FeO₄ and LiFe₅O₈ phases. However, the heavily Li₂O-doped sample consisted only of LiFe₅O₈ phase. The specific surface area of the system investigated decreased to an extent proportional to the amount of K₂O and Li₂O added. On the other hand, the catalytic activity was found to increase by increasing the amount of K₂O and Li₂O added. The maximum increase in the catalytic activity, expressed as the reaction rate constant (k) measured at 200 °C, attained 30.8% and 26.5% for K₂O and Li₂O doping, respectively. The doping process did not modify the activation energy of the catalyzed reaction but rather increased the concentration of the active sites without changing their energetic nature.     

Effect of Y2O3 additions on the plasticity of sintered Cr2O3

We have carried our constant strain-rate compression tests on polycrystalline Cr₂O₃ and Cr₂O₃ doped with 0.09 wt. % Y₂O₃ to establish whether there exists an effect of Y₂O₃ on the plasticity of Cr₂O₃. This study is motivated by previous work on the oxidation of alloys containing reactive-element additions. In that work, it has been observed that the addition of oxygen-active elements, such as Y to alloys that form Cr₂O₃ or Al₂O₃ oxide layers upon exposure at high temperature, strongly enhances the adhesion of the oxide layer to the base alloy as compared with alloys without reactive-element additions. We have found that at 1200°C (1) chromia exhibits limited plasticity at high temperatures, and (2) the presence of Y in the oxides does not enhance plasticity compared with addition-free oxides.     

改进型镁扩散法制备高临界电流密度MgB2超导体性能研究

本文采用一种改进型镁扩散法成功制备出密度达到1.95g/cm₃的MgB₂超导块材。论文研究了不同的热处理条件对MgB₂块材的超导转变温度(T_c)和临界电流密度(J_c)性能的影响。采用最佳热处理条件制备的MgB₂超导体T_c和J_c分别达到了38.1K和0.53MA/cm₂(10K,自场)。为了改进镁扩散法MgB₂超导体中弱的高场磁通钉扎性能,本文还研究了nano-Pr₆O₁₁和C掺杂对MgB₂超导体的临界电流密度和不可逆场(H_irr)的影响。结果表明C掺杂的MgB₂超导体临界电流密度在10K,6T下达到了10₄A/cm₂,该结果比未掺杂MgB₂超导体在同样条件下性能提高了两个量级,甚至比固态反应法制备的nano-C掺杂MgB₂超导体性能更好。利用该方法制备的nano-Pr₆O₁₁掺杂的MgB₂超导体在10K,2T下也比未掺杂样品J_c提高达9.4倍。根据大量的实验结果和理论分析我们提出基于改进型镁扩散法和化学掺杂,包括纳米粒子和C掺杂,很有可能是一种制备高性能MgB₂超导体非常有效的途径。     

High-temperature corrosion of Co-15Mo alloys containing ternary additions of Al in mixed-gas environments

The corrosion behavior of Co-15 at.% Mo alloys containing up to 20at.% Al in gaseous H ₂ -H ₂ O-H ₂ S mixtures was studied over the temperature range of 600–900°C. The corrosion kinetics of all alloys followed the parabolic rate law over the temperature range of interest. Corrosion resistance increased with increasing aluminum content. Complex scales formed on the alloys, consisting of an outer layer of cobalt sulfide and a heterophasic inner layer. Al ₂ O ₃ formed only at high temperatures in alloys having aluminum additions of 15at.% or more. The absence of Al ₂ O ₃ in some cases is due to the small volume fraction of the intermetallic phase CoAl in the alloys and the nature of the slow growth rate of Al ₂ O ₃.Improvement in corrosion resistance is attributed to the presence of a ternary sulfide, Al _0.55 Mo ₂ S ₄,and Al ₂ O ₃ in the inner layer.