Nanoindentation response analysis of TiN-Cu coating deposited by magnetron sputtering

To investigate the change of the mechanical properties of soft metals doped PVD(Physical Vapor Deposition)coatings after the migration of soft metal to the surface, TiN-Cu coating was deposited on Si(100) by magnetron sputtering. The microstructure and mechanical properties at room temperature and after vacuum heat treatment at 300 ℃ were investigated. The results showed that the grains were clustered and the microstructure was porous for TiN-Cu coating at room temperature, while many micro-and nano-sized Cu particles were observed on the surface after vacuum heat treatment at 300 ℃. The elastic properties of the TiN-Cu coating after vacuum heat treatment at 300℃ degraded compared with that at room temperature. The hardness and elasticity modulus of TiN-Cu coating kept constant(3.7 GPa and 125.0 GPa, respectively) with the increase of nano-indentation depth, while the hardness and elasticity modulus of TiN-Cu coating after vacuum heat treatment at 300 ℃ increased gradually.     

Effect of minor Sc on the microstructure and mechanical properties of AZ91 Magnesium Alloy

The as-cast and heat-treated microstructures and mechanical properties of the AZ91 magnesium alloys with and without minor Sc addition were investigated and compared in this paper. The results indicated that adding0.15–0.45 wt% Sc to the as-cast AZ91 alloy not only could modify and refine the Mg_(17)Al_(12) phase but also suppress the formation of the Mg_(17)Al_(12) phase. At the same time, the grains of the Sc-containing as-cast AZ91 alloys were also effectively refined. As a result, the mechanical properties at room temperature(RT) for the Sccontaining as-cast AZ91 alloys were effectively improved. In addition, adding 0.15–0.45 wt%Sc to the AZ91 alloy promoted the formation of the continuous precipitates(CP) during the aging treatment in spite of that the formation of the discontinuous precipitates(DP) was simultaneously suppressed. Accordingly, the Sc-containing as-aged AZ91 alloys obtained the relatively higher mechanical properties at RT than the as-aged AZ91 alloy.     

Influence of minor boron on the microstructures of a second generation Nibased single crystal superalloy

Boron is added into single crystal superalloys as a micro-alloying element to strengthen low angle grain boundaries.However,systematic investigations on the effect of boron on microstructures of single crystal superalloys are limitedly reported.The effect of boron on as-cast and heat-treated microstructures was investigated in two experimental Ni-based single crystal superalloys containing 3 wt% Re.The current results indicated that the volume fraction of(γ+γ′)eutectic and M_3B_2 borides was evidently increased,while the number of micropores was evidently decreased with the addition of 0.02 wt% boron.The(γ+γ′)eutectic could not be dissolved completely due to the lower incipient melting temperature caused by the formation of M_3B_2 borides.Meanwhile,the M_3B_2 borides were found to be enriched with indispensable strengthening elements Cr,Mo,W and Re,and this may lower the strengthening effect and cause stress concentration during high temperature creep.     

Coupling effects of tungsten and molybdenum on microstructure and stressrupture properties of a nickel-base cast superalloy

In order to comprehensively understand the forming mechanism of abnormal phases solidified in a nickel-base cast superalloy with additives of tungsten and molybdenum, the coupling effects of W and Mo on the microstructure and stress-rupture properties were investigated in this paper. The results indicated that the precipitation of primary α-(W, Mo) phase depended tremendously on the amount of W and Mo addition. When the total amount of W and Mo was greater than 5.79 at%, α-(W, Mo) phase became easily precipitated in the alloy.With increasing of Mo/W ratio, the dendrite-like α-(W, Mo) phases were apt to convert into small bars or blockylike phases at the vicinities of γ′/γ eutectic. The morphological changes of α-(W, Mo) phase can be interpreted as the non-equilibrium solidification of W and Mo in the alloy. Since the large sized α-(W, Mo) phase has detrimental effects on stress-rupture properties in as-cast conditions, secondary cracks may mainly initiate at and then propagate along the interfaces of brittle phases and soft matrix. During exposing at 1100 ℃ for 1000 h, the α-(W, Mo) phases transformed gradually into bigger and harder M_6C carbide, which results in decreasing of stress-rupture properties of the alloy. Finally, the alloy with an addition of 14W-1Mo(wt%) maintained the longest stress lives at high temperatures and therefore it revealed the best microstructure stability after 1100 ℃/1000 h thermal exposure.     

Effect of cold rolling process on microstructure and mechanical properties of high strength β titanium alloy thin sheets

The microstructure and mechanical properties of Ti-3.5Al-5Mo-6V-3Cr-2Sn-0.5Fe high strength titanium alloy sheets prepared by unidirectional cold rolling and two-step cross cold rolling were investigated. Results showed that the β phase grains were refined significantly by cold rolling followed by solution treatment for a short time.Compared to unidirectional cold rolling, the short time solution treatment after two-step cross rolling could significantly reduce the non-uniformity of the microstructure of the alloy sheets. After aging treatment at 550 ℃,the anisotropy of the mechanical properties still existed in the unidirectional rolled sheets, and the tensile strength was highest along the rolling direction. After solution and aging treatment, the anisotropy of the mechanical properties of the two-step cross rolling process sheet was not obvious than unidirectional cold rolling,and alloy had good strength and plasticity matching.     

伪双曲方程一个非协调混合元方法超收敛分析

基于非协调EQrot1元和零阶R-T元针对伪双曲方程,建立了一个自然满足B-B条件的非协调低阶混合元逼近格式.借助单元插值算子的特殊性质、导数转移技巧和插值后处理技术,在半离散格式下给出了原始变量在H1-模和中间变量在L2-模意义下的O(h2)阶超逼近性与整体超收敛结果.同时,对于一个二阶全离散格式得到了原始变量H1-模的O(h2+τ2)超逼近性和中间变量L2-模的O(h+τ2)最优误差估计.     

极端嗜热菌Thermosipho melanesiensis普鲁兰酶基因的异源表达与酶学性质分析

选择来源于极端嗜热菌Thermosipho melanesiensis(DSM12029)的普鲁兰酶基因,以购自德国菌种保藏中心的基因组为模板,扩增出普鲁兰酶基因TM-pulA;利用酶切酶连构建了重组质粒pET21a-TM-pulA;转入大肠杆菌Rosetta(DE3)菌株中诱导表达并经纯化后,进行了水解产物分析和酶学性质测定.结果显示:TM-pulA为Ⅰ型普鲁兰酶,最适pH为5.8;最适温度是80℃;70℃下半衰期为4.75 h;Mn~(2+)、Co~(2+)、AL~(3+)、Fe~(3+)、SDS及EDTA对其酶活有不同程度的抑制作用;该酶的K_m、V_(max)、K_(cat)及K_(cat)/Km值分别为4.68 g·L~(-1)、0.0085 mmol·L~(-1)·s~(-1)、71.18 s~(-1)、15.21 L·g~(-1)·s~(-1).     

粒度对硼铁矿介电特性及微波加热特征的影响

采用谐振腔微扰法测定了不同粒度的硼铁矿在频率为2.45GHz和温度为20~800℃的介电特性,并测定其在微波场下的升温特征.结果表明:随着矿样粒度的减小,填充层空隙率降低,其介电特性增强,微波场中矿样的升温速率加快.当温度高于200℃时,矿样发生热分解产生大量微空隙而增大了空隙率,矿样的介电特性呈下降趋势,使得微波加热过程中矿样的升温速率降低.粒度对硼铁矿介电特性和升温特征的影响研究为微波在冶金领域中的应用及节约能耗提供理论依据.     

铝锡轴承合金的摩擦磨损机理与性能

铝锡轴承合金对大型载重汽车、坦克、高速汽车、拖拉机等的高速高压柴油机的发展有重要的意义。提高铝锡合金的耐摩擦磨损性能可节省大量能源并延长零件的使用寿命,如何取得具有优良的耐摩擦磨损的铝锡合金成为研究的重点。本文介绍了提高铝锡合金的耐摩擦磨损性能的措施及其影响因素,总结铝锡合金中锡元素含量改变、合金元素的添加、热处理与制备工艺的改变对铝锡合金的显微组织以及耐摩擦磨损性能的影响。     

酸性木聚糖酶产生菌XYW5的筛选及酶学性质

【目的】选育优良的产酸性木聚糖酶的微生物,考察酸性木聚糖酶的酶学性质(尤其是pH值为4.0),为实现纤维素乙醇低成本清洁生产打下基础。【方法】从广西大学农场采集土壤,富集后经产酸性木聚糖酶的培养,比较酸性木聚糖酶酶活力,选育酸性木聚糖酶高产菌株,鉴定菌种,分析酶学性质。【结果】筛选出产酸性木聚糖酶酶活力较高的菌株XYW5。扩增菌株XYW5的ITS rDNA序列,经测序分析比对,将其初步鉴定为日本曲霉Aspergillus japonicus XYW5。菌株XYW5产酸性木聚糖酶和酸性木糖苷酶的酶活力最高分别达(26. 26±0. 97)U/mL和(0.63±0.02) U/mL,比活力分别为(85.50±0.63) U/mg和(1.80±0.01) U/mg;其酸性木聚糖酶最适温度和最适pH值分别为65℃和6.5,酸性木糖苷酶最适温度和最适pH值分别为70℃和4.5;酸性木聚糖酶兼有酸性CMCase酶活力,达到8.54 U/mL。【结论】菌株XYW5所产的酸性木聚糖酶具有开发成为优良工业酸性木聚糖酶的潜力。