稀土La在α-Fe中占位倾向及对晶界影响的第一性原理研究

本文采用重合位置点阵理论构建了α-Fe的Σ3[110](112)对称倾转晶界模型,通过基于密度泛函理论的平面波超软赝势方法研究了稀土La元素在α-Fe中的占位倾向.结果表明,La在α-Fe晶界的杂质形成能最低,因而La原子倾向于占据晶界区;掺杂La前后的α-Fe晶界电子结构计算结果显示,La占位于α-Fe晶界会使体系中的电荷发生重新分配,将提供更多电子用于晶界区成键,使得Fe原子得到更多的电子,这将导致掺杂区原子间结合有离子化趋势,从而使La与晶界区相邻Fe原子之间的相互作用加强,也使晶界原子与晶界两侧Fe原子的键合加强,从能量角度解释了材料宏观力学性能变化的原因;计算同时发现,La加入后,也使晶界上的原子成键区态密度左移,降低了体系的总能量,使晶界结构更为稳定.     

稀土La在$lt;em$gt;α$lt;/em$gt;-Fe中占位倾向及对晶界影响的第一性原理研究

本文采用重合位置点阵理论构建了 α-Fe的Σ3[110]（112）对称倾转晶界模型,通过基于密度泛函理论的平面波超软赝势方法研究了稀土La元素在 α-Fe中的占位倾向. 结果表明,La在 α-Fe晶界的杂质形成能最低,因而La原子倾向于占据晶界区;掺杂La前后的 α-Fe晶界电子结构计算结果显示,La占位于 α-Fe晶界会使体系中的电荷发生重新分配,将提供更多电子用于晶界区成键,使得Fe原子得到更多的电子,这将导致掺杂区原子间结合有离子化趋势,从而使La与晶界区相邻Fe原子之间的相互作用加强,也使晶界原子与晶界两侧Fe原子的键合加强,从能量角度解释了材料宏观力学性能变化的原因;计算同时发现,La加入后,也使晶界上的原子成键区态密度左移,降低了体系的总能量,使晶界结构更为稳定. 关键词： La α-Fe')" href="#">α-Fe 晶界 第一性原理     

包含倾斜晶界的双晶ZnO的热输运行为

用嵌入位错线法和重合位置点阵法构建含有小角度和大角度倾斜角的双晶氧化锌纳米结构.用非平衡分子动力学方法模拟双晶氧化锌在不同倾斜角度下的晶界能、卡皮查热阻,并研究了样本长度和温度对卡皮查热阻和热导率的影响.模拟结果表明,晶界能在小角度区域随倾斜角线性增加,而在大角度区域达到稳定,与卡皮查热阻的变化趋势一致.热导率随样本长度的增加而增加,卡皮查热阻表现出相反的趋势.然而随着温度的增加,热导率和卡皮查热阻都减小.通过比较含5.45°和38.94°晶界样本的声子态密度,发现声子光学支对热传导的影响不大,主要由声子声学支贡献,大角度晶界对声子散射作用更强,声学支波峰向低频率移动.     

Al,Cr共偏析α-Fe晶界对其结合强度影响的第一性原理研究

在密度泛函理论的框架下,采用广义梯度近似(GGA)研究了合金化元素Al,Cr在α-Fe+(210)晶界共偏析的作用.结果表明Cr提高了Fe晶界结合,为韧性杂质;而Al减弱了晶界的结合,是脆性杂质.Cr不能够彻底地消除Al的脆化作用,反而使其脆性增强.基于偏聚能分析表明Cr能有效地抑制Al偏析到晶界,提高α-Fe的力学性能.     

B掺入Cu∑5晶界间隙位性质的第一性原理研究

本文采用第一性原理方法对清洁Cu∑5晶界与有B掺杂 到间隙位的Cu∑5晶界进 行了拉伸和压缩的模拟研究. 结果分析表明, Cu∑ 5晶界结合因B的掺入得到加强. 清洁Cu∑5晶界处因有较大空隙而存在电子密度低的区域, 晶界结合相对较弱, 在拉伸过程中晶界从其界面处开始断裂. 有B掺杂在间隙位的Cu∑5晶界电子由Cu向Cu-B间积聚, 晶界结合相对较强, 拉伸时晶界从其近邻原子层开始断裂. 在形变小于20%的压缩过程中, B的掺入未对晶界产生明显影响. 关键词： 第一性原理 Cu晶界 B掺杂 拉伸压缩     

杂质对镁合金耐蚀性影响的电子理论研究

利用大角重位点阵模型建立了Mg合金［0001］对称倾斜晶界模型，应用实空间的连分数方法计算了杂质在晶界的偏聚能，杂质原子间相互作用能和不同体系的费米能级，讨论了杂质在晶界的偏聚行为，杂质间的相互作用与有序化的关系及杂质对镁合金腐蚀性能影响的物理本质. 计算结果表明，杂质原子偏聚于晶界，且主要偏聚于晶界的压缩区；杂质原子间相互排斥，因此在晶界区形成有序相；费米能级与材料的腐蚀电位存在这样的关系：材料的费米能级越高，其腐蚀电位就越低，容易被腐蚀，相反费米能级低，其腐蚀电位就高，不容易腐蚀. 体系中成分不同区域的费米能级差导致电子从费米能级高的区域流向费米能级低的区域，正是费米能级差构成了镁合金电化学腐蚀的电动势. 关键词： 电子理论 晶界偏聚 镁合金 腐蚀机理     

微合金化元素晶界偏聚与钢的超细化理论研究

通过计算机编程建立钢奥氏体相中Σ5〈001〉/(210)大角晶界模型，用实空间的递推方法计 算碳、氮及微合金元素在完整晶体及晶界区引起的环境敏感镶嵌能，进而讨论碳、氮及微合 金元素在晶界区的偏聚及交互作用.计算结果表明，轻杂质C，N易偏聚于晶界区，且形成气 团；微合金元素在完整的奥氏体中趋于均匀分布，Ti，V，Nb易占位于晶界三角棱柱的顶部( 压缩区)，且其加入量足够大时，它们能够在晶界区形成气团；微合金元素能够偏聚于C，N 掺杂的大角晶界区，当温度下降使得C，N及微合金元素的浓度超过其最大固溶度时，在钢的 奥氏体晶界区将有C，N化合物脱溶，这些化合物既可成为奥氏体再结晶的异质晶核，又可以 阻碍奥氏体晶粒长大，故可起到细化晶粒作用.在微合金元素中Nb的细化效果最好. 关键词： 电子结构 晶界偏聚 超细化     

晶界内耗研究的新进展

由不同取向差的纯Al双晶的内耗实验观察到,不同类型晶界的弛豫参量有明显差别.用耦合模型对内耗数据的分析表明,小角度晶界内耗的基本机制是位错攀移,而大角度晶界内耗的基本机制是晶界扩散.在此基础上,对多晶中晶界内耗的一些特征也作了解释.     

单向拉伸作用下Cu(100)扭转晶界塑性行为研究

应用分子动力学方法研究了在不同扭转角度下的Cu（100）失配晶界位错结构,以及不同位错结构对晶界强度的影响.模拟结果表明：小角度扭转晶界上将形成失配位错网,失配位错密度随着晶粒之间的失配扭转角度的增加而增加.变形过程中,位错网每个单元中均产生位错形核扩展.位错之间的塞积作用影响晶界的屈服强度：随着位错网格密度的增加,位错之间的塞积作用增强,界面的屈服强度得到提高.大角度扭转晶界将形成面缺陷,在变形中位错由晶界角点处形核扩展,此时由于面缺陷位错开动应力趋于一致,因此晶界的临界屈服强度趋于定值. 关键词： 扭转晶界 失配位错网 强化机理 分子动力学     

剪切作用下Cu(100)扭转晶界塑性行为研究

本文采用分子动力学方法研究了在剪切载荷作用下,Cu(100)扭转晶界对Cu柱屈服强度的影响.模拟结果发现,在加载过程中,低角度扭转晶界形成的位错网发生位错形核与扩展,位错之间的塞积作用提高了Cu柱的屈服强度;对于高角度扭转晶界,晶界发生滑动降低了Cu柱的屈服强度.同时发现,随着扭转角度的增加,Cu柱的屈服强度先增大,当扭转角度大于临界角度时,Cu柱的屈服应力逐渐减小.这表明剪切载荷作用下,两种不同的机理主导Cu柱的屈服,对于小于临界角度的扭转晶界,Cu柱的屈服由晶界位错形核和扩展机理主导,对于大于临界角度 关键词： 扭转晶界 分子动力学 位错形核 晶界滑移     

Thermodynamics of Vacancies and Impurities at Grain Boundaries

The thermodynamics of vacancy and impurity adsorption at interfaces and grain boundaries (GBs) in solids is considered. Theoretical expressions are derived for the GB/interface free energy change caused by various levels of vacancy or impurity adsorption. This information is used to predict the behavior of vacancies at interfaces and GBs in a stress gradient and to forecast the effect of impurities on GB fracture strength. The latter predictions provide an interpretation of intergranular fracture behavior in terms of impurity adsorption and GB structural parameters such as GB width and value.     

铜（001）扭转晶界能的原子级计算

采用改进分析型嵌入原子法（MAEAM）计算了铜（001）未松弛扭转晶界的晶界能。结果表明，除扭转角为（完整晶体）时的能量为零外，对应和扭转角为36.87°时的晶界能为最小，和实验结果一致；对于其它扭转角，包括很小的扭转角1.94°，晶界能几乎为一常数；均匀膨胀和垂直于晶界面的膨胀都会使晶界能明显降低，尤其是后者。     

Theory of Triple Junctions Mobility in Crystals with Impurities

We consider the steady state migration of the triple junction in the tricrystal with impurities which segregate strongly at the grain boundaries. If the mobility of impurities inside grain boundaries is much higher than the rate of impurity atoms jumps from the grain boundary into the bulk, the triple junction migration causes the divergence of the impurity content at the triple point. We show that this divergence can be relaxed either by the non-equilibrium segregation at the growing grain boundary or by the formation of the inclusion of the impurity-rich phase at the triple point. In the former case the dihedral angle at the triple point differs considerably from its equilibrium value and is strongly temperature-dependent. However, the triple junction cannot be described as an individual object with its own mobility. In the latter case of the cavity formation at the triple point the triple junction can be characterized by its own mobility. It is shown that the dependence of the triple junction migration rate on the driving force is approximately linear at the low migration rates and highly nonlinear at high migration rates. Moreover, there is the maximal allowable steady-state migration rate of the system triple junction-inclusion. For the higher migration rates the jerky motion of the triple junction occurs. Both models are in a good agreement with the experimental data.     

On Applicability of a Direct Shear Test for Strength Estimation of Cereal Grain

Investigations were performed to verify the applicability of a direct shear method as recommended by Eurocode 1 for testing the strength of cereal grains [2]. Tests on rye without preconsolidation have shown that stress‐strain characteristics depend on the method of sample deposition. However, consolidation of the sample by twisting the top plate, as recommended by the code, neutralizes the influence of the grain packing structure on values of the angle of internal friction. Determination of the strength parameters for grain of six genera, under normal reference pressure of 100 kPa, and five levels of moisture content in a range from 10% to 20%, confirmed the applicability of the test. The only necessary modification of Eurocode procedure was elongation of the shear path up to the 0.1 ΔL/D level of the sample diameter. Values for the angle of internal friction were found to range from 22.1°–35.5° and were dependent on the grain genus and moisture content. The majority of dry grain samples showed low cohesion (below 4 kPa), and thus, should be treated as free flowing material. The increase in moisture content resulted in an increase of cohesion up to the highest observed value of 12 kPa. Triaxial compression tests were performed on wheat of five levels of moisture content, and gave results that were in close agreement with the results of the direct shear test.     

Segregation Effects at a High-Angle Twist Boundary in ZnO

Ab initio density functional plane-wave pseudopotential calculations were performed for a = 7 ( = 21.79°) [0001] twist boundary in ZnO with and without the presence of Sb impurities. The segregation energies revealed a significant driving force for segregation and it was shown that the formation of an Sb monolayer was favoured. Decreased coordination in the boundary core suggested a trend towards the formation of an intergranular phase. The impurity states caused by the monolayer were located within the band gap and higher in energy relative to the state produced by a single impurity. Charge transfer to the Sb monolayer was observed indicating a possible enhancement of the grain boundary potential barrier.     

Classification of impurities according to their effect on intergranular cohesion of titanium,nickel, and aluminum

Impurities are classified in regard to their effect on the intergranular cohesion of titanium, nickel, and aluminum on the basis of a comparative analysis of the bond energies between the impurity and the grain boundary. Microadditions which bond dangerous impurities into a compound are discussed.Translated from Izvestiya Vysshikh Uchebnykh Zavedenii, No. 7, pp. 12–15, July, 1987.     

Effect of alumina addition on the microstructure and grain boundary resistance of magnesia partially-stabilized zirconia

The electrical properties of 9 mol% MgO–ZrO₂ (Mg-PSZ) with 1 mol% Al₂O₃ and the mechanisms for electrical degradation were investigated using structural, morphological, and electrochemical analyses. The addition of Al₂O₃ caused an increase in both the monoclinic and the Mg-rich phases at the grain boundaries in the Mg-PSZ. Coarse grains larger than 20 μm and an intergranular layer composed of the Mg-rich phase were identified in a specimen sintered at 1600 °C. This specimen exhibited a minimum of ionic conductivity (4.98 × 10⁻⁴ S cm⁻¹ at 700 °C) due to the grain boundary resistance (245 Ω cm²), which dominated the overall resistance. A similar trend was observed over the entire temperature range (600–1500 °C). An intergranular siliceous impurity (SiO₂) was present in conjunction with the Mg-rich phase. This impurity and the Mg-rich phase acted as a barrier layer for oxygen ion diffusion. The presence of the intergranular phases (i.e. the monoclinic and Mg-rich phases) contributed to the degradation of the ionic conductivity in Mg-PSZ with an Al₂O₃ addition.     

Influence of impurities on the fracture behaviour of tungsten

Ten tungsten materials with different impurity concentrations and different microstructures have been investigated by Auger electron spectroscopy and scanning electron microscopy with respect to their fracture behaviour. For almost all samples, both inter- and transgranular fracture are observed, and the proportion of each type varies. Due to the difference in their impurity content and grain boundary area, a large variation in the grain boundary impurities can be expected. By analysing the fracture surfaces the effect of grain boundary impurities, especially phosphorous and oxygen, on the fracture resistance of the boundaries was determined. The results indicate that for the analysed tungsten materials, grain boundary impurities do not have a significant influence on the fracture resistance of the boundaries. Other factors such as the size and shape of the grains, the amount of deformation and therefore the density of dislocations within the grains have a greater impact on the fracture behaviour of tungsten.     

Deformation study of bicrystalline and nano-polycrystalline structures using phase field crystal method

Deformation behaviors of bicrystalline and nano-polycrystalline structures of various tilt angles and inclination angles in two dimensions are investigated in detail using a two-mode phase field crystal model.The interaction between grain boundary(GB)and dislocation is also examined in bicrystals and nano-polycrystals that both contain asymmetric and symmetric tilt GBs,with energy analysis being carried out to analyze these processes.During deformation simulations,we assume the volume of each simulation cell at every time step is coincident with that of the initial state just before deformation.Our simulation results show that the behaviors of symmetric and asymmetric GBs in bicrystals and nano-polycrystals differ from each other depending on tilt angle and inclination angle.A new dislocation emission mechanism of interest is observed in bicrystals which contain low angle symmetric tilt GBs.Low angle GB has a higher mobility relative to high angle GB in both bicrystalline and nano-polycrystalline structures,as does asymmetric GB to symmetric GB.The generation,motion,pileup and annihilation of dislocations,grain rotation and grain coalescence are observed,which is consistent with the simulation results obtained by molecular dynamics.These simulation results can provide strong guidelines for experimentation.