Physical mechanism of oxygen diffusion in the formation of Ga_(2)O_(3) Ohmic contacts

The formation of low-resistance Ohmic contacts in Ga_(2)O_(3) is crucial for high-performance electronic devices. Conventionally, a titanium/gold(Ti/Au) electrode is rapidly annealed to achieve Ohmic contacts, resulting in mutual diffusion of atoms at the interface. However, the specific role of diffusing elements in Ohmic contact formation remains unclear.In this work, we investigate the contribution of oxygen atom diffusion to the formation of Ohmic contacts in Ga_(2)O_(3). We prepare a Ti/Au electrode on a single crystal substrate and conduct a series of electrical and structural characterizations.Using density functional theory, we construct a model of the interface and calculate the charge density, partial density of states, planar electrostatic potential energy, and I–V characteristics. Our results demonstrate that the oxygen atom diffusion effectively reduces the interface barrier, leading to low-resistance Ohmic contacts in Ga_(2)O_(3). These findings provide valuable insights into the underlying mechanisms of Ohmic contact formation and highlight the importance of considering the oxygen atom diffusion in the design of Ga_(2)O_(3)-based electronic devices.

Elastoplastic Contact Mechanics Model of Rough Surface Based on Fractal Theory

Because the result of the MB fractal model contradicts with the classical contact mechanics, a revised elastoplastic contact model of a single asperity is developed based on fractal theory. The critical areas of a single asperity are scale dependent, with an increase in the contact load and contact area, a transition from elastic, elastoplastic to full plastic deformation takes place in this order. In considering the size distribution function, analytic expression between the total contact load and the real contact area on the contact surface is obtained. The elastic, elastoplastic and full plastic contact load are obtained by the critical elastic contact area of the biggest asperity and maximun contact area of a single asperity. The results show that a rough surface is firstly in elastic deformation. As the load increases, elastoplastic or full plastic deformation takes place. For constant characteristic length scale G, the slope of load-area relation is proportional to fractal dimension D. For constant fractal dimension D, the slope of load-area relation is inversely proportional to G. For constant D and G, the slope of load-area relation is inversely proportional to property of the material ~b, namely with the same load, the material of rough surface is softer, and the total contact area is larger. The contact mechanics model provides a foundation for study of the friction, wear and seal performance of rough surfaces.

Contact Model of Revolute Joint with Clearance Based on Fractal Theory

The contact sti ness of a mechanical bonding surface is an important parameter in determining the normal and radial contact force. To improve the calculation accuracy of the contact force model, the surface roughness of the bonding surface and the energy loss that necessarily occurs during the impact process should be considered com?prehensively. To study the normal contact force of a revolute joint with clearance more accurately in the case of dry friction, a nonlinear sti ness coe cient model considering the surface roughness was established based on fractal theory, which considers the elastic, elastic?plastic, and plastic deformations of the asperities of the contact surface during the contact process. On this basis, a modified nonlinear spring damping model was established based on the Lankarani–Nikravesh contact force model. The laws influencing the surface roughness, recovery coe cient, initial velocity, and clearance size on the impact force were revealed, and were compared with the Lankarani–Nikravesh model and a hybrid model using MATLAB. The maximum impact force was obtained using a modified contact force model under di erent initial velocities, di erent clearances, and di erent degrees of surface roughness, and the calculated results were then compared with the experiment results. This study indicates that the modified model can be used more widely than other models, and is suitable for both large and small clearances. In particular, the modified model is more accurate when calculating the contact force of a revolute joint with a small clearance.

Book Review “Fabrikant,V.I.Contact and Crack Problems in Linear Theory of Elasticity,Bentham Science Publishers,Sharjah,UAE(2010)”

As suggested by the title, this extensive book is concerned with crack and contact prob- lems in linear elasticity. However, in general, it is intended for a wide audience ranging from engineers to mathematical physicists. Indeed, numerous problems of both academic and tech- nological interest in electro-magnetics, acoustics, solid and fluid dynamics, etc. are actually related to each other and governed by the same mixed boundary value problems from a unified mathematical standpoint

COMPLETE CONVERGENCE THEORY OF THE CONTACT PROCESS ON T_d×Z

The author considers the contact process on a branching plane Td×Z, which is the product of a regular tree Td and the line Z. It is shown that above the second critical point, the complete convergence theory holds.

CONTACT PROBLEMS AND DUAL VARIATIONAL INEQUALITY OF 2－D ELASTOPLASTIC BEAM THEORY

In Order to study the frictional contact problems of the elastoplastic beam theory,an extended two-dimensional beam model is established, and a second order nonlinear equilibrium problem with both internal and external complementarity conditions is proposed. The external complementarity condition provides the free boundary condition. while the internal complemententarity condition gives the interface of the elastic and plastic regions. We prove that this bicomplementarity problem is equivalent to a nonlinear variational inequality The dual variational inequality is also developed.It is shown that the dual variational inequality is much easier than the primalvariational problem. Application to limit analysis is illustrated.

Geometrically Exact Theory of Contact Interactions–Further Developments and Achievements

The focus of the current contribution is on the development of the unified geometrical formulation of contact algorithms in a covariant form for various geometrical situations of contacting bodies leading to contact pairs: surface-to-surface, line-to-surface, point-to-surface, line-to-line, point-to-line, point-to-point. The construction of the corresponding computational contact algorithms are considered in accordance with the geometry of contact bodies in a covariant form. These forms can be easily discredited within finite element methods independently of order of approximation and, therefore, the result is straightforwardly applied within iso-geometric finite element methods. This approach is recently became known as geometrically exact theory of contact interaction [10]. Application for contact between bodies with iso- and anisotropic surface, for contact between cables and curvilinear beams as well as recent development for contact between cables and bodies is straightforward. Recent developments include the improvement of the curve-to-surface (deformable) contact algorithm.

利用InSAR形变反演滑坡滑面运动特征——以汶川县布瓦村滑坡为例

当前滑坡滑面运动特征获取多采用接触式手段,费时费力、成本高昂,且仅能获取稀疏点位滑面运动状态。因此,本文提出一种非接触式滑坡滑面运动特征获取方法,其基本思路是:基于位错理论建立滑坡表面形变与滑面运动间的关系模型,同时引入滑面运动平滑约束条件,最终以InSAR等技术获取的地表形变为约束,反演获得滑面运动特征。本文选择四川省汶川县布瓦村滑坡作为研究对象,以时序InSAR技术获取的滑坡坡面升降轨形变数据为约束,基于发展的理论方法反演获得布瓦村滑坡滑面几何与运动学参数,并结合野外勘查、Lidar观测以及模型残差较好地验证了反演结果的可靠性,其中反演升降轨模型残差仅3.1 mm·a^(-1)和3.4 mm·a^(-1)。反演结果显示,布瓦村滑坡滑面位于坡表以下平均~15.0 m深度处,滑面整体以沿坡向运动为主,最大运动量级达~80 mm·a^(-1),同时在坡体西侧中下部发现微量的垂直坡向运动。本文提出方法可方便、快速的获取空间连续的滑坡滑面运动特征,为滑坡灾害预警和失稳风险评估提供更为直接可靠的科学参考。

基于分形理论的变齿厚齿轮接触应力分析

为了更准确地反应变齿厚齿轮齿面真实接触应力,构建了变齿厚齿轮的齿面接触系数,并对其合理性进行了验证。基于分形接触理论和Hertz接触理论建立了综合考虑齿轮齿面粗糙形貌、接触点弹性变形、材料特性等参数的变齿厚齿轮接触模型,计算变齿厚齿轮的接触强度,并与有限元计算结果进行比较,验证了方法的有效性。通过分形理论得出齿轮啮合时载荷与面积的关系,并对4个基本参数进行仿真,分析分形接触模型的效果。结果表明,通过数值模拟和分析实际接触面积与载荷的关系图,验证了分形接触模型的准确性。基于有限元理论、Hertz接触理论和分形理论,对变齿厚齿轮的齿面接触强度进行了比较和分析,验证了分形接触模型计算变齿厚齿轮接触应力的正确性,该模型的建立为变齿厚齿轮的设计与强度校核提供了一定的理论依据。

骨架膜装配式节点设计与承载力分析

提出的骨架膜结构装配式节点具有构造简单、预制程度高、便于现场装配、可以调节消减加工误差、适应各种形状的骨架膜结构、传力清晰等特点。基于Hertz接触理论分析了该节点的关键承载结构——销轴连接的应力分布形式并与有限元分析相互印证。基于有限元分析得出了该节点中杆件与耳板最佳的连接方式,对该节点的三维模型进行简化并建立有限元模型,计算了该节点的极限承载能力,得到其破坏形式并与同规格的空间相贯焊接钢管节点进行对比。结果表明:该装配式节点的失效由下弦杆控制,满足“强节点,弱杆件”的设计要求;该装配式节点的极限承载能力为设计荷载的2.95倍,与同规格的空间相贯焊接钢管节点几乎相同,有充足的安全余量,可以更加灵活地应用于各种建筑结构中。

基于分形理论的浮环密封端面法向接触刚度仿真研究

浮环密封是现代航空发动机常用的密封形式之一,浮环端面的接触刚度对浮环密封辅助密封面的摩擦磨损性能有重要影响。在分形理论的基础上,基于有限元方法建立了一种新的法向接触刚度计算模型。之后通过该模型计算浮环密封端面法向接触刚度,得到了浮环密封端面法向接触刚度随压力与粗糙度的变化规律。计算结果表明:求得的法向接触刚度与粗糙表面接触试验结果吻合较好,最大相对误差不超过4%;浮环密封端面法向接触刚度随压力的增大而增加,随接触面粗糙度的增大而减小。该方法为浮环密封端面法向接触刚度的计算提供了一种新的思路。

圆柱面结合部接触应力的三维分形模型

为了对机械结构中圆柱结合部的承载能力进行研究,基于Hertz接触理论,并结合修正的三维分形理论,应用三维分形曲面来模拟实际工程中的结合面,在综合考虑宏观特性因素与微观形貌因素的情况下,建立了圆柱结合部接触应力的三维分形模型,并与Hertz接触模型进行了对比分析,证明了所建立模型的合理性。通过Matlab仿真分析得到,从宏观特性因素上,可以选用内接触圆柱结合部,或增大小圆柱体的半径来降低接触应力,提高承载能力;从微观形貌因素上,可以减小分形尺度参数,或减小材料特性参数来降低接触应力。分形维数对接触应力的影响比较复杂:当2.1≤D≤2.5时,增大分形维数,可以降低接触应力;当2.5≤D≤2.9时,减小分形维数,可以降低接触应力。

双螺母防松螺栓拧紧过程的理论与仿真研究

工程中双螺母防松是一种常见的螺栓连接防松形式。为研究双螺母螺栓拧紧过程中的力学性能,考虑螺纹柔性的影响,建立了双螺母螺栓连接的力学模型,对螺纹的受力进行了分析,推导并给出了螺栓杆轴力和螺纹表面接触应力的计算方法,研究了螺纹接触应力的分布规律,以及上下螺母拧紧力矩配比对螺纹接触状态的影响,建立了螺栓预紧力与上下螺母拧紧力矩的关系,分析对比了螺栓规格、螺母厚度配比对螺栓杆轴力分布、接触应力的影响规律。建立了双螺母螺栓的精细化有限元模型,并将仿真结果与理论结果进行了对比验证,结果发现该文推导给出的螺栓杆轴力计算方法与有限元结果吻合很好。

舰船非接触水下爆炸系统的混合不确定度量化

[目的]舰船非接触水下爆炸建模与仿真(M&S)中同时存在品目繁多的认知不确定度和偶然不确定度,在M&S过程中引入的不确定度导致系统响应量(SRQ)的数值模拟结果与试验真值间产生较大偏差,影响M&S的性能。而使用非接触水下爆炸不确定度量化(UQ)方法能提高M&S的可靠性和可信度。[方法]首先,针对无物理意义、通过试验直接标定的唯象参数,使用D-S证据理论(DSTE)融合不同学科专家(SME)的建议,得到唯象参数赋值区间和基本信度分配(BBA)函数。鉴于SME的个人工程经验和知识结构的局限性,采用多证据、多周期性融合方法,提高认知不确定度量化的客观性。其次,使用蒙特卡罗法研究非接触水下爆炸中高维输入偶然不确定度的传播。最后,当偶然不确定度和认知不确定度同时存在时,将唯象参数作为外层,不确定的物理量作为内层,使用双层循环法执行非接触水下爆炸的混合不确定度量化。[结果]结果表明,改进后的DSTE方法缩小了认知不确定度的取值范围,对SME初始意见改动较大,计算所得认知不确定度的BBA更精确、客观性更强。双层循环法可计算得到舰船非接触水下爆炸SRQ的可信置信区间和BBA,结果与常识吻合。[结论]研究结果可用于指导舰船防护设计和提高水下兵器爆炸毁伤能力。

基于分形理论的齿面微观形态接触特性分析

如何有效计算结合面的接触刚度以及分析结合面刚度对整体结构动态特性的影响,是机械结构研究的重要课题之一。目前更多的是简单地将分形理论应用于结合面刚度计算分析,难以全面地对微观形态接触特性进行分析。因此,亟待提出齿面接触刚度计算的新方法,对微观形态接触特性进行分析。基于W-M(Weierstrass-Mandelbrot)函数构建了齿面微观结合面三维实体模型,考虑粗糙度对刚度的影响,提出了一种基于分形维数D和齿面粗糙度的粗糙表面轮廓分形表征新方法;探讨了微凸体接触变形机制,揭示了接触刚度随微凸体变形而变化的规律。研究表明,在同一粗糙度的微观结合面中,当微凸体变形到同一水准时,分形维数D越大,其接触刚度越大;在同一分形维数、不同粗糙度的结合面中,结合面的粗糙度越小,接触刚度越大。

考虑轮轨多点接触关系的车轨系统地震响应分析

为研究地震作用下轮轨多点接触关系及其对车轨系统地震响应的影响,本文基于虚拟渗透理论分析了轮轨多点接触的几何关系,采用修正的Kik-Piotrowski方法和Kalker线性理论求解轮轨接触力,并建立了地震作用下考虑轮轨多点接触关系的列车-无砟轨道系统模型;以某高速铁路为对象,研究了车轨系统的地震响应及列车的行车安全性。研究结果表明:地震作用下轮轨之间会出现2点接触情况,次接触斑对轮轨接触行为具有重要影响;轮轨多点接触关系对地震作用下的轮轴横向力和脱轨系数具有重要影响,不考虑该多点接触关系会低估列车的行车安全性;车轮抬升量对地震动强度不是特别敏感。

低速冲击下碳纤维面板泡沫夹芯复合材料的损伤分析

主要研究了夹层复合材料受外来载荷作用下的凹痕、横向位移、接触力随时间的变化规律.采用高阶剪切变形理论给出夹层板的广义内力表达式,再由薄板小挠度理论、Hertz接触理论、夹层板平衡方程、Navier法推导出夹层板在外来载荷作用下的动态响应过程.其中,夹层板的接触力和横向位移由两自由度弹簧-质量模型给出.将推导的结果与文献中的理论结果对比,本文计算的误差均不超过6%.并在此基础上比较了不同冲击条件下夹层板的抗冲击性能.

高速列车滚动轴承特征频率计算方法

针对高速列车滚动轴承的工作特点,研究了滚子在完好和损伤条件下滚动轴承的特征频率变化规律。基于赫兹接触理论结合轴承实际接触状态,分析了轴承各部件之间相互作用下变形规律,建立了虑及轴承接触部位挠度变化的特征频率计算模型,研究了转速对VA3881型滚动轴承的滚子分别在正常和损伤情况下特征频率的影响规律。研究结果表明,振动特征频率受到轴承转速的影响,特征频率会随着转速的增加而增加。通过有限元瞬态动力学仿真模型对所建立的计算模型进行验证,仿真结果与理论计算结果相吻合,证明了所建模型与仿真结果的合理性和正确性。该研究为轴承的故障诊断提供了合理的方法。

面向机器人打磨陶瓷洁具工艺的参数优化

针对卫浴陶瓷洁具进行抛光工艺,引入新松打磨机器人作为自动化设备实现自动化抛光打磨。结合Preston方程以及赫兹接触理论,确定了海绵轮与工件之间的相对速度,正压力是对陶瓷洁具表面质量的影响的两个工艺参数,以此建立了陶瓷洁具的材料去除理论模型;后续搭建了机器人恒力抛光平台,设计了陶瓷洁具的抛光打磨抛光工序,以其主要的两个参数为变量设计了单因素实验,得到各参数对抛光效率的关系,并为提出最佳抛光工艺参数组合做好铺垫。

考虑微凸体间相互作用的机床结合面加载接触特性分形理论建模

文章基于分形几何理论,考虑机械结合面微凸体间的相互作用对结合面接触特性的影响,同时考虑微凸体发生弹塑性变形的两个阶段,得出考虑微凸体间相互作用的单个微凸体的弹性临界变形;从而建立考虑微凸体间相互作用的单个微凸体各变形阶段接触载荷、接触刚度理论模型;进一步建立考虑微凸体间相互作用的结合面真实接触载荷、接触刚度分形理论模型,并进行无量纲处理,分别得出接触载荷、接触刚度与接触面积之间量纲为一的关系式。通过仿真分析对比,可见考虑微凸体间相互作用时单个微凸体的临界变形小于不考虑微凸体间相互作用时,而对应的微凸体接触载荷、接触刚度则大于不考虑微凸体间相互作用时。对比考虑微凸体间相互作用时不同分形维数对结合面接触载荷、接触刚度的影响,得出考虑微凸体间相互作用时分形维数增大结合面接触载荷、接触刚度呈增大趋势。