Morphology and Frictional Characteristics Under Electrical Currents of Al_2O_3/Cu Composites Prepared by Internal Oxidation

Two Al2O3/Cu composites containing 0.24 wt.% Al2O3 and 0.60 wt.% Al2O3 separately are prepared by internal oxidation. Effects of sliding speed and pressure on the frictional characteristics of the composites and copper against brass are investigated and compared. The changes in morphology of the sliding surface and subsurface are examined with scanning electron microscope （SEM） and energy dispersive X-ray spectrum （EDS）. The results show that the wear resistance of the Al2O3/Cu composites is superior to that of copper under the same conditions, Under a given electrical current, the wear rate of Al2O3/Cu composites decreases as the Al2O3-content increases, However, the wear rates of the Al2O3/Cu composites and copper increase as the sliding speed and pressure increase under dry sliding condition. The main wear mechanisms for Al2O3/Cu composites are of abrasion and adhesion; for copper, it is adhesion, although wear by oxidation and electrical erosion can also be observed as the speed and pressure rise.

Fabrication of an in-situ nanoAl_2O_3/Cu composite with high strength and high electric conductivity

A heat-resistant dispersion-strengthening nano-Al_2O_3/Cu composite with highstrength and high electric conductivity was fabricated in a multiplex medium. The internaloxidation product, microstructures and properties of the composite, and the process flow weresystematically studied. It is confirmed that this new technique simplifies the process and improvesthe properties of the composite. X-ray analysis indicates that the alumina particles formed duringinternal oxidation consist of a large mount of gamma-Al_2O_3 and a certain amount of theta-Al_2O_3and alpha-Al_2O_3. TEM observation shows that the obtained gamma-Al_2O_3 nano-particles areuniformly distributed in the copper grains; their mean size and space between particles are 7 runand 30 nm, respectively. The main properties of the composite with 50 percent cold deformation areas follows: the electric conductivity is 51 MS/m (87 percent IACS), sigma_b = 628 MPa, and thehardness is HRB86. After annealing at 1273 K, all or most of the above properties remain, and themicrostructures are still dependent on elongated fiber-form grains.

Effect of Ni-coated MoS2 on microstructure and tribological properties of(Cu−10Sn)-based composites

The(Cu−10Sn)−Ni−MoS2 composites,prepared by powder metallurgy,were studied for the effects of Ni-coated MoS2 on the microstructure,mechanical properties and lubricating properties.The mechanism of effects of Ni and MoS2 on the properties of composites was analyzed through a comparative experiment by adding Ni and MoS2 separately.The results show that the nickel wrapping around the MoS2 particles decreases the reaction rate of MoS2 with the copper matrix,and greatly improves the bonding of the matrix.The composites with 12 wt.%Ni-coated MoS2(C12)show the optimum performance including the mechanical properties and tribological behaviors.Under oil lubrication conditions,the friction coefficient is 0.0075 with a pressure of 8 MPa and a linear velocity of 0.25 m/s.The average dry friction coefficient,sliding against 40Cr steel disc,is measured to be 0.1769 when the linear velocity and pressure are 0.25 m/s and 4 MPa,respectively.

Self-propagating High-temperature Synthesis, Microstructure and Mechanical Properties of TiC-TiB_2-Cu Composites

TiC-TiB2-Cu composites were produced by self-propagating high-temperature synthesis combined with pseudo hot isostatic pressing using Ti, B4C and Cu powders. The microstructure and mechanical properties of the composites were investigated. The X-ray diffraction （XRD） and scanning electron microscopy （SEM） results showed that the final products were only TiC, TiB2 and Cu phases. The clubbed TiB2 grains and spheroidal or irregular TiC grains were found in the microstructure of synthesized products. The reaction temperature and grain size of TiB2 and TiC particles decreased with increasing Cu content. The introduction of Cu into the composites resulted in a drastic increase in the relative density and flexual strength, and the maximum values were obtained with the addition of 20 wt pct, while the fracture toughness was the best when Cu content was 40 wt pct.

Reaction thermodynamics and kinetics on in situ Al_2O_3/Cu composites

The preferred internal oxidation of aluminum in Cu Al alloy was used to obtain in situ Al 2O 3/Cu composites. The reinforcement particles were mainly γ Al 2O 3, some θ Al 2O 3 and a little α Al 2O 3. Thermodynamics analyses show that the chemical reactions are 3Cu 2O+2Al=6Cu+Al 2O 3 or 3CuO+2Al=3Cu+Al 2O 3. A related equilibrium diagram was drawn. The experiments and investigation show that the formation rate of Al 2O 3 was controlled by the diffusion of oxygen in matrix.

In situ TiB2/Cu composites fabricated by spray deposition using solid-liquid and liquid-liquid reactions

In situ TiB2/Cu composites were fabricated by both solid-liquid(S-L)and liquid-liquid(L-L)reactive spray deposition in combination with cold rolling and annealing.The microstructure and properties of the fabricated TiB2/Cu composites were investigated.The results show that the reactive mode and rolling treatment are the main factors affecting the microstructure and properties of the TiB2/Cu composite.The in situ reaction in the L-L reaction can be carried out more completely.By controlling the rolling and annealing process,the relative density and the properties of the as-deposited composites are optimized.The comprehensive performance of the deformed TiB2/Cu composite prepared by L-L reactive spray deposition(401 MPa and 83.5%IACS)is better than that by S-L reactive spray deposition(520 MPa and 20.2%IACS).

Potential-aided recovery of iodide using 2-D nanosheet CuxO coating polymer/graphene/carbon fibers composite

2-D nanosheet Cu2O doped CuO coating poly m-phenylenediamine and melamine/graphene/carbon fibers composite(CuxO/MPM/GFs)was firstly fabricated by compound electrochemical method.CuxO/MPM/GFs was successfully used to the recovery of iodide(I-)from salt water by lower potential-aided sorption and desorption processes.The potential-aided recovery of I-at CuxO/MPM/GFs was characterized by FE-SEM,XRD,IR,Raman,XPS,UV-vis and electrochemical techniques in detail.The maximal adsorption capacity of 86.82 mg·g^-1 could be obtained with a pseudo-second-order model at 0.8 V for 210 min in pH 5.0,0.1 mol·L^-1 NaCl,and the process accompanied the generation of CuI,CuO and I5-.The I-could be quickly desorbed from the electrode with a transfer of CuI to Cu2O by cycle voltammetry from-1.0 to 0.5 V for 90 cycles in pH 9.0,0.1 mol·L^-1 KNO3.Thus,CuxO/MPM/GFs was renewable in the continuous electrochemical-adsorption-desorption processes.

High Temperature Flow Stress Prediction of Nano-Al_2O_3/Cu Composite Using an Artificial Neural Network

Alumina dispersion strengthened copper composite （nano-Al2O3/Cu composite） was recently emerged as a kind of potentially viable and attractive engineering material for applications requiring high strength, high thermal and electrical conductivities and resistance to softening at elevated temperatures. The nano-Al2O3/Cu composite was produced by internal oxidation. The microstructures of the composite were analyzed by the TEM and its hot deformation behavior was investigated by means of continuous compression tests performed on a Gleeble 1500 thermo-simulator. Making use of the modified algorithm-Levenberg-Marquardt （L-M） algorithm BP neural network, a model for predicting the flow stresses during hot deformation was set up on the base of the experimental data. Results show that the microstructures of the composite are characterized by uniform distribution of nano-Al2O3 particles in Cu-matrix. The sliding of dislocations is the main deformation mechanism. The dynamic recovery is the main softening mode with the flow stress decreasing gently from 500℃ to 850 ~C. The recrystallization of Cu-matrix can be retarded late into as high as 850 ℃, when it happens only partially. The well-trained BP neural network model can accurately describe the influence of the temperature, strain rate, and true strain on the flow stresses, therefore, it can precisely predict the flow stresses of the composite under given deforming conditions and provide a new way to optimize hot deforming process parameters.

Mechanical properties and microstructure of in situ TiB_2/Cu composite fabricated by reactive hot pressing

A copper matrix composite reinforced by TiB_2 particle was fabricated by reactions of Cu,Ti and B powders.The microstructure and mechanical properties of the in situ composite were investigated.The results showed that the in situ formed TiB_2 particles,which has a size of no larger than 1 μm,exhibits a uniform distribution in the copper matrix.Due to TiB_2 reinforcement,the mechanical properties in terms of Young's modulus and yield and ultimate tensile stress of the in situ TiB_2/Cu composite are improved greatly.In addition,even if the volume fraction of TiB_2 reinforcement are the same,the composite in the present study containing fine TiB_2 particles exhibits much higher properties than that of the composite reinforced with coarse ones.

Interface characterization of Al/Cu 2-ply composites under various loading conditions

The effects of reduction ratio during roll bonding on the microstructural evolution at interface and subsequent mechanical properties of roll-bonded Al/Cu 2-ply sheets were investigated. The interface microstructures for several Al/Cu 2-ply sheets fabricated under different reduction ratios between 30% and 65% were verified by transmission electron microscopy(TEM). Taking the difference of interface microstructure into consideration, 3-point bending and peel tests were performed for obtaining flexural and bonding strengths for Al/Cu 2-ply sheets. The effect of the quantified areas of metallurgical bonding at interfaces on the bonding strength was also discussed. The results show that both the bonding and flexural strengths for Al/Cu 2-ply sheets are reduced by decreasing the reduction ratio during the roll bonding process, which is strongly correlated with the interface microstructure. This was especially verified by observing the interface delamination from the 3-point bent samples.

High Temperature Deformation of Al_2O_3/Cu Composites

This work concerns with the high temperature deformation of internally oxidized Al2O3/Cu composites. The investigation revealed that dispersive alumina can obstruct dislocation sliding and define the subgrain size thereby improve significantly the strength of the materials at high temperature. The sliding of dislocations is a main deformation mechanism in the given temperature range. The sliding of grain boundary and diffusive creep play important roles at high temperature and low strain rate. The dispersoids can raise the recrystallization temperature to higher than 1223 K. Dynamic recovery is a main softening way under the experimental conditions. Higher deformation rate and lower deformation temperature imply a higher flow stress.

Recovery of valuable elements from spent YBa_2Cu_3O_(7-x)/Agcomposite superconductor bulks

Silver as a highly conductive metal is usually doped in YBa2Cu3O7-x superconductor bulks to improve critical current density of YBa2Cu3O7-x superconductor.The valuable metal elements silver,yttrium,barium and copper in waste YBa2Cu3O7-x/Ag composite superconductor bulks were recovered,respectively.Silver was recovered with process at first,the waste was dissolved by nitric acid and silver chloride was precipitated by adding chloride acid,then silver pig was obtained by melting silver chloride together with sodium carbonate at 1 000℃.The effective factors on recovery ratio and purity of silver were studied.The chemical analysis proves that the purity of silver ingot is 95.86%.The recovery ratio of silver is calculated to be 92.56%.The loss of silver may be due to the loss of silver chloride during filtering and the volatilization of silver when silver chloride and sodium carbonate are smelted at high temperature.For other three metal elements,Y3 +,Ba 2+and Cu 2+,in the surplus waste liquid after recovering silver, they were separated with the sequence of barium,copper and then yttrium step by step.First,sulfate acid was used to precipitate barium sulfate.Then,sodium sulfide was added to the surplus solution so that copper could be separated as copper sulfide.During this separation procedure,it was important to control the pH value to be 1-2.After that,oxalic acid was added into the surplus solution to obtain yttrium oxalate.Finally,yttrium oxide was formed by burning yttrium oxalate.The XRD results indicate that the final products are all single-phase compounds as BaSO4,CuS and Y2O3,respectively.

Fabrication and thermo-physical properties of TiB_(2p)/Cu composites for electronic packaging applications

TiB_(2p)/Cu composites with high reinforcement content(φ_(p)=50%,58%and 65%)for electronic packaging applications were fabricated by squeeze casting technology.The microstructures and thermo-physical properties of the TiB_(2p)/Cu composites were investigated.The results show that TiB2 particles are homogeneous and distribute uniformly,and the TiB2-Cu interfaces are clean and free-from interfacial reaction products and amorphous layers,the densifications of the TiB_(2p)/Cu composites are higher than 98.2%. The mean linear coefficients of thermal expansion at 20-100℃for TiB_(2p)/Cu composites range from 8.3×10^(-6)to 10.8×10^(-6)/K and decrease with increasing volume fraction of TiB2.The experimental coefficients of thermal expansion agree well with the predicted values based on Turner’s model.The thermal conductivities of TiB_(2p)/Cu composites range from 167.3 to 215.4 W/(m·K),decreasing with increasing volume fraction TiB2.

Electrical Sliding Wear Properties of Mo-Reinforced MoS_2/Cu Composites

An adequate hardness of MoS2/Cu composites has not been achieved if these materials are applied under the extreme wear conditions. Therefore, Me-reinforced MoS2/Cu composites were prepared by powder metallurgy （P/M） methods. The electrical sliding wear properties in the absence or presence of Mereinforced MoS2/Cu composites were tested by HST-100 high speed electric-tribometer. The hardness, electrical conductivity, density, and microstmcture of MoS2/Cu composites were observed. Me-reinforcement MoS2/Cu composites are of good electrical conductivity, while the hardness of Mo-reinforcedment MoS2/Cu composites is about 33.3% higher than that of MoS2/Cu composites. With the addition of Me, composites show better wear properties under high speed and large electric current due to the improvement of hardness. The effects of current intensity and sliding velocity on the wear properties of the tested materials are complicated, and the wear mechanisms of MoS2/Cu composites are mainly abrasive wear and adhesive wear with arc erosion.

Preparation and electrochemical property of Cs0.35V2O5/Cu composite material

Cs0.35V2O5 was successfully synthesized as cathode material for lithium secondary battery by the rheological phase reaction method from Cs2CO3 and NH4VO3. The Cs0.35V2O5/Cu composite material was prepared by the displacement reaction in CuSO4 solution using zinc powder as a reductant. The structure and electrochemical property of the so-prepared powders were characterized by means of XRD （powder X-ray diffraction） and the galvanostatic discharge-charge techniques. The results show that the electrochemical property of Cs0.35V2O5/Cu composite material is significantly improved compared to the bulk Cs0.35V2O5 material. The Cs0.35V2O5/Cu composite material exhibits the first discharge capacity as high as 164.3 mAh.g -1 in the range of 4.2-1.8V at a current rate of 10 mA.g-1 and remains at a stable discharge capacity of about 110 mAh.g-1 within 40 cycles.

时效处理对Cu-Y_(2)O_(3)-Ti复合材料组织及性能的影响

以Cu、Y、Ti和CuO粉末为原料,采用机械合金化(MA)和热还原的方法制备了Cu-Y_(2)O_(3)-Ti复合粉末。然后经放电等离子烧结(SPS)技术制备了Cu-Y_(2)O_(3)-Ti复合材料,并对材料进行了900℃固溶1 h和不同温度时效2 h的处理。采用光学显微镜(OM)、扫描电镜(SEM)、X射线衍射仪(XRD)、能谱仪(EDS)、拉伸试验和导电率测量仪等研究了不同温度时效处理对Cu-Y_(2)O_(3)-Ti复合材料组织及性能的影响。结果表明:随着时效温度的升高,Cu-Y_(2)O_(3)-Ti复合材料的晶粒和第二相尺寸增大,导电率降低,最大应变和抗拉强度先增大后减小。Cu-Y_(2)O_(3)-Ti复合材料经900℃固溶1 h+400℃时效2 h后,综合性能最优,其具有良好塑性的同时,抗拉强度和导电率分别达到326.4 MPa和73.0%IACS。

La_(2)O_(3)掺杂Ti_(3)SiC_(2)/Cu复合材料的制备与性能

铜合金作为热管理材料长期服役时,会出现冷-热循环条件下的结构性失效问题,因此考虑将具有低膨胀系数的MAX相材料引入到铜合金中,来降低复合材料的热膨胀性。Ti_(3)SiC_(2)是一种兼具陶瓷和金属的优良特性的三元层状陶瓷材料,具有自润滑、高韧性、高导电性等特点。作为增强相,Ti_(3)SiC_(2)能够提高Cu基复合材料的摩擦性能,降低复合材料的热膨胀系数,因此被应广泛用于电子封装材料、热管理材料等领域。本文将稀土氧化物La_(2)O_(3)引入到Ti_(3)SiC_(2)/Cu复合材料中,研究了La_(2)O_(3)掺杂含量对Ti_(3)SiC_(2)/Cu复合材料物相组成、表面形貌、显微硬度和摩擦因数等的影响。研究发现,利用热压烧结技术能够获得致密度较高的Ti_(3)SiC_(2)/Cu复合材料,相对密度在98.5%以上。适量掺杂La_(2)O_(3)后,Ti_(3)SiC_(2)/Cu复合材料的显微硬度有所增加,能够实现Ti_(3)SiC_(2)/Cu复合材料的弥散强化。随着La_(2)O_(3)掺杂量增加,Ti_(3)SiC_(2)/Cu复合材料的摩擦因数呈现出先降低后增加的趋势。在Cu基复合材料中添加Ti_(3)SiC_(2),能够起到润滑的作用,有利于降低摩擦因数。本研究可为Ti_(3)SiC_(2)/Cu复合材料的工程应用提供试验依据。

HfO_(2)掺杂对湿化学法制备W-20Cu复合材料微观组织和性能的影响

采用湿化学法制备W-20Cu复合粉体,通过喷雾干燥法得到球壳状前驱体,再通过氢气还原成功将弥散分布的HfO_(2)第二相颗粒引入W-20Cu复合粉体,确定了引入的HfO_(2)在W-20Cu复合粉体中的存在形式以及分布状态。采用高温液相烧结制备了细小HfO_(2)颗粒均匀分布的W-20Cu复合材料。结果表明:由于HfO_(2)颗粒在W颗粒表面和W/Cu界面间隙中弥散分布,抑制了W颗粒在烧结过程中的粗化,从而降低了W-W的连通性,使得W-20Cu复合材料表现出较高的综合性能。其中,烧结温度在1350℃时,块体的致密度较高,均为97%,掺杂0.5%HfO_(2)制备得到的复合材料综合性能最佳,其硬度最大可达到338HV,抗弯强度为826 MPa,热导率为209 W/(m·K)。

Al_(2)O_(3)-Cu/25Cr复合材料的热变形行为与热加工图

采用内氧化-快速热压烧结方法制备了Al_(2)O_(3)-Cu/25Cr复合材料,利用Gleeble-1500D型热模拟试验机对其进行热变形试验(变形温度为600~900℃,变形速率为0.001~1 s^(-1)),绘制了其真应力-真应变曲线,根据双曲正弦模型计算了复合材料的热变形激活能和本构方程,得到了Al_(2)O_(3)-Cu/25Cr复合材料热变形过程的热加工图。结果表明:Al_(2)O_(3)-Cu/25Cr复合材料的热变形激活能为287.227 kJ/mol,根据热加工图,确定了复合材料最佳的热加工工艺参数为变形温度为800~900℃、变形速率为0.25~1 s^(-1)。

超音速激光沉积Cu-Al_(2)O_(3)-石墨复合涂层微观结构及耐磨损性能

目的研究不同石墨含量对超音速激光沉积Cu-Al_(2)O_(3)-石墨复合涂层的微观组织、显微硬度、耐磨损性能的影响。方法利用扫描电子显微镜、能量色谱仪、维氏硬度计、激光共聚焦扫描显微系统、X射线衍射仪、摩擦磨损测试对复合涂层的微观组织、显微硬度、耐磨损性能及磨损机制进行分析。结果随着原始粉末中镀铜石墨质量占比的增加,Cu-Al_(2)O_(3)-石墨复合涂层的沉积效率逐渐降低。基于Al_(2)O_(3)颗粒的原位喷丸效应及激光辐照的加热软化效应,复合涂层具有致密的微观组织,且复合涂层与基体界面结合良好。单一添加Al_(2)O_(3)颗粒可以将Cu涂层的硬度从108.19HV0.2提高至121.82HV0.2。随着石墨含量的增大,涂层的显微硬度逐渐降低,镀铜石墨在原始粉末中的质量分数从5%增至15%,Cu-Al_(2)O_(3)-石墨复合涂层的硬度从116.09HV0.2降至94.17HV0.2。添加石墨能够在复合涂层表面形成固体润滑层,降低复合涂层的摩擦因数,提升涂层的耐磨损性能。CuAlGr10复合涂层具有最优的耐磨损性能,磨损率为0.7×10^(−4)mm^(3)/(N·m)。此外,由于激光辐照促进了复合涂层内部颗粒间的界面结合,均匀分散在石墨润滑相中的Al_(2)O_(3)颗粒作为负载支撑和耐磨相,可进一步降低复合涂层的磨损率。结论Cu-Al_(2)O_(3)-石墨复合涂层优异的耐磨性能是润滑相石墨颗粒和硬质增强相Al_(2)O_(3)颗粒共同作用的结果,石墨的添加能够降低复合涂层的摩擦因数,提升涂层的耐磨损性能,但过量的石墨颗粒会对涂层产生割裂作用,导致增强相Al_(2)O_(3)颗粒脱离涂层,从而加剧涂层的磨损。