High corrosion and wear resistant electroless Ni–P gradient coatings on aviation aluminum alloy parts

A Ni–P alloy gradient coating consisting of multiple electroless Ni–P layers with various phosphorus contents was prepared on the aviation aluminum alloy. Several characterization and electrochemical techniques were used to characterize the different Ni–P coatings’ morphologies, phase structures, elemental compositions, and corrosion protection. The gradient coating showed good adhesion and high corrosion and wear resistance, enabling the application of aluminum alloy in harsh environments. The results showed that the double zinc immersion was vital in obtaining excellent adhesion (81.2 N). The optimal coating was not peeled and shredded even after bending tests with angles higher than 90°and was not corroded visually after 500 h of neutral salt spray test at 35℃. The high corrosion resistance was attributed to the misaligning of these micro defects in the three different nickel alloy layers and the amorphous structure of the high P content in the outer layer. These findings guide the exploration of functional gradient coatings that meet the high application requirement of aluminum alloy parts in complicated and harsh aviation environments.

Tribological Behaviors of Electroless Nickel-Boron Coating on Titanium Alloy Surface

Titanium alloys are excellent structural materials in engineering fields,but their poor tribological properties limit their further applications.Electroless plating is an effective method to enhance the tribological performance of alloys,but it is difficult to efficiently apply to titanium alloys,due to titanium alloy’s strong chemical activity.In this work,the electroless Nickel-Boron(Ni-B)coating was successfully deposited on the surface of titanium alloy(Ti-6AL-4V)via a new pre-treatment process.Then,linearly reciprocating sliding wear tests were performed to evaluate the tribological behaviors of titanium alloy and its electroless Ni-B coatings.It was found that the Ni-B coatings can decrease the wear rate of the titanium alloy from 19.89×10^(−3)mm^(3)to 0.41×10^(−3)mm^(3),which attributes to the much higher hardness of Ni-B coatings.After heat treatment,the hardness of Ni-B coating further increases corresponding to coating crystallization and hard phase formation.However,heat treatment does not improve the tribological performance of Ni-B coating,due to the fact that higher brittleness and more severe oxidative wear exacerbate the damage of heat-treated coatings.Furthermore,the Ni-B coatings heat-treated both in air and nitrogen almost present the same tribological performance.The finding of this work on electroless coating would further extend the practical applications of titanium alloys in the engineering fields.

XPS Studies on Electroless As-Deposited and Annealed Ni-P Films

Electroless deposition has been used to deposit Ni-P films on glass slides using the reducing agent sodium hypophosphite. This has been done with a purpose to use Ni-P films as back contact for silicon carbide radiation detectors. By keeping deposition time, temperature, pH and concentration of the precursor solution constant, the film deposition has been done. XPS studies were done to analyze the composition and stoichiometry of Ni-P thin films.

XPS Study of Electroless Deposited Sb2Se3 Thin Films for Solar Cell Absorber Material

As a thin film solar cell absorber material, antimony selenide (Sb2Se3) has become a potential candidate recently because of its unique optical and electrical properties and easy fabrication method. X-ray photoelectron spectroscopy (XPS) was used to determine the stoichiometry and composition of electroless Sb2Se3 thin films using depth profile studies. The surface layers were analyzed nearly stoichiometric. But the abundant amount of antimony makes the inner layer electrically more conductive.

Depth Profile Study of Electroless Deposited Sb2S3 Thin Films Using XPS for Photovoltaic Applications

Sb2S3 has gained tremendous research recently for thin film solar cell absorber material because of their easy synthesis, unique electrical and optical properties. The stoichiometry and composition of electroless Sb2S3 thin films were analyzed using XPS depth profile studies. The surface layers were found nearly stoichiometric. On the other hand, the inner layer was rich in antimony composition making it more conductive electrically.

Pd-ZSM-5复合膜的制备及其氢气分离性能

为了能够在大孔氧化铝载体表面得到透氢性能良好的钯膜,利用二次生长法在多孔Al_(2)O_(3)载体上生长出一层连续完整的ZSM-5沸石分子筛修饰层,通过化学镀过程在ZSM-5沸石分子筛修饰的载体上沉积一层钯膜,从而得到Pd-ZSM-5复合膜。利用扫描电子显微镜(SEM)对载体、ZSM-5沸石分子筛修饰后的载体和Pd-ZSM-5复合膜的形貌进行详细分析,并通过X线能量色散光谱(EDX)对Pd-ZSM-5复合膜的表面和截面元素分布进行了研究。而且,为了确定该Pd-ZSM-5复合膜的H_(2)渗透性能,在623~773 K范围内,研究了操作温度、操作时间和测试压力对Pd-ZSM-5复合膜透氢性能的影响。研究结果表明,ZSM-5沸石分子筛修饰层能够有效改进载体的表面粗糙度和降低其表面孔径,有助于Pd膜的沉积。所制备的Pd-ZSM-5复合膜表面完整、致密,Pd膜层厚度约为5μm, ZSM-5沸石修饰层厚度约为3μm。当操作温度为773 K、渗透压力为0.1 MPa时,Pd-ZSM-5复合膜的H_(2)渗透通量和H_(2)/N_(2)渗透选择性分别为0.113 mol/(m·s)和468。而且,该Pd复合膜在773 K下,连续操作300 h后,其H_(2)渗透性能保持相对稳定。

热致液晶高分子膜的表面处理及化学镀铜

论文采用氢氧化钠(NaOH)溶液对Vecstar型热致液晶高分子(TLCP)膜表面进行刻蚀粗化,然后通过3-氨丙基三乙氧基硅烷(KH550)在膜表面引入氨基,利用氨基络合银离子使膜表面活化,再进行无钯化学镀铜,提升了TLCP膜与金属铜之间的黏附力。借助扫描电子显微镜(SEM)、接触角测量仪、X射线衍射仪(XRD)和剥离测试等对经表面处理及化学镀铜后的TLCP膜进行表征,探讨了NaOH溶液浓度、表面粗化温度和时间、活化溶液组成等对TLCP表面化学镀铜的影响。结果表明,经表面处理后TLCP膜表面产生均匀的孔洞,接触角下降至29.30°,亲水性大幅提高;所镀铜层呈光亮的粉色,带有金属光泽,致密平滑,纯度高,镀层厚度可达2.78μm,与TLCP膜间的附着力等级达到了5B。

Synthesis,Structural Characterization and Hydrogen Storage of Nickel-containing Mesoporous MCM-48 by Electroless Plating

Hydrogen is a promising fuel for it is clean,highly abundant and non-toxic,but on-board storage of hydrogen is still a challenge.So it is imperative to have an efficient method of hydrogen storage.The mesoporous MCM-48 especially the nickel-containing MCM-48 has great potential in hydrogen storage.MCM-48 was prepared by hydrothermal synthesis.Then electroless plating technology was used to deposit Ni on the surface of MCM-48 under ultrasonic environment.Powder X-ray diffraction（XRD）,transmission electron microscopy（TEM）,and N2 adsorption-desorption were employed to investigate the pore structure properties.The results showed that all the samples had Ia3 d cubic structure and pore channels were highly ordered.Hydrogen adsorption studies showed that the MCM-48 after nickel plating adsorbed nearly twice the amount of hydrogen than pure MCM-48 at 2.0 MPa,263 K.So we believe that a small amount of Ni can improve the capacity of hydrogen adsorption of MCM-48 efficiently.

紫外辐照与壳聚糖接枝联合处理对ABS表面改性效果的影响

聚丙烯腈-丁二烯-苯乙烯(ABS)是一种应用广泛的工程塑料。将绿色环保的紫外光辐照表面修饰技术与壳聚糖接枝处理技术相结合对ABS基板表面进行改性处理,探究了紫外光辐照条件、壳聚糖醋酸溶液的浓度、改性温度和改性时间对ABS基板表面形貌、表面粗糙度、表面亲水性和表面化学性质的影响。首先使用2 g/L的二氧化钛(TiO_(2))作为光催化剂在300 W下对ABS进行光辐照处理30 min,然后利用0.75 g/L的壳聚糖醋酸溶液在70℃下改性处理30 min,通过扫描电镜(SEM)、原子力显微镜(AFM)观察ABS基板表面形貌变化,并利用表面接触角测量仪和X射线光电子能谱(XPS)分析ABS基板表面亲水性能的变化。结果表明,经过紫外光辐照和壳聚糖接枝改性处理后,ABS基板处理后表面形成少量微小孔洞,表面粗糙度较小,但是ABS基板表面亲水基团的浓度大幅增加,表面亲水性明显增强,化学镀铜层光滑平整,颜色粉红,具有金属光泽。

PCB化学镀铜新型稳定剂配方与工艺研究

考察了在以EDTA为主络合剂、三聚甲醛为还原剂、酒石酸钾钠为辅助络合剂的化学镀铜基础液里甲醇含量和添加剂盐酸胍、亚铁氰化钾、1,1-联吡啶对镀液性能的影响,同时研究了其中任何一种化合物含量的变化对印刷电路板镀性的影响,得到了适宜的配方和试验条件,实验结果表明:配方中各种添加剂对镀液性能的影响程度不同,少量甲醇的添加能显著抑制甲醛的分解,聚甲醛的使用较甲醛方便,改善了操作环境。添加稳定剂明显改善了镀液的性能,镀液温度可以提高到50℃,生产效率提高。

碳纳米管增强硬质合金的制备及性能研究

为改善硬质合金中增强体碳纳米管(carbon nanotubes,CNTs)的团聚问题,采用化学镀Ni方法对CNTs进行表面改性,利用气压烧结工艺制备了WC-10Co-CNTs硬质合金和WC-10CoCNTs/Ni硬质合金。对镀Ni前后CNTs的表面形貌、结构及成分进行了分析表征,并研究了CNTs和CNTs/Ni对硬质合金组织及性能的影响。结果表明,CNTs经化学镀改性处理后,表面包覆了致密的纳米Ni颗粒,团聚现象明显改善;在WC-10Co中添加CNTs或CNTs/Ni后可以有效地细化硬质合金的晶粒,降低孔隙率;和未添加的比较,添加质量分数0.1%的CNTs的硬质合金和添加质量分数0.1%的CNTs/Ni的硬质合金抗弯强度分别提高了17.5%和28.2%,热扩散系数分别提高了23.5%和42.8%。

挠性印制电路板细线路微蚀及化学镀镍工艺研究

[目的]化学微蚀作为前处理工艺,被广泛应用在印制电路板(PCB)制造的各大环节。[方法]分别采用硫酸-过硫酸钠(用SA-SP表示)、硫酸-双氧水(用SA-HP表示)和甲酸-氯化铜(用FA-CC表示)3种体系对挠性印制电路板(FPCB)的细线路进行微蚀。通过激光光谱共聚焦显微镜(LSCM)对比了采用不同体系时的微蚀量、微蚀速率及微蚀后线路的表面粗糙度。通过扫描电镜(SEM)研究了不同微蚀体系处理前后铜线路的表面形貌,以及微蚀液对化学镀镍的影响。[结果]3种体系微蚀能力大小顺序为:SA-SP>SA-HP>FA-CC。采用不同微蚀液时铜线的表面粗糙度均随微蚀时间延长而增大。采用甲酸-氯化铜体系微蚀后铜线表面有少量氯化亚铜形成。微蚀液对化学镀镍效果的影响显著。采用硫酸-双氧水体系微蚀时镍镀层光亮,但有渗镀现象;采用甲酸-氯化铜体系微蚀时,化学镍渗镀现象严重;采用硫酸-过硫酸钠微蚀时,细线路化学镍渗镀现象得到有效控制,但镀层较暗。[结论]可尝试通过在化学镀镍液中添加光亮剂来提高镀层光亮度。

Ta/Ta_(2)O_(5)/Cu结构制备及应用性能研究

介绍了以Ta/Ta_(2)O_(5)/Cu为结构的平板MIM电容器的制备方法和性能测试,探究金属Cu直接作为钽电解电容器阴极层的可行性。通过阳极氧化法在钽箔表面制备非晶态的Ta_(2)O_(5)薄膜,以化学镀铜、磁控溅射镀铜两种镀铜工艺制备Ta/Ta_(2)O_(5)/Cu结构,并对所得结构进行结构表征和性能测试。实验结果表明:不同镀铜方式制备的Ta/Ta_(2)O_(5)/Cu结构在电学性能测试过程中都没有表现出电容特性,正负极之间的电阻仅有0.7Ω;以金属Cu直接作为钽电容器的阴极层会导致金属铜在测试过程中被氧化成铜离子从而进入Ta_(2)O_(5)介质层中,进而导致Ta_(2)O_(5)的击穿,因此金属铜不适合直接作为钽电容的阴极层。

AZ31B镁合金表面镍基复合镀层的制备及耐蚀性能研究

为了提高镁合金的耐腐蚀性,以AZ31B镁合金为基体,采用化学镀与脉冲电镀技术在其表面制备了Ni-P/Ni复合镀层。采用扫描电镜(SEM)、X射线衍射(XRD)分析了镀层表面的形貌和成分。通过电化学极化、阻抗测试和接触角研究了该复合镀层的耐腐蚀性和疏水性。结果表明:峰值电流密度为30 mA/cm^(2)时,镀层的晶粒最细致,接触角最高为117.3°,自腐蚀电位最高(-0.4510 V),腐蚀电流密度最低(1.94×10^(-7)A/cm^(2)),阻抗值最大,明显优于镁合金基体,这说明该复合镀层可提高镁合金疏水性和耐腐蚀性。

化学沉淀法去除化学镀镍废液中磷的工艺研究

[目的]对化学镀镍废液中的含磷物质进行正确处理和有效回收是实现可持续发展的有效策略。[方法]采用化学沉淀法处理化学镀镍废液,使其中的磷以羟基磷灰石(HAP)沉淀形式得以回收。研究了反应温度、初始pH及Ca/P比(指硝酸钙与废液中磷的质量比)对磷去除率的影响,通过正交试验优化工艺参数。[结果]在温度为75℃、初始pH为12及Ca/P比为1.67的条件下处理后,化学镀镍废液的磷去除率达到了99.998%,并且所得沉淀为HAP。[结论]采用本工艺可有效去除化学镀镍废液中的磷,并且随之产生的HAP有望得以回收利用。

Sn95Sb5焊料与ENIG/ENEPIG镀层焊点界面可靠性研究

研究了Sn95Sb5焊料在化学镍金(ENIG)镀层、化学镍钯浸金(ENEPIG)镀层表面形成的焊点界面微观组织形貌与剪切强度。使用Sn95Sb5焊料在FR4印制板上焊接0805片式电容,焊点在高温时效测试和温度循环过程中均表现出较高的剪切强度,焊点界面连续且完整,剪切强度下降的最大幅度不超过19.2%。Sn95Sb5焊料在ENIG镀层表面形成的焊点(Sn95Sb5/ENIG焊点)强度更高。Sn95Sb5焊料在ENEPIG镀层表面形成的焊点(Sn95Sb5/ENEPIG焊点)界面反应更为复杂,在焊点界面附近可观察到条块状的(Pd,Ni,Au) Sn4。Sn95Sb5/ENEPIG焊点界面的金属间化合物层平均厚度约为Sn95Sb5/ENIG焊点界面的2倍。

PCB化学镀铜废液中铜的资源化回收工艺研究

[目的]化学镀铜废液含有高浓度重金属离子,属于危险废物,给环境保护带来巨大压力。[方法]基于破络沉淀的原理处理化学镀铜废液,以回收其中的铜。研究了不同促进剂、促进剂投加量、初始pH和反应时间对铜回收效果的影响,再进一步通过正交试验对回收工艺进行优化。[结果]最优的工艺条件为:促进剂CAT-2投加量10 g/L,初始pH 14.0,反应时间48 h。在该条件下处理后废液的总铜浓度由初始的3 680 mg/L降至1.00 mg/L,铜回收率达到99.97%。[结论]采用破络沉淀法可实现对化学镀铜废液中铜的有效回收,有利于提高资源利用率,降低企业生产成本。

低浓度硫酸铜对化学镀Ni-P镀层微观结构及性能的影响

为改善镍磷(Ni-P)镀层的表面质量、提高Ni-P镀层的性能,在化学镀Ni-P镀液中加入少量的硫酸铜(CuSO_(4)·5H_(2)O)制备Ni-P镀层。利用扫描电镜、能谱仪、X射线衍射仪分析了镀层的表面形貌、成分和结构,研究了CuSO_(4)·5H_(2)O浓度对镀层的微观结构、表面粗糙度、光泽度、硬度、耐磨性和耐蚀性的影响。研究表明:当CuSO_(4)·5H_(2)O浓度为0.1 g/L时,镀层为致密的非晶态节瘤状组织,具有最佳的耐蚀性;当CuSO_(4)·5H_(2)O浓度为0.2 g/L时,镀层表面质量最好,硬度高、耐磨性优异,但镀层中出现少量微晶态Ni-Cu固溶体,耐蚀性下降;当CuSO_(4)·5H_(2)O浓度超过0.2 g/L后,镀层为混晶态菜花状组织,镀层表面的质量和耐蚀性随CuSO_(4)·5H_(2)O浓度的增加不断恶化。

镀银石墨粉制备银石墨复合材料的微观结构和性能

银石墨复合材料是一种具有理想综合性能的电接触材料。为了解决复合材料中石墨分布不均匀,界面结合较弱的问题,通过在石墨表面预先镀铜,再镀银的两步化学镀法,制备镀层致密均匀的预镀铜-镀银石墨粉,并采用热压烧结方式制备高性能银石墨复合材料。结果表明:预镀铜工艺的引入能改善复合材料中石墨的分布均匀性,减少界面处的孔隙和裂纹等缺陷,提高材料的致密度,并且使银基体在石墨颗粒周围形成连续的三维网状结构,有效提升复合材料的力学性能和导电性能。与活化-镀银石墨复合材料相比,预镀铜-镀银石墨复合材料的硬度(HV)由22.9提高至33.0,提升了44.1%;抗弯强度由70.4 MPa提高至97.2MPa,提升了38.1%;电阻率则由0.11μΩ·m降低至0.08μΩ·m。

适用于航空航天铝合金件的镀多层镍工艺

[目的]航空航天铝合金件镀镉工艺亟需找到环保的替代技术。[方法]制定了一种镀多层镍工艺,其工艺流程主要包括化学除油、超声波除油、碱腐蚀、出光、除垢、微腐蚀、第一次沉锌、退锌、第二次沉锌、化学预镀镍、镀半光亮镍、镀高硫镍、镀光亮镍、稀土电解保护和烘干。[结果]这种镀层在进行168h中性盐雾试验后无锈蚀,220℃热震试验中无起泡和脱落,在温度40℃和相对湿度93%的条件下进行的1000h恒定湿热试验后无可见变化。[结论]该工艺克服了单一化学镀镍层对铝合金基体无电化学保护作用的缺点,并以新开发的稀土电解保护工艺代替了传统的铬酸盐电解保护法,绿色环保,具有良好的应用前景。