Sn-Zn-Bi-(P,Nd)无铅钎料的微观组织及性能

研究了复合加入P,Nd元素的Sn-8Zn-3Bi钎料的微观组织、力学性能、抗氧化性及润湿性.结果表明,单独加入元素P会导致Sn-8Zn-3Bi钎料组织中出现初生Zn相,而同时加入元素P和Nd不仅能够抑制初生Zn相的形成,钎料组织也能够得到细化,因此钎料的塑性提高,断后伸长率达到48%.P,Nd元素的复合添加能够在钎料表面形成稳定的扩散阻挡层,抑制P元素在长时间加热条件下的烧损,进一步降低表面的氧化速度.由于钎料的抗氧化性提高,Sn-8Zn-3Bi-0.1P-0.05Nd钎料呈现出更好的润湿性.     

The Inhibition of Tin Whiskers on the Surface of Sn-8Zn-3Bi-0.5Ce Solders

Through the refinement of the (Ce, Zn)Sn₃ intermetallic phase, the formation of tin whiskers, previously observed on the surface of a Sn-3Ag-0.5Cu-0.5Ce solder, was prevented in a Sn-9Zn-0.5Ce alloy. However, whisker growth can still occur on the surface of Sn-8Zn-3Bi-0.5Ce solder after air storage at room temperature and at 150 °C due to the formation of large (Ce, Zn)Sn₃ intermetallic clusters. Further experiments showed that decreasing the Bi-content in this Sn-8Zn-0.5Ce alloy to 1 and 2 wt.% can recover the beneficial effects of Zn additions on the refinement of the (Ce, Zn)Sn₃ phase and obviously reduce the appearance of tin whiskers. In addition, alloying the Sn-8Zn-3Bi-0.5Ce solder with 0.5 wt.% Ge, which increases the oxidation resistance of the (Ce, Zn)Sn₃ intermetallic clusters, can also effectively inhibit tin whisker growth.     

铋和磷元素对Sn-Zn-RE电子微连接钎料组织与性能的影响

制备了含不同Bi,P元素的（Sn-9Zn0.05Ce）xBi和（Sn-9Zn0.05Ce）xP钎料合金,观察并分析了钎料的显微组织形貌,测试了钎料的抗拉强度、断后伸长率以及维氏硬度.结果表明,添加Bi元素能显著提高Sn-9Zn0.05Ce钎料合金的抗拉强度和硬度,但同时会明显降低其断后伸长率,而添加微量P元素对钎料的抗...     

硼酸铝晶须对Sn-58Bi/Cu界面金属间化合物 层演变及剪切行为的影响

研究了硼酸铝晶须对Sn-58Bi/Cu界面金属间化合物(IMC)层组织演变的影响.结合钎焊接头显微组织、剪切性能以及断口形貌,分析了Sn-58Bi-1.2%Al₁₈B₄O₃₃钎焊接头的断裂机理.结果表明,硼酸铝晶须的加入可以细化钎料组织,抑制大块富铋相的出现;钎料/基板界面IMC层厚度和晶粒粒径均随着重熔次数的增加而增大,但硼酸铝晶须的加入能够阻碍界面IMC层的增厚和晶粒粗化,提高钎焊接头的性能;不同重熔次数下Sn-58Bi-1.2% Al₁₈B₄O₃₃/Cu钎焊焊点比Sn-58Bi/Cu钎料焊点能承受更高的剪切载荷,且经过多次重熔后接头强度保持稳定.     

Effect of Nd and La on surface tension and wettability of Sn-8Zn-3Bi solders

Maximum bubble pressure measurement was employed to evaluate surface tension of Sn-8Zn-3Bi- （0-0.15）Nd and Sn-8Zn-3Bi-（0 -0. 15）La solder melts. Wetting balance method was used to measure wetting force and wetting time on Cu substrate of the two group solders. The experimental results show that minute amount of Nd or La addition to Sn-8Zn-3Bi solder causes significant decrease of the surface tension of the solder melts at 200 - 240 ℃ and Nd addition is more effective on reduction of surface tension than that of La. Nd or La addition has the effect on enhancing the wetting force of the solder melts on Cu substrate, which results from the de- crease of interracial tension between the solder melt and Cu substrate. The wetting force reaches the maximum when 0.1% Nd is added to the base alloy. The contact angle between Sn-8Zn-3Bi base solders and Cu substrate decreases with the addition of Nd or La and the minimum of the contact angle is obtained from the solder with 0.1% Nd addition.     

Sn-6Bi-2Ag(Cu, Sb)无铅钎料合金微观组织分析

利用差示扫描量热计 (DSC)测定了Sn 6Bi 2Ag ,Sn 6Bi 2Ag 0 .5Cu ,Sn 6Bi 2Ag 2 .5Sb三种新无铅钎料合金的熔化温度。结果表明 ,少量Cu的加入能降低Sn Bi Ag系无铅钎料合金的熔化温度 ,而Sb的加入使合金的熔化温度升高。利用光学显微镜 (OM )、扫描电子显微镜 (SEM )、能谱分析 (EDX)对合金的微观组织进行了分析与比较 ,钎料合金的微观组织与冷却条件和合金元素的含量有关 ,Sb的加入使析出相的尺寸细化。硬度测定表明Sn Bi Ag(Cu ,Sb)无铅钎料合金的硬度远大于纯Sn的硬度 ,加入少量的Cu(0 .5 % ) ,Sb(2 .5 % )对Sn Bi Ag系钎料合金的硬度影响较小     

High-Temperature Oxidation of a Sn-Zn-Al Solder

The oxidation of 91Sn-9(95Zn-5Al) solder in theliquid state, 250°C, was studied by thermalgravimetric analysis (TGA). The oxidation behavior of63Sn-37Pb, 91Sn-9Zn, 99.4Sn-0.6Al, and Sn was alsoinvestigated for comparison. The weight gains per unitsurface area descend in the order: 63Sn-37Pb > Sn> 91Sn-9Zn > 91Sn-9(95Zn-5Al) > 99.4Sn-0.6Al.The initial weight gains of the materials investigated increase linearly with reaction time, whileparabolic behavior exists after the linear stage. Therate constants of the oxidation reaction for the tworeaction stages were determined. Activation energies for oxidation of the five materials weredetermined in the range of 250 to 400°C. Theactivation energies, derived from the linear rateconstants for the early stages of oxidation, are 27.7kJ/mole for 99.4Sn-0.6Al, 23.3 kJ/mole for 91Sn-9Zn, 21.4kJ/mole for 91Sn-9(95Zn-5Al), 20.5 kJ/mole for63Sn-37Pb, and 19.8 kJ/mole for Sn. Thesurface-oxidation behavior was investigated further withelectron spectroscopy for chemical analysis (ESCA) and Auger electronspectroscopy (AES). AES profiles showed that oxides ofZn and Al formed on 91Sn-9Zn and 91Sn-9(95Zn-5Al)solders, while tin oxide is formed on 63Sn-37Pbsolder.     

In对Sn-8Zn-3Bi无铅钎料润湿性的影响

首先采用铺展法测试了Sn-8Zn-3Bi-(0～5)In钎料合金的铺展性.结果表明,少量In的加入提高了钎料的润湿性.当In含量达到0.5%时(质量分数,下同),钎料在铜基底上的铺展面积最大.采用气泡最大压力法对Sn-8Zn-3Bi-(0～1.5)In钎料熔体进行了表面张力测试.加入0.5%的In大大降低了Sn-8Zn-3Bi钎料熔体的表面张力,但进一步增加In的含量导致熔体表面张力增大.最后采用润湿平衡法对上述钎料进行了润湿力测试.结果表明0.5%In的加入使合金的润湿力达到最大,其原因是钎料/铜界面的界面张力减小.     

热循环对Sn58Bi(纳米Ti)/Cu焊点界面与性能影响

为了改善Sn-58Bi低温钎料的性能,通过在Sn-58Bi低温钎料中添加质量分数为0.1%的纳米Ti颗粒制备了Sn-58Bi-0.1Ti纳米增强复合钎料。在本文中,研究了纳米Ti颗粒的添加对-55～125 _^oC热循环过程中Sn-58Bi/Cu焊点的界面金属间化合物(IMC)生长行为的影响。研究结果表明：回流焊后,在Sn-58Bi/Cu焊点和Sn-58Bi-0.1Ti/Cu焊点的界面处都形成一层扇贝状的Cu₆Sn₅ IMC层。在热循环300次后,在Cu₆Sn₅/Cu界面处形成了一层Cu₃Sn IMC。Sn-58Bi/Cu焊点和Sn-58Bi-0.1Ti/Cu焊点的IMC层厚度均和热循环时间的平方根呈线性关系。但是,Sn-58Bi-0.1Ti/Cu焊点的IMC层厚度明显低于Sn-58B/Cu焊点,这表明纳米Ti颗粒的添加能有效抑制热循环过程中界面IMC的过度生长。另外计算了这两种焊点的IMC层扩散系数,结果发现Sn-58Bi-0.1Ti/Cu焊点的IMC层扩散系数(整体IMC、Cu₆Sn₅和Cu₃Sn IMC)明显比Sn-58Bi/Cu焊点小,这在一定程度上解释了Ti纳米颗粒对界面IMC层的抑制作用。     

氧含量对Sn-9Zn-2.5Bi-1.5In低温波峰焊焊接性能的影响

制备了一种新型Sn-9Zn-2.5Bi-1.5In钎料，开发了一套波峰焊氮气保护系统，考察了该钎料在不同氧含量的环境下的焊接质量. 结果表明，开发的氮气保护系统通过增加氮气流量可以将焊接区域内的动态氧含量降低到0.06%以下. 降低焊接区氧含量，可显著减少桥连、填充不良、气孔3类缺陷的数量，将不良率控制在0.20%以内. 在氧含量0.50%的临界值以下，该钎料可在锡炉设定温度为225 ℃的条件下进行低温焊接，焊接效果满足规模化生产需求. 通过能谱分析发现氧化物表面Zn元素含量比Sn-9Zn-2.5Bi-1.5In钎料升高84.9%，Zn元素的易氧化倾向是导致钎料形成大量氧化渣的主要原因. 降低焊接区域的氧含量可以有效抑制氧化渣的形成.采用氮气保护的方法可以解决Sn-Zn钎料在高氧环境下易出现的焊接缺陷问题，从而实现225 ℃低温波峰焊.     

Al元素对亚共晶SnBi钎料接头组织及力学性能影响

通过向亚共晶Sn30Bi钎料中添加Al元素,制备新型Sn-30Bi-xAl低温无铅钎料,采用扫描电镜和拉伸力学实验等研究了时效前后Sn30Bi-Al钎料合金的微观组织及力学性能。结果表明:向亚共晶Sn30Bi钎料中加入Al元素,能够一定程度上抑制焊后接头中形成网状共晶组织,以及Bi相团聚,当Sn30Bi-Al合金中Al元素含量为0.3%时,对网状共晶组织形成和Bi相团聚的抑制作用最佳;在时效过程中,向Sn30Bi合金中添加Al元素,能够一定程度上抑制Bi相团聚,降低界面IMC层生长速率;当Al含量为0.3%时,Sn30Bi-0.3Al接头的力学性能最佳。     

凝固条件和应变速率对Sn-58Bi钎料拉伸性能和断裂行为的影响

研究了熔炼制备的Sn-58Bi无铅钎料于水冷、空冷、炉冷三种方式冷却后在应变速率0.001,0.002,0.004 s−1下的拉伸性能和断裂行为. 结果表明,水冷和空冷钎料共晶组织细小,尤其是空冷钎料共晶组织更为均匀,而炉冷钎料共晶组织粗大且偏析严重. 随着应变速率增大,三种钎料抗拉强度均提高而断后伸长率均变小. 炉冷钎料组织偏析导致硬脆富Bi相聚集,抗拉强度最大,但断后伸长率极低,为典型的脆性断裂;水冷和空冷钎料的均细共晶组织显著提高了钎料断后伸长率,具有更均匀共晶组织的空冷钎料断后伸长率最大,呈现韧性或韧脆性混合断裂.     

稀土铈在Sn-Zn无铅钎料表面的高温氧化行为

通过俄歇电子能谱法和X射线光电子能谱法研究了Sn-9Zn-0.15Ce和Sn-9Zn-0.002Al-0.2Ga-0.25Ag-0.15Ce两种钎料表面Ce元素的分布和存在形式.结果表明,铈在Sn-9Zn-0.15Ce钎料表面0~40 nm范围内的富集区浓度达到30%(原子分数)左右,是基体内部的250倍,主要以CeO2和Ce2O3形态存在.在Sn-9Zn-0.15Ce钎料中复合添加镓和铝后,Ga元素在钎料表面0~6 nm范围内富集,Al元素在表面2~20 nm范围内富集并主要以氧化态形式存在.Ce元素富集在距离钎料表面2~60 nm的范围内,处于Ga,Al元素富集层的下方;由Ga,Al元素富集层构成的致密保护膜可显著降低表面铈被氧化的概率.     

Sn-9Zn系无铅焊料钎焊接头剪切性能的研究

利用扫描电镜及万能材料实验机研究了Sn-9Zn/Cu钎焊接头的界面形貌及Sn-9Zn焊料微合金化前后钎焊接头的剪切性能变化。结果表明,Sn-9Zn/Cu界面金属间化合物为Cu5Zn8,界面层呈平整的锯齿状。由于焊接时没有保护气氛,以致Sn-9Zn氧化而使剪切性能变差,而同时添加微量RE和Ag或RE和Al元素后剪切强度大幅度增高,尤其是添加0.025%RE和0.3%Ag时剪切强度可提高46.47%,同时添加元素后剪切断口韧性断裂趋势增大。     

Ag的添加量对Sn-9Zn无铅钎料性能的影响

研究Ag的添加量对Sn-9Zn无铅钎料性能的影响规律。结果表明,Ag不仅对Sn-9Zn无铅钎料的润湿性能和显微组织有明显作用,而且对钎料接头的力学性能也有较大的影响。添加0.3%Ag (质量分数, 下同)后,钎料的抗氧化性能得到提高,因此钎料的润湿性能得到改善。Sn-9Zn-0.3Ag具有比Sn-9Zn钎料更均匀的组织。研究结果还表明,添加0.3%Ag后,钎料接头的力学性能最佳,接头断口显示有大量的细小均匀的韧窝组织。当Ag的添加量添加到1%时,在韧窝底部出现Cu-Zn、Ag-Zn金属间化合物,此时,接头力学性能下降     

ZL102合金用低温软钎料的研究

Sn-9Zn共晶钎料可以用于钎焊钎焊性极差的铸造铝合金ZL102，在Sn-9Zn钎料的基础上添加In元素，以提高钎料对ZL102合金的润湿。本文对Sn-9Zn和Sn-9Zn-5In两种软钎料对ZL102合金润型，界面结合等方面进行研究，分析实验结果可知，Sn-9Zn-5In钎料的性能优于Sn-9Zn共晶钎料。     

Effects of Ga,Al, Ag,and Ce multi-additions on the wetting characteristics of Sn-9Zn lead-free solder

An orthogonal method was used to evaluate the effects of Ga, Al, Ag, and Ce multi-additions on the wetting characteristics of Sn-9Zn lead-free solders by wetting balance method. The results show that the optimal loading of Ga, Al, Ag, and Ce was 0.2 wt.%, 0.002 wt.%, 0.25 wt.%, and 0.15 wt.%, respectively. Intermetallic compounds (IMCs) formed at the interface between Sn-9Zn-0.2Ga-0.002Al-0.25Ag-0.15Ce solder and Cu substrate were investigated by scanning electron microscope (SEM) and energy dispersive spectroscopy (EDS) analysis. The SEM images illustrate that the IMCs can be divided into two portions from the substrate side to the solder side: a planar Cu₅Zn₈ layer and an additional continuous scallop-like AgZn₃ layer. The EDS analysis also shows that Ga segregates in the solder abutting upon the interface. X-ray photoelectron spectroscopy (XPS) and Auger electron spectroscopy (AES) of the surface components of Sn-9Zn-0.2Ga-0.002Al-0.25Ag-0.15Ce solder indicate that Al aggregates at the surface in the form of Al₂O₃ protective film, which prevents the further oxidation of the solder surface. On the other hand, Ce aggregates at the subsurface, which may reduce the surface tension of the solder and improve the wettability in consequence.     

Improvement of mechanical properties of Sn-58Bi alloy with multi-walled carbon nanotubes

Carbon nanotubes (CNTs) reinforced Sn-58Bi composites were successfully fabricated through ball-milling method and low temperature melting process.The influence of multi-walled carbon nanotubes (MWCNTs) on the mechanical strength and ductility of Sn-58Bi lead-free alloy was studied.The mechanical test results show that the bending strength of Sn-58Bi-0.03CNTs (mass fraction,%) composite is increased by 10.5% than that of the Sn-58Bi alloy,which can be attributed to the reduction of Sn-rich segregation and the grain refinement.The toughness of Sn-58Bi-0.03CNTs composite is increased by 48.9% than that of the matrix materials.It is indicated that the influence of CNTs on the strength of Sn-58Bi-xCNTs composite is insignificant.In addition,the fracture mechanism of CNTs reinforced Sn Bi composite was analyzed.The corresponding fracture surface comparison between the Sn-58Bi-0.03CNTs composite and the monolithic Sn-58Bi alloy was made to identify the influence of CNTs on the fracture behavior and the reinforcing effect of CNTs.     

Ga、Al对Sn-Zn钎料耐蚀及高温抗氧化性能的影响

采用侵蚀失重法研究Ga、Al对Sn-9Zn钎料在3.5%NaCl水溶液中耐腐蚀性的影响.结果表明,添加Ga元素后,腐蚀产物的粘附性提高,均匀覆盖在钎料表面上,提高了钎料的耐蚀性能;添加Al以后,Zn和Al被选择性腐蚀,腐蚀随着Al含量的增加而加剧.采用热重分析(TGA)和俄歇电子能谱(AES)研究Ga、Al对Sn-9Zn钎料高温抗氧化性的影响.结果表明,Ga可在钎料表面形成一层集肤层;Al可在钎料表面形成一层致密的氧化膜,两者均可阻挡空气中的氧向钎料内部扩散,从而大大改善钎料的高温抗氧化性.     

Sn-0.7Cu-xNb复合钎料微观组织和力学性能

文中主要研究了纳米Nb颗粒对Sn-0.7Cu基复合钎料显微组织和力学性能的影响。结果表明,添加纳米Nb颗粒细化了Sn-0.7Cu复合钎料微观组织,提高了Sn-0.7Cu复合钎料的抗拉强度。当Nb含量为0.12%时抗拉强度达最大值25.36 MPa,但此时钎料的断后伸长率有所降低。Sn-0.7Cu-x Nb复合钎料的断裂模式均为塑性断裂,随Nb含量的增加,Sn-0.7Cu基复合钎料断口表面的韧窝尺寸逐渐变小,表明微量的纳米Nb可以抑制合金内Cu 6 Sn 5金属间化合物的长大。