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Wettability of SnCuNi-xEu solders and mechanical properties of solder joints
JOURNAL OF RARE EARTHS, Vol. 32, No. 12, Dec. 2014, P. 1184
Wettability of SnCuNi-xEu solders and mechanical properties of solder joints ZHANG Liang (张 亮)1,2, TIAN Lei (田 磊)3,*, GUO Yonghuan (郭永环)1, SUN Lei (孙 磊)1, MIN Yong (闵 勇)1 (1. School of Mechanical and Electrical Engineering, Jiangsu Normal University, Xuzhou 221116, China; 2. Department of Materials Science and Engineering, University of California at Los Angeles, Los Angeles, CA 90095, USA; 3. Petroleum Engineering College, Yangtze University, Wuhan 430100, China) Received 19 February 2014; revised 11 September 2014
Abstract: Wettability balance method was used to investigate the wetting performance of SnCuNi-xEu on Cu substrate, and the mechanical properties and the fracture morphology were studied. The results indicated that the addition of Eu could enhance the properties of solder and solder joints, with the increase of Eu content, tendency of first increase and then decrease could be found in the wetting time, wetting force and the mechanical properties of SnCuNi-xEu, and the optimal content was 0.039%. For SnCuNi-0.039Eu solder joints, the optimum mechanical properties could be found, and the amplitude increased was 20%, with the observation of the fracture morphology, it was found that small dimples could be seen, the toughness fracture for SnCuNi and mixture fracture for SnCuNi-0.039Eu could be demonstrated. And thermal fatigue behavior of SnCuNi solder joints could be enhanced obviously with the 0.039%Eu addition. Keywords: lead-free solders; wetting; mechanical property; fracture morphology; rare earths
Due to the low cost and low melting point of SnPb solders, these alloys play an important role in joining electronic devices to metallic substrates. However, Pb is toxic and hazardous to human health and environment. Since July 1, 2006, European Union has promulgated directives, such as the Waste Electrical and Electronic Equipment Directive and Restriction of Hazardous Substances Directive[1]. The evolution of an ultimate leadfree solder solution has become an important issue for electronic interconnection materials because of the health and environmental safety concerning Pb usage[2,3]. Among the new lead-free solders, SnCuNi is cheap and considered to be equally attractive as SnPb for wave, dip and iron soldering process[4,5]. But some drawbacks can be found for the SnCuNi solders, for example, the lower wettability and thermal fatigue resistance of solders[6]. Rare earth (RE) elements have been called the “vitamin” of metals, which means that a small amount of RE elements can greatly enhance the properties of metals[7]. Trace amount of rare earth Yb can improve the wettability, mechanical properties and the thermal fatigue behavior of SnAgCu solders[8]. With 0.03% Ce addition, the fatigue life of SnAgCu solder joints in WLCSP device can be enhanced significantly, is 30.2% higher than that of SnAgCu solder joints[9]. Wang et al.[10] demonstrated that the addition of Ce can improve the wettability and mechanical properties of SnCuNi solders, and depress the growth of intermetallic compound layers. Rare earth Pr can refine the matrix microstructure and depress the IMC growth of solder joints, the wettability and me-
chanical property can be improved obviously[11]. Hu et al.[12] also found the enhancement effect of rare earth Nd on SnZn lead-free solders. Wang et al.[13] tested the wetting property of SnAg solder with the addition of rare earth elements (La, Ce), it was found that the wetting property, ultimate strength and ductility were improved by 0.25%– 0.5% addition of La and Ce. In this paper, the rare earth Eu was selected as additive into SnCuNi lead-free solders. The wettability of SnCuNi solders and the mechanical properties of solder joints were studied, and the fracture morphology and thermal fatigue behavior of solder joints was analyzed systematically.
1 Experimental The SnCuNi-xEu (x=0, 0.024, 0.039, 0.061, 0.105) solders were prepared from the pure Sn, Sn-Cu alloy, Sn-Ni alloy, and Sn-Eu alloys. Atomic emission spectroscopy was used to verify the compositions of solders. All the raw materials for SnCuNi-xEu solders were melted in a ceramic crucible, and melted at 550±1 ºC for 40 min with mechanical stirring. In order to protect the solder for oxidation during the melting, CeO2 nano-particles were used over the surface of liquid solder. Then the molten alloys were chilled and cast ingots in a mold and solidified by nominally air-cooling. In order to stabilize the microstructure of SnCuNi-xEu solders, all solder specimens were heated and treated at 125 ºC for an hour. According to IPC/EIA J-STD-003B 2004 specification, the wetting balance test can be utilized to determine the
Foundation item: Project supported by Natural Science Foundation of the Higher Education Institutions of Jiangsu Province (12KJB460005) * Corresponding author: TIAN Lei (E-mail: [email protected]; Tel.: +86-27-69111707) DOI: 10.1016/S1002-0721(14)60201-5
ZHANG Liang et al., Wettability of SnCuNi-xEu solders and mechanical properties of solder joints
dynamic process of wetting by measuring the wetting time and wetting force that act between the immersing samples and molten solder. A typical wetting curve is shown in Fig. 1, in which the wetting time, t0, is the time at which the solder contact angle to the coupon is 90º, as shown in point D. Short wetting times and wetting force can demonstrate the good wettability of solders. The immersion depth was 2 mm, the immersion time was 10 s, and the immersion speed was 4 mm/s. And the wetting tests were carried out in air and in N2 atmosphere, respectively. The effects of soldering temperature (240, 250 and 260 ºC), atmosphere and the amount of rare earth Eu on the solderability of solders were investigated simultaneously. QFP32 device soldered with SnCuNi-xEu solders and no-clean fluxes were carried out for mechanical properties. The package meets the EIAJ (Electronic Industry Association of Japan) package specification. And the samples were fixed on the testing bench of STR-1000 micro-joints strength tester, the testing showed a angle between the hook and the PCB was 45°, which is shown in Fig. 2. And the fracture morphology of the solder joints was examined by scanning electron microscopy (SEM). Moreover, differential scanning calorimetry (DSC) was used to determine the melting temperature of SnAgCu-xEu solders. Thermal fatigue behavior of SnCuNi-xEu solder joints in QFP32 devices were tested using a TL-100 thermal cycle equipment. According to MIL-STD-883 specification[14], accelerated thermal cycle tests was selected to be imposed on the QFP32 assembly. It was performed at temperatures ranging from 218 to 398 K, dwell time at all peak temperature is 15 min, the rates of descend and ascend temperature were 12 K/min.
2 Results and discussion The onset point of the DSC heating curve is related to the solidus temperature while the peak point is recognized as liquidus temperature of solders. Fig. 3 shows the solidus temperature and liquidus temperature of SnCuNi solders bearing different Eu contents. It is found that the addition of rare earth Eu has a trifling effect on the melting temperature of SnCuNi solders, with the increase of Eu contents, the liquidus temperature and solidus temperature show a small increase, the liquidus temperature range is 227.5–228.1 ºC, for solidus temperature, it is 229.1–229.9 ºC. Therefore, the reflow soldering curve of SnCuNi-xEu in electronic packaging can be designed with the same parameters of SnCuNi solder. Wetting is very important for solder alloys because a reliable solder interconnection requires a good wetting property[15]. The wettability of SnCuNi-xEu solder is assessed based on the wetting balance testing. Fig. 4 shows the wetting time of SnCuNi solders with the addition of rare earth Eu with air and N2 atmospheres under different temperatures. With the addition of Eu, the wetting time can be reduced obviously, and the smallest wetting time can be demonstrated with the optimal Eu content (0.039%). However, with the further increase of Eu addition, the wetting time increases significantly. From the N2 atmosphere, similar phenomena can be observed. Moreover, the wetting time can be reduced in N2 atmosphere. The wetting behavior of SnCuNi-xEu solders is clearly good in comparison with the air samples, because the oxidation of SnCuNi and SnCuNi0.039Eu solders was more severe in air than in N2 atmosphere. The similar superiority of N2 atmosphere also demonstrated by Baated et al.[16]. Fig. 5 shows the effect of Eu on the wetting force of SnCuNi solders. As the oxidation of molten solder and Cu substrate is depressed, the wetting force of SnCuNi solders is increased in N2 atmosphere. And the rare earth Eu can effectively increase the wetting force of alloys in air and N2 atmospheres. From Fig. 5(a) and (b), the optimal content of rare earth Eu is demonstrated to be 0.039%, with 0.039% Eu addition, the wetting force reaches the largest value among these bars.
Fig. 1 Wetting curve of lead-free solders
Fig. 2 Tensile testing of QFP devices
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Fig. 3 Solidus-liquidus temperature
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Fig. 4 Wetting time of SnCuNi-xEu solders during different atmospheres (a) In air; (b) N2 atmosphere
JOURNAL OF RARE EARTHS, Vol. 32, No. 12, Dec. 2014
tively, which can result in enhancing of wettability[17]. However, when a large amount of Eu addition into SnCuNi solders, the oxidation of bulk Sn-Eu phases in SnCuNi alloys will appear to prevent the flow of molten solders. So the excessive Eu addition, the wettability may be reduced significantly. For rare earth Y selected to be added into SnZn solders[18], the enhancement of wettability can also be found with an optimal content. For electronic devices, solder joints act as mechanical supports as well as electrical interconnections, which are crucial elements for the integrity of electron products. Therefore, the mechanical properties of SnCuNi-xEu solder joints should be studied. Fig. 6 indicates the tensile force of QFP32 device with SnCuNi-xEu solder joints. The tensile force of SnCuNi-0.039Eu solder joints is found to be evidently stronger than that of SnCuNi solder joints, which means that adding a small amount of Eu can significantly increase the tensile force of the SnCuNi solder joints. With the increase of Eu content, the tensile force changes from 19.5 to 21N. When the Eu content exceeds 0.039%, the tensile force drops evidently, the optimal content of Eu is 0.039%, which agrees well with the wettability testing. The fracture morphology of SnCuNi and SnCuNi0.039Eu solder joints in QFP32 components was tested and is shown in Fig. 7. Typical micro-voids coalescence mechanism of ductile failure is obvious. For the SnCuNi solder joints (Fig.7(a)), nonuniform dimples and second phase particles can be found in the fracture, and the toughness fracture can be found. With the 0.039% Eu addition (Fig.7(b)), the homogeneous dimples and small second phase particles appear, respectively, which may attribute to the refine effect and high “affinity Sn” of rare earth elements[19]. Dissimilar to fracture morphology of SnCuNi solder joints, mixture fracture exists in SnCuNi0.039Eu solder joints, in Fig. 7(b), the brittle fracture can be found in the ambient area, in the middle of the figure, the toughness fracture can be found, in order to further show the fracture morphology of solder joints, the whole microstructure of the fracture surface is shown in Fig. 7(c). Han et al.[20] suggested that these toughness fracture
Fig. 5 Maximum wetting force of SnCuNi-xEu solders during different atmospheres (a) In air; (b) N2 atmosphere
Due to the active of rare earth element, Eu tends to accumulate at the solder interface in the molten state, and the surface tension of molten solder is decreased effec-
Fig. 6 Tensile force of SnCuNi-xEu solder joints
ZHANG Liang et al., Wettability of SnCuNi-xEu solders and mechanical properties of solder joints
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Fig. 7 Fracture morphology of SnCuNi/SnCuNi-0.039Eu solder joints (a) SnCuNi; (b) SnCuNi-0.039Eu; (c) SnCuNi-0.039Eu
modes belonged to micro-porous aggregation fracture. In addition, the second phase particles were (Cu,Ni)6Sn5. For the testing of thermal fatigue behaviors of SnCuNi solder joints bearing rare earth Eu, the SnCuNi and SnCuNi-0.039Eu solder joints in QFP32 devices were selected to analyze during thermal cycling loading. Fig. 8 shows the tensile force of SnCuNi and SnCuNi-0.039Eu solder joints with the variation of cycles. It is observed that the average tensile force of SnCuNi and SnCuNi0.039Eu solder joints decreases with the increase of thermal cycle number, which can be attributed to the fatigue damage because of coefficient of thermal expansion mismatch during thermal cycles loading[21,22]. Moreover, SnCuNi-0.039Eu solder joints show higher tensile force than SnCuNi solder joints during thermal cycling loading, which can be concluded that the addition of 0.039% Eu can enhance the thermal fatigue behavior of solder joints. TEM testing was used to analyze the effect mechanism of rare earth Eu. Fig. 9 shows the Sn-Eu particles in the matrix microstructure. Table 1 shows the EDX of Sn-Eu phase, combing the Sn-Eu phase diagram[23], the EuSn3 can be determined obviously. Due to the reaction of Eu and Sn, small EuSn3 particles can be formed and exist in the boundaries of β-Sn grains. These particles can act as obstacles to pin dislocation, which will lead to increase in the applied stress required to move dislocation[24]. Therefore, during deformation, the SnCuNi-0.039Eu solder joints represent higher strength than that of SnCuNi solder joints.
Fig. 9 Sn-Eu particles in the matrix Table 1 EDX of Sn-Eu phase Elements
wt.%
at.%
Sn
66.23
71.52
Eu
33.77
28.48
3 Conclusions With the addition of rare earth Eu, the wettibility and tensile force could be improved significantly. And the optimal content of Eu was 0.039%, the 0.039% Eu could refine the microstructure and reduced the size of second phase particles in the fracture morphology of solder joints, moreover, the thermal fatigue behavior were also enhanced obviously.
References:
Fig. 8 Average tensile force versus cycle number
[1] Yen Y W, Hsieh Y P, Jao C C, Chiu C W, Li Y S. Interfacial reaction of Sn, Sn-3.0Ag-0.5Cu, and Sn-9Zn lead-free solders with Fe-42Ni substrates. J. Electron. Mater., 2014, 43(1): 187. [2] Billah M M, Shorowordi K M, Sharif A. Effect of micro size Ni particle addition in Sn-8Zn-3Bi lead-free solder alloy on the microstructure, thermal and mechanical properties. J. Alloys Compd., 2014, 585: 32. [3] Zhang L, Han J G, Guo Y H, He C W. Microstructures and properties of SnZn lead-free solder joints bearing La for electronic packaging. IEEE Trans. Electron Devices, 2012, 59(12): 3269.
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[4] Wang J X. Study on effects of Ce on properties of Sn-AgCu & Sn-Cu-Ni solders and reliability of soldered joints. Nanjing University of Aeronautics and Astronautics, 2009. [5] Nogita K. Stabilisation of Cu6Sn5 by Ni in Sn-0.7Cu-0.05Ni lead-free solder alloys. Intermetallics, 2010, 18(1): 145. [6] Wang J X, Xue S B, Han Z J, Shi Y P, Zhang L. Effects of Ce on physical properties and spreadability of Sn-Cu-Ni solder. Electric Welding Machine, 2008, 38(9): 42. [7] Zhang L, Xue S B, Gao L L, Zeng G, Sheng Z, Chen Y, Yu S L. Effects of rare earths on properties and microstructures of lead-free solder alloys. J. Mater. Sci.-Mater. Electron., 2009, 20: 685. [8] Zhang L, Han J G, Guo Y H, He C W. Properties enhancement of SnAgCu solders containing rare earth Yb. Mater. Des., 2014, 57: 646. [9] Zhang L, Han J G, Guo Y H, He C W. Effect of rare earth Ce on the fatigue life of SnAgCu solder joints in WLCSP device using FEM and experiments. Mater. Sci. Eng., A, 2014, 597: 219. [10] Wang J X, Xue S B, Han Z J, Yu S L, Chen Y, Shi Y P, Wang H. Effects of rare earth Ce on microstructures, solderability of Sn-Ag-Cu and Sn-Cu-Ni solders as well as mechanical properties of soldered joints. J. Alloys Compd., 2009, 467(1-2): 219. [11] Luo J D. Study on the microstructure, properties and joint reliability of SnCuNi-xPr lead-free solder. Nanjing University of Aeronautics and Astronautics, 2013. [12] Hu Y H, Xue S B, Wang H, Ye H, Xiao Z X, Gao L L. Effects of rare earth element Nd on the solderability and microstructure of Sn-Zn lead-free solder. J. Mater. SciMater. Electron., 2011, 22: 481. [13] Wang L, Yu D Q, Zhao J, Huang M L. Improvement of wettability and tensile property in Sn-Ag-RE lead-free solder alloy. Mater. Lett., 2002, 56(6): 1039. [14] Zhang L, Cui J H, Han J G, Guo Y H, He C W. Microstructures and properties of SnZn-xEr lead-free solders. J. Rare Earths, 2012, 30(8): 790.
[15] Yoon J W, Noh B I, Kim B K, Shur C C, Jung S B. Wettability and interfacial reactions of Sn-Ag-Cu/Cu and Sn-Ag-Ni/Cu solder joints. J. Alloys Compd., 2009, 486(1-2): 142. [16] Batted A, Kim K S, Suganuma K, Huang S, Jurcik B, Nozawa S, Ueshima M. Effects of reflow atmosphere and flux on Sn whisker growth of Sn-Ag-Cu solders. J. Mater. Sci.-Mater. Electron., 2010, 21(10): 1066. [17] Zhang L, Xue S B, Gao L L, Sheng Z, Ye H, Xiao Z X, Zeng G, Chen Y, Yu S L. Development of Sn-Zn lead-free solders bearing alloying elements. J. Mater. Sci.-Mater. Electron., 2010, 21(1): 1. [18] Zhang L, Han J G, He C W, Guo Y H. Properties of SnZn lead-free solders bearing rare earth Y. Sci. Technol. Weld. Joining, 2012, 17(5): 424. [19] Ma X, Qian Y Y, Yoshida F. Effect of La on the Cu-Sn intermetallic compound (IMC) growth and solder joint reliability. J. Alloys Compd., 2002, 334(1-2): 224. [20] Han Z J, Xue S B, Wang J X, Zhang X, Zhang L, Yu S L, Wang H. Mechanical properties of QFP micro-joints soldered with lead-free solders using didode laser soldering technology. Trans. Nonferrous Met. Soc. China, 2008, 18(4): 814. [21] Shnawah D A, Sabri M F M, Badruddin I A. A review on thermal cycling and drop impact reliability of SAC solder joint in portable electronic products. Microelectron. Reliab., 2012, 52(1): 90. [22] Zhang L, Han J G, He C W, Guo Y H. Reliability behavior of lead-free soldered joints in electronic components. J. Mater. Sci.-Mater. Electron., 2013, 24(1): 172. [23] Zhang L, Han J G, Guo Y H, Sun L. Properties and microstructures of SnAgCu-xEu alloys for concentrator silicon solar cells solder layer. Sol. Energy Mater. Sol. Cells, 2014, 130: 397. [24] Zhang L, Tu K N. Structure and properties of lead-free solders bearing micro and nano particles. Mater. Sci. Eng., R, 2014, 82: 1.
Wettability of SnCuNi-xEu solders and mechanical properties of solder joints ZHANG Liang (张 亮)1,2, TIAN Lei (田 磊)3,*, GUO Yonghuan (郭永环)1, SUN Lei (孙 磊)1, MIN Yong (闵 勇)1 (1. School of Mechanical and Electrical Engineering, Jiangsu Normal University, Xuzhou 221116, China; 2. Department of Materials Science and Engineering, University of California at Los Angeles, Los Angeles, CA 90095, USA; 3. Petroleum Engineering College, Yangtze University, Wuhan 430100, China) Received 19 February 2014; revised 11 September 2014
Abstract: Wettability balance method was used to investigate the wetting performance of SnCuNi-xEu on Cu substrate, and the mechanical properties and the fracture morphology were studied. The results indicated that the addition of Eu could enhance the properties of solder and solder joints, with the increase of Eu content, tendency of first increase and then decrease could be found in the wetting time, wetting force and the mechanical properties of SnCuNi-xEu, and the optimal content was 0.039%. For SnCuNi-0.039Eu solder joints, the optimum mechanical properties could be found, and the amplitude increased was 20%, with the observation of the fracture morphology, it was found that small dimples could be seen, the toughness fracture for SnCuNi and mixture fracture for SnCuNi-0.039Eu could be demonstrated. And thermal fatigue behavior of SnCuNi solder joints could be enhanced obviously with the 0.039%Eu addition. Keywords: lead-free solders; wetting; mechanical property; fracture morphology; rare earths
Due to the low cost and low melting point of SnPb solders, these alloys play an important role in joining electronic devices to metallic substrates. However, Pb is toxic and hazardous to human health and environment. Since July 1, 2006, European Union has promulgated directives, such as the Waste Electrical and Electronic Equipment Directive and Restriction of Hazardous Substances Directive[1]. The evolution of an ultimate leadfree solder solution has become an important issue for electronic interconnection materials because of the health and environmental safety concerning Pb usage[2,3]. Among the new lead-free solders, SnCuNi is cheap and considered to be equally attractive as SnPb for wave, dip and iron soldering process[4,5]. But some drawbacks can be found for the SnCuNi solders, for example, the lower wettability and thermal fatigue resistance of solders[6]. Rare earth (RE) elements have been called the “vitamin” of metals, which means that a small amount of RE elements can greatly enhance the properties of metals[7]. Trace amount of rare earth Yb can improve the wettability, mechanical properties and the thermal fatigue behavior of SnAgCu solders[8]. With 0.03% Ce addition, the fatigue life of SnAgCu solder joints in WLCSP device can be enhanced significantly, is 30.2% higher than that of SnAgCu solder joints[9]. Wang et al.[10] demonstrated that the addition of Ce can improve the wettability and mechanical properties of SnCuNi solders, and depress the growth of intermetallic compound layers. Rare earth Pr can refine the matrix microstructure and depress the IMC growth of solder joints, the wettability and me-
chanical property can be improved obviously[11]. Hu et al.[12] also found the enhancement effect of rare earth Nd on SnZn lead-free solders. Wang et al.[13] tested the wetting property of SnAg solder with the addition of rare earth elements (La, Ce), it was found that the wetting property, ultimate strength and ductility were improved by 0.25%– 0.5% addition of La and Ce. In this paper, the rare earth Eu was selected as additive into SnCuNi lead-free solders. The wettability of SnCuNi solders and the mechanical properties of solder joints were studied, and the fracture morphology and thermal fatigue behavior of solder joints was analyzed systematically.
1 Experimental The SnCuNi-xEu (x=0, 0.024, 0.039, 0.061, 0.105) solders were prepared from the pure Sn, Sn-Cu alloy, Sn-Ni alloy, and Sn-Eu alloys. Atomic emission spectroscopy was used to verify the compositions of solders. All the raw materials for SnCuNi-xEu solders were melted in a ceramic crucible, and melted at 550±1 ºC for 40 min with mechanical stirring. In order to protect the solder for oxidation during the melting, CeO2 nano-particles were used over the surface of liquid solder. Then the molten alloys were chilled and cast ingots in a mold and solidified by nominally air-cooling. In order to stabilize the microstructure of SnCuNi-xEu solders, all solder specimens were heated and treated at 125 ºC for an hour. According to IPC/EIA J-STD-003B 2004 specification, the wetting balance test can be utilized to determine the
Foundation item: Project supported by Natural Science Foundation of the Higher Education Institutions of Jiangsu Province (12KJB460005) * Corresponding author: TIAN Lei (E-mail: [email protected]; Tel.: +86-27-69111707) DOI: 10.1016/S1002-0721(14)60201-5
ZHANG Liang et al., Wettability of SnCuNi-xEu solders and mechanical properties of solder joints
dynamic process of wetting by measuring the wetting time and wetting force that act between the immersing samples and molten solder. A typical wetting curve is shown in Fig. 1, in which the wetting time, t0, is the time at which the solder contact angle to the coupon is 90º, as shown in point D. Short wetting times and wetting force can demonstrate the good wettability of solders. The immersion depth was 2 mm, the immersion time was 10 s, and the immersion speed was 4 mm/s. And the wetting tests were carried out in air and in N2 atmosphere, respectively. The effects of soldering temperature (240, 250 and 260 ºC), atmosphere and the amount of rare earth Eu on the solderability of solders were investigated simultaneously. QFP32 device soldered with SnCuNi-xEu solders and no-clean fluxes were carried out for mechanical properties. The package meets the EIAJ (Electronic Industry Association of Japan) package specification. And the samples were fixed on the testing bench of STR-1000 micro-joints strength tester, the testing showed a angle between the hook and the PCB was 45°, which is shown in Fig. 2. And the fracture morphology of the solder joints was examined by scanning electron microscopy (SEM). Moreover, differential scanning calorimetry (DSC) was used to determine the melting temperature of SnAgCu-xEu solders. Thermal fatigue behavior of SnCuNi-xEu solder joints in QFP32 devices were tested using a TL-100 thermal cycle equipment. According to MIL-STD-883 specification[14], accelerated thermal cycle tests was selected to be imposed on the QFP32 assembly. It was performed at temperatures ranging from 218 to 398 K, dwell time at all peak temperature is 15 min, the rates of descend and ascend temperature were 12 K/min.
2 Results and discussion The onset point of the DSC heating curve is related to the solidus temperature while the peak point is recognized as liquidus temperature of solders. Fig. 3 shows the solidus temperature and liquidus temperature of SnCuNi solders bearing different Eu contents. It is found that the addition of rare earth Eu has a trifling effect on the melting temperature of SnCuNi solders, with the increase of Eu contents, the liquidus temperature and solidus temperature show a small increase, the liquidus temperature range is 227.5–228.1 ºC, for solidus temperature, it is 229.1–229.9 ºC. Therefore, the reflow soldering curve of SnCuNi-xEu in electronic packaging can be designed with the same parameters of SnCuNi solder. Wetting is very important for solder alloys because a reliable solder interconnection requires a good wetting property[15]. The wettability of SnCuNi-xEu solder is assessed based on the wetting balance testing. Fig. 4 shows the wetting time of SnCuNi solders with the addition of rare earth Eu with air and N2 atmospheres under different temperatures. With the addition of Eu, the wetting time can be reduced obviously, and the smallest wetting time can be demonstrated with the optimal Eu content (0.039%). However, with the further increase of Eu addition, the wetting time increases significantly. From the N2 atmosphere, similar phenomena can be observed. Moreover, the wetting time can be reduced in N2 atmosphere. The wetting behavior of SnCuNi-xEu solders is clearly good in comparison with the air samples, because the oxidation of SnCuNi and SnCuNi0.039Eu solders was more severe in air than in N2 atmosphere. The similar superiority of N2 atmosphere also demonstrated by Baated et al.[16]. Fig. 5 shows the effect of Eu on the wetting force of SnCuNi solders. As the oxidation of molten solder and Cu substrate is depressed, the wetting force of SnCuNi solders is increased in N2 atmosphere. And the rare earth Eu can effectively increase the wetting force of alloys in air and N2 atmospheres. From Fig. 5(a) and (b), the optimal content of rare earth Eu is demonstrated to be 0.039%, with 0.039% Eu addition, the wetting force reaches the largest value among these bars.
Fig. 1 Wetting curve of lead-free solders
Fig. 2 Tensile testing of QFP devices
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Fig. 3 Solidus-liquidus temperature
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Fig. 4 Wetting time of SnCuNi-xEu solders during different atmospheres (a) In air; (b) N2 atmosphere
JOURNAL OF RARE EARTHS, Vol. 32, No. 12, Dec. 2014
tively, which can result in enhancing of wettability[17]. However, when a large amount of Eu addition into SnCuNi solders, the oxidation of bulk Sn-Eu phases in SnCuNi alloys will appear to prevent the flow of molten solders. So the excessive Eu addition, the wettability may be reduced significantly. For rare earth Y selected to be added into SnZn solders[18], the enhancement of wettability can also be found with an optimal content. For electronic devices, solder joints act as mechanical supports as well as electrical interconnections, which are crucial elements for the integrity of electron products. Therefore, the mechanical properties of SnCuNi-xEu solder joints should be studied. Fig. 6 indicates the tensile force of QFP32 device with SnCuNi-xEu solder joints. The tensile force of SnCuNi-0.039Eu solder joints is found to be evidently stronger than that of SnCuNi solder joints, which means that adding a small amount of Eu can significantly increase the tensile force of the SnCuNi solder joints. With the increase of Eu content, the tensile force changes from 19.5 to 21N. When the Eu content exceeds 0.039%, the tensile force drops evidently, the optimal content of Eu is 0.039%, which agrees well with the wettability testing. The fracture morphology of SnCuNi and SnCuNi0.039Eu solder joints in QFP32 components was tested and is shown in Fig. 7. Typical micro-voids coalescence mechanism of ductile failure is obvious. For the SnCuNi solder joints (Fig.7(a)), nonuniform dimples and second phase particles can be found in the fracture, and the toughness fracture can be found. With the 0.039% Eu addition (Fig.7(b)), the homogeneous dimples and small second phase particles appear, respectively, which may attribute to the refine effect and high “affinity Sn” of rare earth elements[19]. Dissimilar to fracture morphology of SnCuNi solder joints, mixture fracture exists in SnCuNi0.039Eu solder joints, in Fig. 7(b), the brittle fracture can be found in the ambient area, in the middle of the figure, the toughness fracture can be found, in order to further show the fracture morphology of solder joints, the whole microstructure of the fracture surface is shown in Fig. 7(c). Han et al.[20] suggested that these toughness fracture
Fig. 5 Maximum wetting force of SnCuNi-xEu solders during different atmospheres (a) In air; (b) N2 atmosphere
Due to the active of rare earth element, Eu tends to accumulate at the solder interface in the molten state, and the surface tension of molten solder is decreased effec-
Fig. 6 Tensile force of SnCuNi-xEu solder joints
ZHANG Liang et al., Wettability of SnCuNi-xEu solders and mechanical properties of solder joints
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Fig. 7 Fracture morphology of SnCuNi/SnCuNi-0.039Eu solder joints (a) SnCuNi; (b) SnCuNi-0.039Eu; (c) SnCuNi-0.039Eu
modes belonged to micro-porous aggregation fracture. In addition, the second phase particles were (Cu,Ni)6Sn5. For the testing of thermal fatigue behaviors of SnCuNi solder joints bearing rare earth Eu, the SnCuNi and SnCuNi-0.039Eu solder joints in QFP32 devices were selected to analyze during thermal cycling loading. Fig. 8 shows the tensile force of SnCuNi and SnCuNi-0.039Eu solder joints with the variation of cycles. It is observed that the average tensile force of SnCuNi and SnCuNi0.039Eu solder joints decreases with the increase of thermal cycle number, which can be attributed to the fatigue damage because of coefficient of thermal expansion mismatch during thermal cycles loading[21,22]. Moreover, SnCuNi-0.039Eu solder joints show higher tensile force than SnCuNi solder joints during thermal cycling loading, which can be concluded that the addition of 0.039% Eu can enhance the thermal fatigue behavior of solder joints. TEM testing was used to analyze the effect mechanism of rare earth Eu. Fig. 9 shows the Sn-Eu particles in the matrix microstructure. Table 1 shows the EDX of Sn-Eu phase, combing the Sn-Eu phase diagram[23], the EuSn3 can be determined obviously. Due to the reaction of Eu and Sn, small EuSn3 particles can be formed and exist in the boundaries of β-Sn grains. These particles can act as obstacles to pin dislocation, which will lead to increase in the applied stress required to move dislocation[24]. Therefore, during deformation, the SnCuNi-0.039Eu solder joints represent higher strength than that of SnCuNi solder joints.
Fig. 9 Sn-Eu particles in the matrix Table 1 EDX of Sn-Eu phase Elements
wt.%
at.%
Sn
66.23
71.52
Eu
33.77
28.48
3 Conclusions With the addition of rare earth Eu, the wettibility and tensile force could be improved significantly. And the optimal content of Eu was 0.039%, the 0.039% Eu could refine the microstructure and reduced the size of second phase particles in the fracture morphology of solder joints, moreover, the thermal fatigue behavior were also enhanced obviously.
References:
Fig. 8 Average tensile force versus cycle number
[1] Yen Y W, Hsieh Y P, Jao C C, Chiu C W, Li Y S. Interfacial reaction of Sn, Sn-3.0Ag-0.5Cu, and Sn-9Zn lead-free solders with Fe-42Ni substrates. J. Electron. Mater., 2014, 43(1): 187. [2] Billah M M, Shorowordi K M, Sharif A. Effect of micro size Ni particle addition in Sn-8Zn-3Bi lead-free solder alloy on the microstructure, thermal and mechanical properties. J. Alloys Compd., 2014, 585: 32. [3] Zhang L, Han J G, Guo Y H, He C W. Microstructures and properties of SnZn lead-free solder joints bearing La for electronic packaging. IEEE Trans. Electron Devices, 2012, 59(12): 3269.
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[4] Wang J X. Study on effects of Ce on properties of Sn-AgCu & Sn-Cu-Ni solders and reliability of soldered joints. Nanjing University of Aeronautics and Astronautics, 2009. [5] Nogita K. Stabilisation of Cu6Sn5 by Ni in Sn-0.7Cu-0.05Ni lead-free solder alloys. Intermetallics, 2010, 18(1): 145. [6] Wang J X, Xue S B, Han Z J, Shi Y P, Zhang L. Effects of Ce on physical properties and spreadability of Sn-Cu-Ni solder. Electric Welding Machine, 2008, 38(9): 42. [7] Zhang L, Xue S B, Gao L L, Zeng G, Sheng Z, Chen Y, Yu S L. Effects of rare earths on properties and microstructures of lead-free solder alloys. J. Mater. Sci.-Mater. Electron., 2009, 20: 685. [8] Zhang L, Han J G, Guo Y H, He C W. Properties enhancement of SnAgCu solders containing rare earth Yb. Mater. Des., 2014, 57: 646. [9] Zhang L, Han J G, Guo Y H, He C W. Effect of rare earth Ce on the fatigue life of SnAgCu solder joints in WLCSP device using FEM and experiments. Mater. Sci. Eng., A, 2014, 597: 219. [10] Wang J X, Xue S B, Han Z J, Yu S L, Chen Y, Shi Y P, Wang H. Effects of rare earth Ce on microstructures, solderability of Sn-Ag-Cu and Sn-Cu-Ni solders as well as mechanical properties of soldered joints. J. Alloys Compd., 2009, 467(1-2): 219. [11] Luo J D. Study on the microstructure, properties and joint reliability of SnCuNi-xPr lead-free solder. Nanjing University of Aeronautics and Astronautics, 2013. [12] Hu Y H, Xue S B, Wang H, Ye H, Xiao Z X, Gao L L. Effects of rare earth element Nd on the solderability and microstructure of Sn-Zn lead-free solder. J. Mater. SciMater. Electron., 2011, 22: 481. [13] Wang L, Yu D Q, Zhao J, Huang M L. Improvement of wettability and tensile property in Sn-Ag-RE lead-free solder alloy. Mater. Lett., 2002, 56(6): 1039. [14] Zhang L, Cui J H, Han J G, Guo Y H, He C W. Microstructures and properties of SnZn-xEr lead-free solders. J. Rare Earths, 2012, 30(8): 790.
[15] Yoon J W, Noh B I, Kim B K, Shur C C, Jung S B. Wettability and interfacial reactions of Sn-Ag-Cu/Cu and Sn-Ag-Ni/Cu solder joints. J. Alloys Compd., 2009, 486(1-2): 142. [16] Batted A, Kim K S, Suganuma K, Huang S, Jurcik B, Nozawa S, Ueshima M. Effects of reflow atmosphere and flux on Sn whisker growth of Sn-Ag-Cu solders. J. Mater. Sci.-Mater. Electron., 2010, 21(10): 1066. [17] Zhang L, Xue S B, Gao L L, Sheng Z, Ye H, Xiao Z X, Zeng G, Chen Y, Yu S L. Development of Sn-Zn lead-free solders bearing alloying elements. J. Mater. Sci.-Mater. Electron., 2010, 21(1): 1. [18] Zhang L, Han J G, He C W, Guo Y H. Properties of SnZn lead-free solders bearing rare earth Y. Sci. Technol. Weld. Joining, 2012, 17(5): 424. [19] Ma X, Qian Y Y, Yoshida F. Effect of La on the Cu-Sn intermetallic compound (IMC) growth and solder joint reliability. J. Alloys Compd., 2002, 334(1-2): 224. [20] Han Z J, Xue S B, Wang J X, Zhang X, Zhang L, Yu S L, Wang H. Mechanical properties of QFP micro-joints soldered with lead-free solders using didode laser soldering technology. Trans. Nonferrous Met. Soc. China, 2008, 18(4): 814. [21] Shnawah D A, Sabri M F M, Badruddin I A. A review on thermal cycling and drop impact reliability of SAC solder joint in portable electronic products. Microelectron. Reliab., 2012, 52(1): 90. [22] Zhang L, Han J G, He C W, Guo Y H. Reliability behavior of lead-free soldered joints in electronic components. J. Mater. Sci.-Mater. Electron., 2013, 24(1): 172. [23] Zhang L, Han J G, Guo Y H, Sun L. Properties and microstructures of SnAgCu-xEu alloys for concentrator silicon solar cells solder layer. Sol. Energy Mater. Sol. Cells, 2014, 130: 397. [24] Zhang L, Tu K N. Structure and properties of lead-free solders bearing micro and nano particles. Mater. Sci. Eng., R, 2014, 82: 1.