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Journal of Electronic Materials
Erschienen in: Journal of Electronic Materials 3/2021

12.01.2021 | TMS2020 Microelectronic Packaging, Interconnect, and Pb-free Solder

Effect of Soldering Temperature on the Reliability of Sn-Ag-Cu Lead-Free Solder Joints

verfasst von: Zhai Xinmeng, Li Yuefeng, Zou Jun, Shi Mingming, Yang Bobo, Li Yang, Guo Chunfeng, Hu Rongrong

Erschienen in: Journal of Electronic Materials | Ausgabe 3/2021

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Abstract

This paper investigates the effect of soldering temperature on solder joint voids and reliability of flip-chip LED chips during reflow soldering. Lead-free solder SAC305 was used as solder paste. The void ratio of the flip-chip LED solder joint at 250°C, 260°C, 270°C, 280°C, and 290°C reflow soldering temperatures was detected by x-ray detector. Shear tests were conducted to evaluate the influence of interfacial reactions on the mechanical reliability of solder joints. The distribution of voids in the shear section was observed by scanning electron microscope (SEM). Next, the photoelectric and thermal properties of FC-LED filament were tested and analyzed. Finally, a high-temperature and high-humidity aging experiment was carried out to test the reliability of the LED filament. The results show that the void ratio of the LED filament soldering joint is the lowest when the soldering temperature is 270°C. The small void ratio of the solder joints results in lower steady-state voltage and junction temperature of the flip-chip LED filament. As the void density in the solder joint decreases, the shear strength of the solder joint increases. At this time, the shear resistance and mechanical reliability are the highest.
Vorheriger Artikel Effects of Surface Finish on Sn-3.0Ag-0.5Cu Solder Joint Microstructure and Strength
Nächster Artikel Effect of Ni, Zn, Au, Sb and In on the Suppression of the Cu3Sn Phase in Sn-10 wt.%Cu Alloys

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Literatur
1.
Y. Kariya, T. Hosoi, S. Terashima, and T.M. Otsuka, J. Electron. Mater. 33, 321 (2004).CrossRef
2.
M.G. Cho, S.K. Kang, and S.H.M. Lee, J. Electron. Mater. 36, 1501 (2007).CrossRef
3.
I.E. Anderson and J.L. Harringa, J. Electron. Mater. 33, 1485 (2004).CrossRef
4.
K.W. Moon, W.J. Boettinger, U.R. Kattner, F.S. Biancaniello, and C.A. Handwerker, J. Electron. Mater. 29, 1122 (2000).CrossRef
5.
Z. Guo, X. Wang, Y. Liu, Y. Liu, and F. Li, J. Constr. Steel Res. 172, 106174 (2020).CrossRef
6.
H. Yongle, L. Yifei, X. Fei, L. Binli, and T. Xin, Microelectron Reliab. 109, 113637 (2020).CrossRef
7.
K.S. Kim, S.H. Huh, and K. Suganuma, J. Alloys Compd. 352, 226 (2003).CrossRef
8.
9.
L. Yang, J. Ge, Y. Zhang, J. Dai, and Y. Jing, J. Mater. Sci. Mater. Electron. 26, 613 (2015).CrossRef
10.
S. Lei and Z. Liang, Adv. Mater. Sci. Eng. 2015, 1 (2015).
11.
L.L. Liou, B. Bayraktaroglu, and C.I. Huang, Solid-State Electron. 39, 165 (1996).CrossRef
12.
L. Ciampolini, M. Ciappa, and P. Malberti, Microelectron. J. 30, 1115 (1999).CrossRef
13.
J. Chengshuo, F. Jiajie, Q. Cheng, Z. Hao, F. Xuejun, G. Weiling, and Z. Guoqi, IEEE Trans. Compon. Packag. Manuf. 99, 1 (2018).
14.
Y. Liu, S.Y.Y. Leung, J. Zhao, C.K.Y. Wong, C.A. Yuan, G. Zhang, F. Sun, and L. Luo, Microelectron. Reliab. 54, 2028 (2014).CrossRef
15.
L. Hailong, A. Rong, W. Chunqing, T. Yanhong, and J. Zhi, Mater. Lett. 144, 97 (2015).CrossRef
16.
D. Bušek, K. Dušek, D. Růžička, M. Plaček, P. Mach, J. Urbánek, and J. Starý, Microelectron. Reliab. 60, 135 (2016).CrossRef
17.
T.C. Liu, C.M. Liu, Y.S. Huang, C. Chen, and K.N. Tu, Scr. Mater. 68, 241 (2013).CrossRef
18.
K. Weinberg, T. Böhme, and W.H. Müller, Comput. Mater. 45, 827 (2009).CrossRef
19.
S.K. Tippabhotla, I. Radchenko, K.N. Rengarajan, G. Illya, V. Handara, M. Kunz, N. Tamura, and A.S. Budiman, Procedia Eng. 139, 123 (2016).CrossRef
20.
21.
T. Tian, K. Chen, A.A. Macdowell, D. Parkinson, Y.S. Lai, and K.N. Tu, Scr. Mater. 65, 646 (2011).CrossRef
22.
P. Wild, D. Lorenz, T. Grözinger, and A. Zimmermann, Microelectron Reliab. 85, 163 (2018).CrossRef
23.
M. Rauer, A. Volkert, T. Schreck, S. Härter, and M. Kaloudis, J Fail. Anal. Prev. 14, 272 (2014).CrossRef
24.
A.S. Budiman, H.A.S. Shin, B.J. Kim, S.H. Hwang, H.Y. Son, M.S. Suh, Q.H. Chung, K.Y. Byun, N. Tamura, and M. Kunz, Microelectron. Reliab. 52, 530 (2012).CrossRef
25.
K.C. Otiaba, R.S. Bhatti, N.N. Ekere, S. Mallik, M.O. Alam, E.H. Amalu, and M. Ekpu, Microelectron. Reliab. 52, 1409 (2012).CrossRef
26.
27.
S. Baricordi, G. Calabrese, F. Gualdi, V. Guidi, M. Pasquini, L. Pozzetti, and D. Vincenzi, Sol. Energy Mater. Sol. Cells 111, 133 (2013).CrossRef
28.
29.
M.A.A.M. Salleh, C.M. Gourlay, J.W. Xian, S.A. Belyakov, H. Yasuda, and S.D. Mcdonald, Sci. Rep. UK 7, 40010 (2017).CrossRef
30.
I.E. Anderson, B.A. Cook, J. Harringa, and R.L. Terpstra, J. Electron. Mater. 31, 1166 (2002).CrossRef
31.
C.E. Ho, R.Y. Tsai, Y.L. Lin, and C.R. Kao, J. Electron. Mater. 31, 584 (2002).CrossRef
32.
D. Goyal, T. Lane, P. Kinzie, C. Panichas, and O. Villalobos, Electron Comp Tech Con., p. 732 (2002).
33.
M. Yunus, K. Srihari, J.M. Pitarresi, and A. Primavera, Microelectron. Reliab. 43, 2077 (2003).CrossRef
34.
Y.W. Chang, Y. Cheng, F. Xu, L. Helfen, T. Tian, M. Di Michiel, C. Chen, K.N. Tu, and T. Baumbach, Acta Mater. 117, 100 (2016).CrossRef
35.
J.M. Song, H.Y. Chuang, and Z.M. Wu, J. Electron. Mater. 36, 1516 (2007).CrossRef
36.
A.K. Gain, T. Fouzder, Y.C. Chan, and W.K.C. Yung, J. Alloys Compd. 509, 3319 (2011).CrossRef
37.
38.
G. Chen, X.H. Wang, J. Yang, W.L. Xu, and Q. Lin, Microelectron. Reliab. 108, 113634 (2020).CrossRef
39.
K. Mehrabi, F. Khodabakhshi, E. Zareh, A. Shahbazkhan, and A. Simchi, J. Alloys Compd. 688, 143 (2016).CrossRef
40.
C.M.T. Law, C.M.L. Wu, D.Q. Yu, L. Wang, and J.K.L. Lai, J. Electron. Mater. 35, 89 (2006).CrossRef
41.
Z. Huang, P. Kumar, I. Dutta, J.H.L. Pang, and R. Sidhu, Eng. Fract. Mech. 131, 9 (2014).CrossRef
42.
C.J. Lee, K.D. Min, H.J. Park, and S.B. Jung, J. Alloys Compd. 820, 153077 (2020).CrossRef
43.
L. Lin, Z.Z. Chen, H.P. Pan, S.L. Qi, P. Liu, Z.X. Qin, T.J. Yu, B. Zhang, Y.Z. Tong, and G.Y. Zhang, Phys. Status Solidi-R 4, 2834 (2007).
44.
Y.T. Chin, P.K. Lam, H.K. Yow, and T.Y. Tou, J. Mater. Res. 25, 1304 (2010).CrossRef
45.
X. Luo, R. Hu, S. Liu, and K. Wang, Prog. Energy Combust. 56, 1 (2016).CrossRef
46.
X. Yu, L. Xiang, N. Pei, S. Zhou, and X. Luo, IEEE Trans. Electron. Device 67, 3655 (2020).CrossRef
47.
C. Morando, O. Fornaro, O. Garbellini, and H. Palacio, Procedia Mater. 1, 80 (2012).CrossRef
48.
G.J. Jeong, H.D. Yoo, K.K. Kim, and S.N. Lee, J. Vac. Sci. Technol. B 33, 051205 (2015).CrossRef
Metadaten
Titel
Effect of Soldering Temperature on the Reliability of Sn-Ag-Cu Lead-Free Solder Joints
verfasst von
Zhai Xinmeng
Li Yuefeng
Zou Jun
Shi Mingming
Yang Bobo
Li Yang
Guo Chunfeng
Hu Rongrong
Publikationsdatum
12.01.2021
Verlag
Springer US
Erschienen in
Journal of Electronic Materials / Ausgabe 3/2021
Print ISSN: 0361-5235
Elektronische ISSN: 1543-186X
DOI
https://doi.org/10.1007/s11664-020-08715-5

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