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References (76)
-
R. Mayappan, Z. Ahmad (2010)
Effect of Bi addition on the activation energy for the growth of Cu5Zn8 intermetallic in the Sn–Zn lead-free solderIntermetallics, 18
-
Yang Yang, Yongzhi Li, Hao Lu, Chun Yu, Junmei Chen (2013)
Interdiffusion at the interface between Sn-based solders and Cu substrateMicroelectron. Reliab., 53
-
J. Keller, D. Baither, U. Wilke, G. Schmitz (2011)
Mechanical properties of Pb-free SnAg solder jointsActa Materialia, 59
-
Tama Fouzder, I. Shafiq, Y. Chan, A. Sharif, W. Yung (2011)
Influence of SrTiO3 nano-particles on the microstructure and shear strength of Sn–Ag–Cu solder on Au/Ni metallized Cu padsJournal of Alloys and Compounds, 509
-
Dongxia Xu, Y. Lei, Z. Xia, F. Guo, Yaowu Shi (2008)
Experimental Wettability Study of Lead-Free Solder on Cu Substrates Using Varying Flux and TemperatureJournal of Electronic Materials, 37
-
S. Nai, Jun Wei, M. Gupta (2006)
Influence of ceramic reinforcements on the wettability and mechanical properties of novel lead-free solder compositesThin Solid Films, 504
-
A. Gain, Y. Chan, W. Yung (2011)
Effect of additions of ZrO2 nano-particles on the microstructure and shear strength of Sn-Ag-Cu solder on Au/Ni metallized Cu padsMicroelectron. Reliab., 51
-
Tao-Chih Chang, Jian-wen Wang, Moo-Chin Wang, M. Hon (2006)
Solderability of Sn–9Zn–0.5Ag–1In lead-free solder on Cu substrate: Part 1. Thermal properties, microstructure, corrosion and oxidation resistanceJournal of Alloys and Compounds, 422
-
S. Wiese, K. Wolter (2004)
Microstructure and creep behaviour of eutectic SnAg and SnAgCu soldersMicroelectron. Reliab., 44
-
Xianghua Liu, Zhengyi Jiang, J. Han (2011)
Materials processing technology -
L. Garcia, W. Osório, L. Peixoto, Amauri Garcia (2010)
Mechanical properties of Sn–Zn lead-free solder alloys based on the microstructure arrayMaterials Characterization, 61
-
A. El-Daly, A. Hammad (2010)
Elastic properties and thermal behavior of Sn–Zn based lead-free solder alloysJournal of Alloys and Compounds, 505
-
M. Abtew, G. Selvaduray (2000)
Lead-free Solders in MicroelectronicsMaterials Science & Engineering R-reports, 27
-
C. Morando, O. Fornaro, O. Garbellini, H. Palacio (2012)
Microstructure Evolution During the Aging at Elevated Temperature of Sn-Ag-Cu Solder AlloysProcedia Materials Science, 1
-
J. Gong, Changqing Liu, P. Conway, V. Silberschmidt (2009)
Initial formation of CuSn intermetallic compounds between molten SnAgCu solder and Cu substrateScripta Materialia, 60
-
Jun Shen, Y. Chan (2009)
Research advances in nano-composite soldersMicroelectron. Reliab., 49
-
C. Lin, U. Mohanty, J. Chou (2010)
High temperature synthesis of Sn–3.5Ag–0.5Zn alloy nanoparticles by chemical reduction methodJournal of Alloys and Compounds, 501
-
K. Prabhu, Parashuram Deshapande, Satyanarayan (2012)
Effect of cooling rate during solidification of Sn–9Zn lead-free solder alloy on its microstructure, tensile strength and ductile–brittle transition temperatureMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 533
-
A. Haseeb, Tay Leng (2011)
Effects of Co nanoparticle addition to Sn–3.8Ag–0.7Cu solder on interfacial structure after reflow and ageingIntermetallics, 19
-
Wei Zhang, Y. Zhong, Chunqing Wang (2012)
Effect of Diamond Additions on Wettability and Distribution of SnAgCu Composite SolderJournal of Materials Science & Technology, 28
-
R. Shalaby (2010)
Effect of rapid solidification on mechanical properties of a lead free Sn–3.5Ag solderJournal of Alloys and Compounds, 505
-
J. Sundelin, S. Nurmi, T. Lepistö (2008)
Recrystallization behaviour of SnAgCu solder jointsMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 474
-
Hongtao Chen, Chunqing Wang, Mingyu Li, D. Tian (2009)
Influence of Thermal Cycling on the Microstructure and Shear Strength of Sn3.5Ag0.75Cu and Sn63Pb37 Solder Joints on Au/Ni MetallizationJournal of Materials Science & Technology, 23
-
Q. Zhang, Q. Zhu, Z. Zhang (2010)
Fatigue fracture mechanisms of Cu/lead-free solders interfaces2010 11th International Conference on Electronic Packaging Technology & High Density Packaging
-
Yulai Gao, Changdong Zou, Bin Yang, Q. Zhai, Johan Liu, E. Zhuravlev, C. Schick (2009)
Nanoparticles of SnAgCu lead-free solder alloy with an equivalent melting temperature of SnPb solder alloyJournal of Alloys and Compounds, 484
-
Jeong-Won Yoon, Bo-In Noh, Bong-Kyun Kim, C. Shur, Seung-Boo Jung (2009)
Wettability and interfacial reactions of Sn–Ag–Cu/Cu and Sn–Ag–Ni/Cu solder jointsJournal of Alloys and Compounds, 486
-
Liang Zhang, S. Xue, G. Zeng, Li-li Gao, Huan Ye (2012)
Interface reaction between SnAgCu/SnAgCuCe solders and Cu substrate subjected to thermal cycling and isothermal agingJournal of Alloys and Compounds, 510
-
J. Gong, Changqing Liu, P. Conway, V. Silberschmidt (2008)
Evolution of CuSn intermetallics between molten SnAgCu solder and Cu substrateActa Materialia, 56
-
M. Islam, Y. Chan, M. Rizvi, W. Jillek (2005)
Investigations of interfacial reactions of Sn–Zn based and Sn–Ag–Cu lead-free solder alloys as replacement for Sn–Pb solderJournal of Alloys and Compounds, 400
-
C. Chuang, L. Tsao, H. Lin, L. Feng (2012)
Effects of small amount of active Ti element additions on microstructure and property of Sn3.5Ag0.5Cu solderMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 558
-
S. Chang, C. Jain, T. Chuang, L. Feng, L. Tsao (2011)
Effect of addition of TiO2 nanoparticles on the microstructure, microhardness and interfacial reactions of Sn3.5AgXCu solderMaterials & Design, 32
-
A. Haseeb, M. Arafat, M. Johan (2012)
Stability of molybdenum nanoparticles in Sn-3.8Ag-0.7Cu solder during multiple reflow and their influence on interfacial intermetallic compoundsMaterials Characterization, 64
-
Ervina Noor, Amares Singh, Tze Yap (2013)
A review: influence of nano particles reinforced on solder alloySoldering & Surface Mount Technology, 25
-
T. Laurila, V. Vuorinen, J. Kivilahti (2005)
Interfacial reactions between lead-free solders and common base materialsMaterials Science & Engineering R-reports, 49
-
Changdong Zou, Yulai Gao, Bin Yang, Q. Zhai (2010)
Melting and solidification properties of the nanoparticles of Sn3.0Ag0.5Cu lead-free solder alloyMaterials Characterization, 61
-
W. Peng, E. Monlevade, Marco Marques (2007)
Effect of thermal aging on the interfacial structure of SnAgCu solder joints on CuMicroelectron. Reliab., 47
-
S. Jeon, S. Hyun, Hak-Joo Lee, Jong‐Woong Kim, S. Ha, Jeong-Won Yoon, Seung-Boo Jung, Hoo-Jeong Lee (2008)
Mechanical reliability evaluation of Sn-37Pb solder joint using high speed lap-shear testMicroelectronic Engineering, 85
-
D. Yu, Jing Zhao, L. Wang (2004)
Improvement on the microstructure stability, mechanical and wetting properties of Sn-Ag-Cu lead-free solder with the addition of rare earth elementsJournal of Alloys and Compounds, 376
-
L. Gao, S. Xue, L. Zhang, Z. Sheng, F. Ji, W. Dai, S.L. Yu, G. Zeng
Effect of alloying elements on properties and microstructures SnAgCu solders -
S. Kikuchi, M. Nishimura, K. Suetsugu, T. Ikari, K. Matsushige (2001)
Strength of bonding interface in lead-free Sn alloy soldersMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 319
-
B. Rao, J. Weng, L. Shen, T. Lee, K. Zeng (2010)
Morphology and mechanical properties of intermetallic compounds in SnAgCu solder jointsMicroelectronic Engineering, 87
-
I. Anderson, J. Foley, B. Cook, J. Harringa, R. Terpstra, Ö. Ünal (2001)
Alloying effects in near-eutectic Sn-Ag-Cu solder alloys for improved microstructural stabilityJournal of Electronic Materials, 30
-
H. Kotadia, O. Mokhtari, M. Clode, Mark Green, S. Mannan (2012)
Intermetallic compound growth suppression at high temperature in SAC solders with Zn addition on Cu and Ni–P substratesJournal of Alloys and Compounds, 511
-
Jeong-Won Yoon, Seung-Boo Jung (2006)
High temperature reliability and interfacial reaction of eutectic Sn-0.7Cu/Ni solder joints during isothermal agingMicroelectron. Reliab., 46
-
E. Ervina, S. Tan (2013)
Wettability of Molten Sn-Zn-Bi Solder on Cu Substrate Ervina EfzanApplied Mechanics and Materials, 315
-
A. Marini (2012)
A REVIEW OF SOLDER EVOLUTION IN ELECTRONIC APPLICATION -
J. Gong, Changqing Liu, P. Conway, V. Silberschmidt (2009)
Formation of Sn dendrites and SnAg eutectics in a SnAgCu solderScripta Materialia, 61
-
Liang Zhang, S. Xue, Li-li Gao, Z. Sheng, Huan Ye, Zheng-xiang Xiao, G. Zeng, Yan Chen, Sheng-lin Yu (2010)
Development of Sn–Zn lead-free solders bearing alloying elementsJournal of Materials Science: Materials in Electronics, 21
-
Hongtao Ma, J. Suhling (2009)
A review of mechanical properties of lead-free solders for electronic packagingJournal of Materials Science, 44
-
Satyanarayan, K. Prabhu (2011)
Reactive wetting, evolution of interfacial and bulk IMCs and their effect on mechanical properties of eutectic Sn-Cu solder alloy.Advances in colloid and interface science, 166 1-2
-
K. Kanlayasiri, M. Mongkolwongrojn, T. Ariga (2009)
Influence of indium addition on characteristics of Sn-0.3Ag-0.7Cu solder alloyJournal of Alloys and Compounds, 485
-
E. Ervina, A. Singh (2012)
Characterization of mechanical testing on lead free solder on electronic application2012 35th IEEE/CPMT International Electronics Manufacturing Technology Conference (IEMT)
-
Szu-Chi Yang, C. Chang, M. Tsai, C. Kao (2010)
Effect of Cu concentration, solder volume, and temperature on the reaction between SnAgCu solders and NiJournal of Alloys and Compounds, 499
-
L. Duan, Daiquan Yu, S. Han, Hai-Bin Ma, Larry Wang (2004)
Microstructural evolution of Sn–9Zn–3Bi solder/Cu joint during long-term aging at 170 °CJournal of Alloys and Compounds, 381
-
Li-li Gao, S. Xue, Liang Zhang, Z. Sheng, F. Ji, Wei Dai, Sheng-lin Yu, G. Zeng (2010)
Review Article: Effect of alloying elements on properties and microstructures of SnAgCu soldersMicroelectronic Engineering, 87
-
L. Wang, D. Yu, J. Zhao, M. Huang (2002)
Improvement of wettability and tensile property in Sn–Ag–RE lead-free solder alloyMaterials Letters, 56
-
D. Lin, S. Liu, T. Guo, Guo-xiang Wang, T. Srivatsan, M. Petraroli (2003)
An investigation of nanoparticles addition on solidification kinetics and microstructure development of tin–lead solderMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 360
-
L. Tsao, S. Chang, C. Lee, W. Sun, C. Huang (2010)
Effects of nano-Al2O3 additions on microstructure development and hardness of Sn3.5Ag0.5Cu solderMaterials & Design, 31
-
N.‐C. Lee
Reflow Soldering and Trouble Shooting -
Jian Zhou, Yangshan Sun, F. Xue (2005)
Properties of low melting point Sn–Zn–Bi soldersJournal of Alloys and Compounds, 397
-
L. Tsao, C. Huang, C. Chung, Rong-Sheng Chen (2012)
Influence of TiO2 nanoparticles addition on the microstructural and mechanical properties of Sn0.7Cu nano-composite solderMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 545
-
Fu-quan Li, Chunqing Wang (2006)
Influence of interfacial reaction between molten SnAgCu solder droplet and Au/Ni/Cu pad on IMC evolutionTransactions of Nonferrous Metals Society of China, 16
-
D. Whalley (2004)
A simplified reflow soldering process modelJournal of Materials Processing Technology, 150
-
H. Tsukamoto, T. Nishimura, S. Suenaga, K. Nogita (2010)
Shear and tensile impact strength of lead-free solder ball grid arrays placed on Ni (P)/Au surface-finished substratesMaterials Science and Engineering B-advanced Functional Solid-state Materials, 171
-
R. Mahmudi, A. Geranmayeh, H. Noori, N. Jahangiri, H. Khanbareh (2008)
Effect of cooling rate on the room-temperature impression: creep of lead-free Sn–9Zn and Sn–8Zn–3Bi soldersMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 487
-
G. Humpston, D.M. Jacobson
Principles of Soldering -
F. Che, W. Zhu, E. Poh, Xiaowei Zhang, X. Zhang (2010)
The study of mechanical properties of Sn–Ag–Cu lead-free solders with different Ag contents and Ni doping under different strain rates and temperaturesJournal of Alloys and Compounds, 507
-
K. Suganuma (2003)
Lead-Free Soldering in Electronics: Science, Technology, and Environmental Impact -
S. Tay, A. Haseeb, M. Johan, P. Munroe, M. Quadir (2013)
Influence of Ni nanoparticle on the morphology and growth of interfacial intermetallic compounds between Sn–3.8Ag–0.7Cu lead-free solder and copper substrateIntermetallics, 33
-
10.1016/j.msea.2009.10.040
-
E.M.N. Ervina, S.Y. Tan
Wettability of molten Sn‐Zn‐Bi solder on Cu substrate -
Ervina Noor, N. Sharif, C. Yew, T. Ariga, A. Ismail, Zuhailawati Hussain (2010)
Wettability and strength of In–Bi–Sn lead-free solder alloy on copper substrateJournal of Alloys and Compounds, 507
-
Ping Liu, P. Yao, Jim Liu (2009)
Effects of multiple reflows on interfacial reaction and shear strength of SnAgCu and SnPb solder joints with different PCB surface finishesJournal of Alloys and Compounds, 470
-
Hsiu-Jen Lin, T. Chuang (2010)
Effects of Ce and Zn additions on the microstructure and mechanical properties of Sn–3Ag–0.5Cu solder jointsJournal of Alloys and Compounds, 500
-
C. Law, C. Wu, D. Yu, L. Wang, J. Lai (2006)
Microstructure, solderability, and growth of intermetallic compounds of Sn-Ag-Cu-RE lead-free solder alloysJournal of Electronic Materials, 35
-
J. Shang, M. Flury, J. Harsh, R. Zollars (2008)
Comparison of different methods to measure contact angles of soil colloids.Journal of colloid and interface science, 328 2
- Publisher
- Emerald Publishing
- Copyright
- Copyright © Emerald Group Publishing Limited
- ISSN
- 0954-0911
- DOI
- 10.1108/SSMT-02-2014-0001
- Publisher site
- See Article on Publisher Site
Abstract
Purpose– The aim of the present study was to gather and review all the important properties of the Sn–Ag–Cu (SAC) solder alloy. The SAC solder alloy has been proposed as the alternative solder to overcome the environmental concern of lead (Pb) solder. Many researchers have studied the SAC solder alloy and found that the properties such as melting temperature, wettability, microstructure and interfacial, together with mechanical properties, are better for the SAC solder than the tin – lead (SnPb) solders. Meanwhile, addition of various elements and nanoparticles seems to produce enhancement on the prior bulk solder alloy as well. These benefits suggest that the SAC solder alloy could be the next alternative solder for the electronic packaging industry. Although many studies have been conducted for this particular solder alloy, a compilation of all these properties regarding the SAC solder alloy is still not available for a review to say. Design/methodology/approach– Soldering is identified as the metallurgical joining method in electronic packaging industry which uses filler metal, or well known as the solder, with a melting point < 425°C (Yoon et al., 2009; Ervina and Marini, 2012). The SAC solder has been developed by many methods and even alloying it with some elements to enhance its properties (Law et al., 2006; Tsao et al., 2010; Wang et al., 2002; Gain et al., 2011). The development toward miniaturization, meanwhile, requires much smaller solder joints and fine-pitch interconnections for microelectronic packaging in electronic devices which demand better solder joint reliability of SAC solder Although many studies have been done based on the SAC solder, a review based on the important characteristics and the fundamental factor involving the SAC solder is still not sufficient. Henceforth, this paper resolves in stating all its important properties based on the SAC solder including its alloying of elements and nanoparticles addition for further understanding. Findings– Various Pb-free solders have been studied and investigated to overcome the health and environmental concern of the SnPb solder. In terms of the melting temperature, the SAC solder seems to possess a high melting temperature of 227°C than the Pb solder SnPb. Here, the melting temperature of this solder falls within the range of the average reflow temperature in the electronic packaging industry and would not really affect the process of connection. A good amendment here is, this melting temperature can actually be reduced by adding some element such as titanium and zinc. The addition of these elements tends to decrease the melting temperature of the SAC solder alloy to about 3°C. Adding nanoparticles, meanwhile, tend to increase the melting temperature slightly; nonetheless, this increment was not seemed to damage other devices due to the very slight increment and no drastic changes in the solidification temperature. Henceforth, this paper reviews all the properties of the Pb-free SAC solder system by how it is developed from overcoming environmental problem to achieving and sustaining as the viable candidate in the electronic packaging industry. The Pb-free SAC solder can be the alternative to all drawbacks that the traditional SnPb solder possesses and also an upcoming new invention for the future needs. Although many studies have been done in this particular solder, not much information is gathered in a review to give better understanding for SAC solder alloy. In that, this paper reviews and gathers the importance of this SAC solder in the electronic packaging industry and provides information for better knowledge. Originality/value– This paper resolves in stating of all its important properties based on the SAC solder including its alloying of elements and nanoparticles addition for further understanding.
Journal
Soldering & Surface Mount Technology – Emerald Publishing
Published: May 27, 2014
Keywords: Pb‐free; Solder joints; Solder; Sn‐Ag‐Cu; Interconnections