Nano-indentation characterization of Ni–Cu–Sn IMC layer subject to isothermal aging

Lead-free Sn–Ag–Cu(SAC) solder joint on Cu–OSP and ENIG subject to thermal testing leads to IMC growth and causes corresponding reliability concerns at the interface. Modulus and hardness of these IMCs were characterized by Nanoindentation CSM from plan view in this study. A plan-view IMC surface wa...

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Published in	Thin solid films Vol. 504; no. 1; pp. 362 - 366
Main Authors	Xu, Luhua, Pang, John H.L.
Format	Journal Article Conference Proceeding
Language	English
Published	Lausanne Elsevier B.V 10.05.2006 Elsevier Science
Subjects	Condensed matter: structure, mechanical and thermal properties Cross-disciplinary physics: materials science; rheology Elastic modulus Elasticity, elastic constants Exact sciences and technology Intermetallic compound Materials science Mechanical and acoustical properties of condensed matter Mechanical properties of solids Nanoindentation CSM Physics SnAgCu lead-free solder Surface treatments Transport properties of condensed matter (nonelectronic) Tribology and hardness Elastic modulus SnAgCu lead-free solder Intermetallic compound Nanoindentation CSM Thermal diffusion Inorganic compounds Nickel alloys Intermetallic compounds Nanoindentation Polishing Hardness Experimental study Interfaces Young modulus Tin alloys Copper alloys Growth mechanism Aging Reliability Crystal morphology Soldered joints Transition element alloys Crystal structure
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Abstract	Lead-free Sn–Ag–Cu(SAC) solder joint on Cu–OSP and ENIG subject to thermal testing leads to IMC growth and causes corresponding reliability concerns at the interface. Modulus and hardness of these IMCs were characterized by Nanoindentation CSM from plan view in this study. A plan-view IMC surface was prepared by deep etching and slight polishing method. When SAC/Ni(Au) solder joint were subject to thermal aging, elastic modulus of the NiCuSn IMC at SAC/ENIG specimen changed from 207 to 146 GPa with different aging time up to 500 h. The hardness decreased from 10.0 to 7.3 GPa. For SAC/Cu–OSP reaction couple, elastic modulus of Cu 6Sn 5 kept constant at 97.0 GPa and hardness about 5.7 GPa. The modulus of Cu 3Sn after 500 h thermal aging was 115.7 GPa. The change of modulus is caused by solid state diffusion process during thermal aging where the morphology and crystal structure of Ni,–Cu–Sn IMC is changing. The calculation of modulus and hardness for IMC layers was based on nanoindentation CSM test results and was compared with reported results.
AbstractList	Lead-free Sn-Ag-Cu(SAC) solder joint on Cu-OSP and ENIG subject to thermal testing leads to IMC growth and causes corresponding reliability concerns at the interface. Modulus and hardness of these IMCs were characterized by Nanoindentation CSM from plan view in this study. A plan-view IMC surface was prepared by deep etching and slight polishing method. When SAC/Ni(Au) solder joint were subject to thermal aging, elastic modulus of the NiCuSn IMC at SAC/ENIG specimen changed from 207 to 146 GPa with different aging time up to 500 h. The hardness decreased from 10.0 to 7.3 GPa. For SAC/Cu-OSP reaction couple, elastic modulus of Cu6Sn5 kept constant at 97.0 GPa and hardness about 5.7 GPa. The modulus of Cu3Sn after 500 h thermal aging was 115.7 GPa. The change of modulus is caused by solid state diffusion process during thermal aging where the morphology and crystal structure of Ni-Cu-Sn IMC is changing. The calculation of modulus and hardness for IMC layers was based on nanoindentation CSM test results and was compared with reported results. Lead-free Sn–Ag–Cu(SAC) solder joint on Cu–OSP and ENIG subject to thermal testing leads to IMC growth and causes corresponding reliability concerns at the interface. Modulus and hardness of these IMCs were characterized by Nanoindentation CSM from plan view in this study. A plan-view IMC surface was prepared by deep etching and slight polishing method. When SAC/Ni(Au) solder joint were subject to thermal aging, elastic modulus of the NiCuSn IMC at SAC/ENIG specimen changed from 207 to 146 GPa with different aging time up to 500 h. The hardness decreased from 10.0 to 7.3 GPa. For SAC/Cu–OSP reaction couple, elastic modulus of Cu 6Sn 5 kept constant at 97.0 GPa and hardness about 5.7 GPa. The modulus of Cu 3Sn after 500 h thermal aging was 115.7 GPa. The change of modulus is caused by solid state diffusion process during thermal aging where the morphology and crystal structure of Ni,–Cu–Sn IMC is changing. The calculation of modulus and hardness for IMC layers was based on nanoindentation CSM test results and was compared with reported results.
Author	Xu, Luhua Pang, John H.L.
Author_xml	– sequence: 1 givenname: Luhua surname: Xu fullname: Xu, Luhua – sequence: 2 givenname: John H.L. surname: Pang fullname: Pang, John H.L. email: mhlpang@ntu.edu.sg
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Snippet	Lead-free Sn–Ag–Cu(SAC) solder joint on Cu–OSP and ENIG subject to thermal testing leads to IMC growth and causes corresponding reliability concerns at the... Lead-free Sn-Ag-Cu(SAC) solder joint on Cu-OSP and ENIG subject to thermal testing leads to IMC growth and causes corresponding reliability concerns at the...
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SubjectTerms	Condensed matter: structure, mechanical and thermal properties Cross-disciplinary physics: materials science; rheology Elastic modulus Elasticity, elastic constants Exact sciences and technology Intermetallic compound Materials science Mechanical and acoustical properties of condensed matter Mechanical properties of solids Nanoindentation CSM Physics SnAgCu lead-free solder Surface treatments Transport properties of condensed matter (nonelectronic) Tribology and hardness
Title	Nano-indentation characterization of Ni–Cu–Sn IMC layer subject to isothermal aging
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