Nanoindentation characterization of Sn-Ag-Sb/Cu substrate IMC Layer subject to thermal aging

Intermetallic compound (IMC) plays great roles in connecting components to PCB boards, as well as die attach materials connecting chips to substrates. Cracks in IMC may leads to failure in an electronic product function. Therefore it is important to investigate the mechanical properties of the IMC t...

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Main Authors: Shualdi W., Bais B., Ahmad I., Omar G., Isnin A.
Other Authors: 36194999100
Format: Conference paper
Published: 2023
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spelling my.uniten.dspace-296012023-12-28T15:05:46Z Nanoindentation characterization of Sn-Ag-Sb/Cu substrate IMC Layer subject to thermal aging Shualdi W. Bais B. Ahmad I. Omar G. Isnin A. 36194999100 9638472600 12792216600 11540084800 24338529400 Intermetallic compound nanoindentation SnAgSb lead free Young modulus Copper alloys Hardness Interfaces (materials) Intermetallics Nanoindentation Silver Silver alloys Soldering alloys Substrates Thermal aging Aging time Cu substrate Die-attach materials Electronic product IMC layer Lead-free solder alloy Nanoindentation tests SnAgSb lead free Solder joints Young modulus Tin Intermetallic compound (IMC) plays great roles in connecting components to PCB boards, as well as die attach materials connecting chips to substrates. Cracks in IMC may leads to failure in an electronic product function. Therefore it is important to investigate the mechanical properties of the IMC to ensure the reliability of the solder joints. In this paper, a nanoindentation test was performed at IMCs that grow on the interface between Sn-Ag-Sb lead-free solder alloy and its Cu substrate. The test was done from planar IMC surface. Prior of that, the specimens were subjected to thermal aging process until 1500 hours at 175�C to accelerate the growth of IMC. The nanotest was executed on specimens with completed aging time for 100, 200, 400, 800 and 1500 hours. Nanoindentation results in this paper show the hardness and Young modulus of IMC composition as a whole, without interpretation of hardness properties of Cu3Sn and Cu6Sn5 individually. The hardness of Sn-Ag-Sb/Cu Substrate IMC Layer is decreasing from 5.583 GPa to4.444 GPa while the Young modulus is decreasing from 106.475 GPa to 128.439 GPa. � 2011 IEEE. Final 2023-12-28T07:05:46Z 2023-12-28T07:05:46Z 2011 Conference paper 10.1109/RSM.2011.6088328 2-s2.0-83755196515 https://www.scopus.com/inward/record.uri?eid=2-s2.0-83755196515&doi=10.1109%2fRSM.2011.6088328&partnerID=40&md5=7ab5243a8ee14c2b1007c5ac1a2d232e https://irepository.uniten.edu.my/handle/123456789/29601 6088328 220 223 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Intermetallic compound
nanoindentation
SnAgSb lead free
Young modulus
Copper alloys
Hardness
Interfaces (materials)
Intermetallics
Nanoindentation
Silver
Silver alloys
Soldering alloys
Substrates
Thermal aging
Aging time
Cu substrate
Die-attach materials
Electronic product
IMC layer
Lead-free solder alloy
Nanoindentation tests
SnAgSb lead free
Solder joints
Young modulus
Tin
spellingShingle Intermetallic compound
nanoindentation
SnAgSb lead free
Young modulus
Copper alloys
Hardness
Interfaces (materials)
Intermetallics
Nanoindentation
Silver
Silver alloys
Soldering alloys
Substrates
Thermal aging
Aging time
Cu substrate
Die-attach materials
Electronic product
IMC layer
Lead-free solder alloy
Nanoindentation tests
SnAgSb lead free
Solder joints
Young modulus
Tin
Shualdi W.
Bais B.
Ahmad I.
Omar G.
Isnin A.
Nanoindentation characterization of Sn-Ag-Sb/Cu substrate IMC Layer subject to thermal aging
description Intermetallic compound (IMC) plays great roles in connecting components to PCB boards, as well as die attach materials connecting chips to substrates. Cracks in IMC may leads to failure in an electronic product function. Therefore it is important to investigate the mechanical properties of the IMC to ensure the reliability of the solder joints. In this paper, a nanoindentation test was performed at IMCs that grow on the interface between Sn-Ag-Sb lead-free solder alloy and its Cu substrate. The test was done from planar IMC surface. Prior of that, the specimens were subjected to thermal aging process until 1500 hours at 175�C to accelerate the growth of IMC. The nanotest was executed on specimens with completed aging time for 100, 200, 400, 800 and 1500 hours. Nanoindentation results in this paper show the hardness and Young modulus of IMC composition as a whole, without interpretation of hardness properties of Cu3Sn and Cu6Sn5 individually. The hardness of Sn-Ag-Sb/Cu Substrate IMC Layer is decreasing from 5.583 GPa to4.444 GPa while the Young modulus is decreasing from 106.475 GPa to 128.439 GPa. � 2011 IEEE.
author2 36194999100
author_facet 36194999100
Shualdi W.
Bais B.
Ahmad I.
Omar G.
Isnin A.
format Conference paper
author Shualdi W.
Bais B.
Ahmad I.
Omar G.
Isnin A.
author_sort Shualdi W.
title Nanoindentation characterization of Sn-Ag-Sb/Cu substrate IMC Layer subject to thermal aging
title_short Nanoindentation characterization of Sn-Ag-Sb/Cu substrate IMC Layer subject to thermal aging
title_full Nanoindentation characterization of Sn-Ag-Sb/Cu substrate IMC Layer subject to thermal aging
title_fullStr Nanoindentation characterization of Sn-Ag-Sb/Cu substrate IMC Layer subject to thermal aging
title_full_unstemmed Nanoindentation characterization of Sn-Ag-Sb/Cu substrate IMC Layer subject to thermal aging
title_sort nanoindentation characterization of sn-ag-sb/cu substrate imc layer subject to thermal aging
publishDate 2023
_version_ 1806427731964985344
score 13.214268