Optimal phosphorous content selection for the soldering reaction of Ni-P under bump metallization with Sn-Ag-Cu solder

Lin, Yung-Chi; Duh, Jenq‐Gong

doi:10.1007/s11664-006-0215-9

Cited by 12 publications

(3 citation statements)

References 26 publications

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“…This linear relationship suggests that the growth of IMC layer in soldering process is controlled by the diffusion mechanism and the thicker IMC layer of composite solders shows that its growth is restrained by the addition of GNSs. Because the formation of interfacial IMC was controlled by diffusion mechanism, so its growth process can be described by an experienced formula [20,21]:…”

Section: Liquid-solid Reactions Studiesmentioning

confidence: 99%

Effects of graphene nanosheets on interfacial reaction of Sn–Ag–Cu solder joints

Xu¹,

Wang²,

Jing³

et al. 2015

Journal of Alloys and Compounds

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Section: Liquid-solid Reactions Studiesmentioning

confidence: 99%

Effects of graphene nanosheets on interfacial reaction of Sn–Ag–Cu solder joints

Xu¹,

Wang²,

Jing³

et al. 2015

Journal of Alloys and Compounds

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“…On the other hand, (Cu, Ni) 6 Sn 5 is preferentially formed if the Cu concentration in the Cu-bearing solder is above 0.5 wt.% [13][14][15][16][17][18]. For a medium Cu content, both (Ni, Cu) 3 Sn 4 and (Cu, Ni) 6 Sn 5 have been observed to form at the joint interface [13][14][15][19][20][21] These results indicate that the concentration of Cu in a solder greatly influences the formation of a variety of interfacial intermetallic compounds between the solder and a Ni-based surface finish. Thus, it is expected that the Cu compound content in a flux also has some impact on the growth of both interfacial IMCs and a P-rich layer at a solder joint with an ENIG surface finish.…”

Section: Introductionmentioning

confidence: 99%

Effects of Cu contents in flux on microstructure and joint strength of Sn–3.5Ag soldering with electroless Ni–P/Au surface finish

Sakurai

Kim

et al. 2012

Microelectronics Reliability

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“…7,8 Feasibility of electroless Co(P) and Co(W,P) to the diffusion barrier to PbSn solder was also reported. 9,10 The researches regarding of the available barrier materials and Pb-free solders, e.g., the interactions of Ni-base barriers and Pb-free solders, [11][12][13][14][15][16][17][18][19][20][21] are rather flourishing in recent years. However, the diffusion barrier characteristics of electroless Co(W,P) to Pb-free solders are less investigated.…”

mentioning

confidence: 99%

Diffusion Barrier Characteristics of Electroless Co(W,P) Thin Films to Lead-Free SnAgCu Solder

Pan

Hsieh

2011

J. Electrochem. Soc.

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Diffusion barrier and bonding characteristics of amorphous and polycrystalline electroless Co(W,P) layers (α-Co(W,P) and polyCo(W,P)) to SnAgCu (SAC) solder were investigated. In the SAC/α-Co(W,P) sample subjected to liquid-state aging at 250 • C, the spallation of intermetallic compound (IMC) into solder, a nano-crystalline P-rich layer at SAC/Co(W,P) interface, and the recrystallized Co(W,P) containing Co 2 P precipitates were observed. As to the SAC/α-Co(W,P) sample subjected to solid-state aging at 150 • C, a thick IMC layer neighboring to the P-rich layer formed at the solder/Co(W,P) interface. Liquid-state aging resulted in an IMC mixture without spallation whereas solid-state aging induced a layer-like IMC in SAC/poly-Co(W,P) samples. Amorphous W-rich layers were also observed in SAC/poly-Co(W,P) samples and it could not inhibit subsequent alloy reactions in the samples. Analytical results indicated the α-Co(W,P) is a sacrificial-plus stuffed-type barrier whereas the poly-Co(W,P) is mainly a sacrificial barrier. The activation energies of IMC growth were 110.7 and 81.8 kJ/mol for SAC/α-Co(W,P) and SAC/poly-Co(W,P) samples, respectively. High P content in α-Co(W,P) was found to degrade the bonding strength to the solder as revealed by the shear test and the control of P content would be a key issue for electroless plating layer applied to under bump metallurgy as the diffusion barrier.

show abstract

Optimal phosphorous content selection for the soldering reaction of Ni-P under bump metallization with Sn-Ag-Cu solder

Cited by 12 publications

References 26 publications

Effects of graphene nanosheets on interfacial reaction of Sn–Ag–Cu solder joints

Effects of graphene nanosheets on interfacial reaction of Sn–Ag–Cu solder joints

Effects of Cu contents in flux on microstructure and joint strength of Sn–3.5Ag soldering with electroless Ni–P/Au surface finish

Diffusion Barrier Characteristics of Electroless Co(W,P) Thin Films to Lead-Free SnAgCu Solder

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