Add to ORKGA low cost approach to obtain bumped dice using electroless nickel under bump metallization and different solder bumping techniques was realized in this work. This paper demonstrated the use of electroless Ni(P)-Au UBM for flip chip interconnections with solder applied by either stencil printing, solder ball placement, or mechanical solder bumping for an automotive application. In order to characterize the performance and reliability of such flip chip interconnections, the influence of the growth of NiSn intermetallics during thermal aging at 150 degrees C on their electrical performance was evaluated in this work. In this respect, two near-eutectic lead-tin alloys with different dopants were used. The results obtained are compared with tho...
A driving force to achieve increased speed and performance along with higher I/O count is the Flip C...
The reliability of electroless Ni(P) under-bump metallization (UBM) was evaluated via temperature cy...
Three lead-free solder bumps (Sn-0.7Cu, Sn-3.5Ag, Sn-4Ag-0.5Cu) were produced by stencil printing of...
The effects of under bump metallurgy (UBM) microstructures on the intermetallic compound (IMC) growt...
This paper presents a flip chip technique based on electroless Ni-Au bumping and stencil printing of...
We developed an Au/Ni-Zn/Ti under bump metallurgy (UBM) for Pb-free solders. Au/Ni-Zn/Ti and Au/Ni/T...
Flip chip offers many advantages including more I/O count at a limited chip size, enhanced electrica...
Flip Chip (FC) Technology is gaining an increased level of importance for a variety of applications ...
The reliability of electroless Ni(P) under-bump metallization (UBM) was evaluated via temperature cy...
Flip chip assembly on flexible organic substrates is facing increasing interest. In consumer product...
To achieve a higher I/O count, increased speed along with increased performance, the flip-chip techn...
The bumping process plays a critical role in flip chip technology. A low cost bumping process has be...
To achieve a higher I/O count, increased speed along with increased performance, the flip-chip techn...
Flip chip technology is a key driver for new complex system architectures and high-density packaging...
A driving force to achieve increased speed and performance along with higher I/O count is the Flip C...
A driving force to achieve increased speed and performance along with higher I/O count is the Flip C...
The reliability of electroless Ni(P) under-bump metallization (UBM) was evaluated via temperature cy...
Three lead-free solder bumps (Sn-0.7Cu, Sn-3.5Ag, Sn-4Ag-0.5Cu) were produced by stencil printing of...
The effects of under bump metallurgy (UBM) microstructures on the intermetallic compound (IMC) growt...
This paper presents a flip chip technique based on electroless Ni-Au bumping and stencil printing of...
We developed an Au/Ni-Zn/Ti under bump metallurgy (UBM) for Pb-free solders. Au/Ni-Zn/Ti and Au/Ni/T...
Flip chip offers many advantages including more I/O count at a limited chip size, enhanced electrica...
Flip Chip (FC) Technology is gaining an increased level of importance for a variety of applications ...
The reliability of electroless Ni(P) under-bump metallization (UBM) was evaluated via temperature cy...
Flip chip assembly on flexible organic substrates is facing increasing interest. In consumer product...
To achieve a higher I/O count, increased speed along with increased performance, the flip-chip techn...
The bumping process plays a critical role in flip chip technology. A low cost bumping process has be...
To achieve a higher I/O count, increased speed along with increased performance, the flip-chip techn...
Flip chip technology is a key driver for new complex system architectures and high-density packaging...
A driving force to achieve increased speed and performance along with higher I/O count is the Flip C...
A driving force to achieve increased speed and performance along with higher I/O count is the Flip C...
The reliability of electroless Ni(P) under-bump metallization (UBM) was evaluated via temperature cy...
Three lead-free solder bumps (Sn-0.7Cu, Sn-3.5Ag, Sn-4Ag-0.5Cu) were produced by stencil printing of...