For decades soldering has been the technology of choice in die bonding. However, due to worldwide health regulations, the most common solder alloys, which contain lead, have been banned. Furthermore, standard solders cannot fulfil the reliability requirements of future power electronic devices. New interconnection technologies have to be developed. One of them is pressure sintering of silver flakes, which forms a highly reliable, highly thermally conductive bond. However, the level of pressure needed (30–50 MPa) requires a powerful pressing equipment and can lead to cracking of the devices and ceramic substrates. A promising development is the use of nano-scaled silver particles, which can be sintered using less pressure due to their superior sintering properties. Preceding thermogravimetric and calorimetric analyses showed that the presence of oxygen eases the sintering of silver nanoparticles. In order to grasp the sintering characteristics of interconnection layers consisting of nano-scaled silver, sintering experiments were conducted in both air and nitrogen. Scanning electronic microscope pictures and density measurements with a laser profilometer show that sintering of the nano-scaled silver in air but under a chip, the case of real interest, is closer to uncovered sintering in nitrogen than in air. Densities remain lower and the microstructures more fine-grained. This is due to limitation of diffusion of organics out of and oxygen into the layer. The application of pressure can make up for this in terms of density. Hence, the increase in density of stencil printed layers of nano-silver when sintering at temperatures ranging from 200 to 300°C, pressures between 0 and 30 MPa, and for a time of up to 1800 s was measured. The density can be set to any value between 60% and 90% of bulk silver by adjusting sintering time and the levels of temperature and pressure. Samples for shear tests were built using dummy chips made of silver-coated copper. They show that after 60 s of sintering at 275°C and 5 MPa a good shear strength of 40 MPa had been established. If the remaining parameters are set correctly, even 5 s of sintering, a temperature of 225°C, or a pressure as low as 2 MPa is sufficient to generate bonds comparable to solder and high pressure sinter joints.
[1]
R. Averback,et al.
Sintering of Nano-Particle Powders: Simulations and Experiments
,
1996
.
[2]
L. Ding,et al.
A molecular dynamics study of sintering between nanoparticles
,
2009
.
[3]
P. C. Clapp,et al.
Nanoparticle sintering simulations
,
1998
.
[4]
C. Gobl,et al.
Low temperature sinter technology die attachment for power electronic applications
,
2010,
2010 6th International Conference on Integrated Power Electronics Systems.
[5]
H. Schwarzbauer,et al.
Novel large area joining technique for improved power device performance
,
1989,
Conference Record of the IEEE Industry Applications Society Annual Meeting,.
[6]
Michael F. Ashby,et al.
A first report on sintering diagrams
,
1973
.
[7]
Guofeng Bai,et al.
Low-temperature sintering of nanoscale silver paste for semiconductor device interconnection
,
2005
.