Copper micro and nano particles mixture for 3D interconnection application
Copper is a well-known material used for interconnections application. It offers economical advantage over silver and has high electrical conductivity. Studies on copper nano-paste (comprising of monodispersed nano-particles) application on surfaces have reported cracking and a low packing densit...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2016
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| Online Access: | http://hdl.handle.net/10356/67807 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Copper is a well-known material used for interconnections application. It offers economical
advantage over silver and has high electrical conductivity. Studies on copper nano-paste
(comprising of monodispersed nano-particles) application on surfaces have reported cracking
and a low packing density with high porosity. A novel method utilizing a mixture of copper
micron sized particles and nano-particles paste is proposed and investigated. This enables high
packing density with low resistivity thus improving the interconnection for low temperature
electronics packaging. A model to find the optimum micro-nano particle size ratio is
established to achieve high packing density. The algorithm is based on Monte Carlo method.
Firstly, the large micro-particles are arranged in Face-Centered-Cubic (FCC) structure. Next,
a fixed initial number of smaller spheres (nano-particles) are randomly arranged in the
interstitial spaces between the micro- particles. A stepwise increment in nano-particle diameter
at a fixed micro-particle size (1 µm) is carried out until the system reaches a jammed state.
Based on the modeling results, a weight ratio of 6.3:1 between micro- and nano- copper
particles is predicted to provide maximum packing.
Further experiments were carried out to examine the properties of the mixed, micro- and nanopastes. The particles were firstly dispersed in low boiling point organic solvents which are able
to evaporate at low temperature. Afterwards, the three kinds of pastes were inspected under
microscope and SEM images and it is found that the nano-paste has small cracks. To solve the
paste adhesion issue and improve paste performance a new recipe is developed. A washing
procedure to remove the surface oxide on the micro-particles before making the paste and a
method to improve mixture uniformity are developed. Next, Thermal Gravimetric Analysis
(TGA) was carried out to investigate the pastes thermal property. The mixed paste shows a
transitional temperature of ~201 °C, which is lower than reference micro- and nano- paste
respectively. In-situ temperature and resistance measurements show that mixed paste made by
new recipe has lower electrical resistance. After sintering, the mixed paste shows 1.0 Ω of
resistance whereas the micro-paste shows 2.3 Ω of resistance. The resistance of nano-paste
initially decreases to 1.8 Ω then it shows a rapid increase during sintering due to cracks. Besides,
packing density of mixed pastes with different ratios was studied and analyzed using Scanning
Electron Microscopy (SEM) and ImageJ software. The 3:1 mixed paste has lowest porosity
and no cracks were observed. The result is also verified by sheet resistance measurement that the 3:1 mixed paste shows only 0.3 Ω/sq as compared to micro-paste which is 3 Ω/sq. The
deviation between simulation and experiments is possibly because the nano-particles are not
always arranged around micro-particles as expected. As a final application, die to wafer
bonding has been conducted by using the three types of paste and the bond strength is
characterized by shear bond test. Results show that the mixed paste has higher bond strength
of 0.7 MPa than micro- and nano- paste of 0.5 MPa and 0.1 MPa respectively after bonding at
200 °C without pressure. Therefore, this technique could be used in future applications such as
low temperature metal-metal bonding for 3D interconnects application. |
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