Material selection for 3D interconnects for devices working at low/cryogenic temperatures in 3D stacking.

Leuven - PhD
|
More than two weeks ago

As our new PhD researcher in 3D system integration group, you will be involved in the fabrication, 3D bonding, electrical test and characterization of IMC properties at cryogenic temperatures for quantum computers

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For some applications including quantum computers, aerospace, medical devices like MRI, cyclotrons for high energy physics research and cryogenic oxygen generators, electronic circuits and devices must be operated at very low temperatures. For instance, in quantum computers, to prevent unwanted thermal excitation of the states, qubits must work at temperatures around 20-50mK. These applications strongly push for the development of future (3-5 years from now) microelectronics devices and packages which can work reliable at these low temperatures.

At this moment, Sn-based solder bumps are used typically to electrically connect silicon chips to a substrate for packaging, or to each other for 3D-technology (stacking and interconnecting of many thinned Si-chips). These bumps are plated between Cu-pads, called under-bump metal (UBM).

However, at such low temperatures, these conventionally used Sn based solders will undergo a ductile to brittle transition due to a phase change from the white (β) to the gray (α) phase, resulting in powder-like material and thus catastrophic failure of electronic components.   

The goal of this PhD thesis is to select and study possible metals that can be used as solder and UBM for packaging and 3D integration of devices which work at low temperatures.

Indium and bismuth based solders are two potential candidates.

The properties to be studied include:

  • processing related properties, such as wettability and assessment of electroplating
  • material properties such as IMC (intermetallic compound) phase formation, grain size and orientation, and the thermal expansion coefficient. And how these properties change at lower temperatures.
  • mechanical properties such as tensile strength and fracture location, also as a function of (lower) temperature
  • electrical properties such as the resistance in function of (low) temperature
  • reliability properties, such as electromigration and corrosion resistance, at low temperatures

To understand the IMC phase evolution and wettability, phase field and molecular dynamic simulations might be needed as well.

The PhD candidate should be familiar with material science and different analyses techniques. Practical know-how of techniques such as SEM, XPS, Auger, contact angle measurements, TEM, AFM, EBSD is an asset. Experience with electrical measurements to study the electrical properties of different UBM and solder materials is a plus-point.  

Required background: Engineering Technology, Engineering science and material science

Type of work: 10% literature, 20% modeling, 70% experimental

Supervisor: Ingrid De Wolf

Daily advisor: Jaber Derakhshandeh

The reference code for this position is 2020-029. Mention this reference code on your application form.
Chinese nationals who wish to apply for the CSC scholarship, should use the following code when applying for this topic: CSC2020-14.

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