Fabrication and RF Property Evaluation of High-Resistivity Si Interposer for 2.5-D/3-D Heterogeneous Integration of RF Devices

Abstract

In this paper, a high-resistivity silicon (HR-Si) interposer integrated with through-silicon via (TSV) electrically grounded coplanar waveguide (CPW) line is presented for 2.5-D/3-D heterogeneous integration of radio frequency (RF) microelectronics devices. In addition, design of TSV interconnection composed of two coaxial ladder-hollow-annular Cu (copper) TSVs of different diameters is utilized to maintain a sufficient freedom for strict standard cleaning to avoid Si resistivity degradation. The formation of the coaxial ladder TSV structure is more beneficial to the subsequent plating process because it reduces the aspect ratio of TSV vias. Hollow-annular Cu TSV is manufactured in order to reduce the problem of mismatch in coefficient of thermal expansion among TSV’s constituent materials. A layer of Au (aurum) film is utilized to passivate the exposed Cu surface of Si interposer. Au is widely used in III–V groups’ devices because of the good compatibility with photonic integrated circuits, conductivity, and corrosion resistance. HR-Si interposer with TSV grounded CPW line and test structure is fabricated and characterized. With the monitoring test results, it can be found that it changes little in the resistivity of Si substrate, though the whole process, which is a basic requirement for RF performance. RF property test results show that the insertion loss is about −0.20 dB/mm at 10 GHz for the presented TSV grounded CPW line and −0.02 dB per TSV. These test results are better than the traditional design. To verify its applicability to 2.5-D/3-D heterogeneous integration, RF microelectronics die is assembled on TSV interposer and tested, and the test results prove that it works properly.