Hostname: page-component-848d4c4894-4hhp2 Total loading time: 0 Render date: 2024-05-10T18:19:08.304Z Has data issue: false hasContentIssue false
  • English
  • Français

Through Wafer Interconnects - A Technology not only for Medical Applications

Published online by Cambridge University Press:  26 February 2011

Gereon Vogtmeier ,
Christian Drabe ,
Ralf Dorscheid ,
Roger Steadman  and
Dr. Alexander Wolter
Gereon Vogtmeier
Affiliation:
gereon.vogtmeier@philips.com, Philips Research Europe - Aachen, Weisshausstrasse 2, Aachen, 52066, Germany
Christian Drabe
Affiliation:
christian.drabe@ipms.fraunhofer.de, Fraunhofer Institute Photonic Microsystems, Maria-Reiche-Str. 2, Dresden, 01109, Germany
Ralf Dorscheid
Affiliation:
ralf.dorscheid@philips.com, Philips Research Europe - Aachen, Weisshausstrasse 2, Aachen, 52066, Germany
Roger Steadman
Affiliation:
roger.steadman@philips.com, Philips Research Europe - Aachen, Weisshausstrasse 2, Aachen, 52066, Germany
Dr. Alexander Wolter
Affiliation:
alexander.wolter@ipms.fraunhofer.de, Fraunhofer Institute Photonic Microsystems, Maria-Reiche-Str. 2, Dresden, 01109, Germany
Get access

Abstract

The foremost driver for the development of fully CMOS compatible Through Wafer Interconnects (TWIs) is the need of very large photodiode arrays for detectors, e.g. in computed tomography applications. The front to back-side contact allows the four-side buttable chip placement of the already large chips (20mm × 22mm2). The TWI technology allows an interconnection for chips up to 280μm thickness. This technique does not require any via opening at the font side, thus enabling a metal signal routing on the active side, on top of the interconnection. The application specific optical sensitive front-side of the chip is fully accessible. The production process is separated into three main steps. The first step is the implementation of the special TWI geometry into the CMOS substrate. Depending on the electrical and geometrical requirements of the circuit, different TWI structures are built with deep trenches (up to 280μm), which are passivated and filled with doped poly-silicon. The technologies used in this process, such as DRIE-etching, oxidation and low pressure CVD, are standard CMOS compatible processes. The use of poly-silicon prevents from achieving very low resistivity interconnections but allows the use of all CMOS process steps for an imager production (no temperature limitation – compared to other TWI process flows). The second step is the standard CMOS processing on the substrate already including the TWIs. The third step is a low temperature back-side process starting with wafer thinning down to 280μm or less to open the implemented TWI structure from the back-side. The thickness may be selected depending on the target application. A modified under ball metallization (UBM) process, which could include also re-routing of signals on the back-side, concludes the process flow until the solder ball placement, or similar bond connections.

The special process flow opens a variety of applications which benefit from the full CMOS compatible processing and the accessible front-side.

Keywords

packagingoptoelectronicmicroelectronics
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 969: Symposium W – Heterogeneous Integration of Materials for Passive Components and Smart Systems , 2006 , 0969-W02-03-V01-03
Copyright
Copyright © Materials Research Society 2007

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Luhta, R., Chappo, M., Harwood, B., Mattson, R., Salk, D., Vrettos, C., “A new 2D-tiled detector for multislice CT”, Proceedings of the SPIE 6142, pp. 275286, 2006 Google Scholar
2. Steadman, R., Morales, F., Vogtmeier, G., Kemna, A., Oezkan, E., Brockherde, W., Hosticka, B., “A CMOS photodiode array with in-pixel data acquisition system for computed tomography”, IEEE J. Solid State Circuits 39, No.7, pp. 10341043, 2004 Google Scholar
3. Bäumer, C., Eick, S., Steadman, R., Vogtmeier, G., “Design and Evaluation of a CMOSPhotosensor with In-Pixel Sigma-Delta Modulator for X-ray Computed Tomography”, Solid-State Circuits Conference, 2006. Proceedings of ESSCIRC '06, to be publishedGoogle Scholar
4. Steadman, R., Vogtmeier, G., Kemna, A., Quossai, S.E. Ibnou, Hosticka, B., “An In-Pixel Current-Mode Amplifier for Computed Tomography”, IEEE letters 2006 Google Scholar
5. Spies, L., Morales, F., Steadman, R., Fiedler, K., Conrads, N., “Performance of prototype modules of a novel multislice CT detector based on CMOS photosensors”, Proceedings SPIE Medical Imaging Conf. 2003, vol. 5030, pp. 490503 Google Scholar
6. Andry, P.S., Tsang, C., Sprogis, E., Patel, C., Wright, S.L., Webb, B.C., Buchwalter, L.P., Manzer, D., Horton, R., Polastre, R., Knickerbocker, J., “A CMOS compatible Process for Fabrication Electrical Through-Vias in Silicon”, Proceedings 56th ECTC conference, pp. 831843, 2006 Google Scholar
7. SB2-Jet, product information PacTechGoogle Scholar
8. Bhardwaj, J.K., Ashraf, H., “Advanced silicon etching using high density plasmas”, Proc. SPIE Micromachining and Microfabrication Process Technology 2639 (1995), pp. 224233 Google Scholar