Plasma etch and dielectric deposition processes for TSV Reveal

Through-Silicon Vias [TSV] offer improved system performance by reducing interconnect length to increase device speeds, and by using stacking to reduce package form-factors and enabling heterogeneous device integration. Via Reveal' [VR] - a sequence of wafer back side process steps - is key to...

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Hauptverfasser:	Buchanan, K., Thomas, D., Griffiths, H., Crook, K., Archard, D., Carruthers, M., Tanaka, M.
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creator	Buchanan, K. Thomas, D. Griffiths, H. Crook, K. Archard, D. Carruthers, M. Tanaka, M.
description	Through-Silicon Vias [TSV] offer improved system performance by reducing interconnect length to increase device speeds, and by using stacking to reduce package form-factors and enabling heterogeneous device integration. Via Reveal' [VR] - a sequence of wafer back side process steps - is key to the successful implementation of TSV. After via formation, typically using a via-middle approach, finished CMOS wafers or interposers are temporarily bonded, face-down, to glass carriers. The TSV are then `revealed' using a combination of Si back-grind and plasma etch steps, and then passivated with dielectric. VR processes must maintain acceptably low Total Thickness Variation [TTV] to allow subsequent bonding/stacking steps. Thermal budgets must also be compatible with carrier bonding adhesives - a particular challenge for dielectric deposition. This paper will focus on 300mm plasma etch and low temperature dielectric Plasma Enhanced Chemical Vapour Deposition [PECVD] processes for VR on 300mm substrates.
doi_str_mv	10.1109/3DIC.2012.6262986
format	Conference Proceeding
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title	Plasma etch and dielectric deposition processes for TSV Reveal
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