Magnetically-enhanced capacitively-coupled plasma etching for 300 mm wafer-scale fabrication of Cu through-silicon-vias for 3D logic integration

We aim to fill the processing gap in 300 mm wafer-scale non-Bosch TSV etch process by developing production-worthy TSV etch solutions for logic-centric 3D integration. This is based on a magnetically-enhanced capacitively-coupled plasma (CCP) etching system. Key factors in this system that contribut...

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Bibliographic Details
Main Authors: Teh, W.H., Caramto, R., Arkalgud, S., Saito, T., Maruyama, K., Maekawa, K.
Format: Conference Proceeding
Language:English
Subjects:
Control systems
Etching
Fabrication
Logic
Magnetic anisotropy
Perpendicular magnetic anisotropy
Plasma applications
Plasma materials processing
Plasma properties
Through-silicon vias
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Summary:We aim to fill the processing gap in 300 mm wafer-scale non-Bosch TSV etch process by developing production-worthy TSV etch solutions for logic-centric 3D integration. This is based on a magnetically-enhanced capacitively-coupled plasma (CCP) etching system. Key factors in this system that contribute to the control of via features such as global sidewall tapering, local sidewall roughness, Si etch rates, mask undercutting and local bowing effects were evaluated. The etching characteristics of anisotropic vias in silicon with nominal feature sizes of, but not limited to 5 mum times 25 mum (AR ~ 5) and 1 mum times 20 mum (AR ~ 20) with minimum pitches of 5 mum and 1 mum, respectively were quantified. 3 mum times 14 mum and 5 mum times 19 mum Cu-filled TSV are demonstrated by having continuous 2kAring TEOS oxide liner/100 nm Ta(TaN) barrier/2kAring Cu seed stack enabled by TSV etch.
ISSN:2380-632X
2380-6338
DOI:10.1109/IITC.2009.5090338