Fabrication and assembly of Cu-RDL-based 2.5-D Low-Cost Through Silicon Interposer (LC-TSI)

Lin, Jong Kai; Chang, Ka Fai; Zhang, Songbai; Yu, Li Hong; Katti, Guruprasad; Ho, S. W.; Li Hong, Yu; Songbai, Zhang; Dutta, Rahul; Weerasekera, Roshan; Ka Fai, Chang; Jong-Kai, Lin; Vempati, Srinivasa Rao; Bhattacharya, Surya

doi:10.1109/MDAT.2015.2424429

Fabrication and assembly of Cu-RDL-based 2.5-D Low-Cost Through Silicon Interposer (LC-TSI)

Lin, Jong Kai; Chang, Ka Fai; Zhang, Songbai; Yu, Li Hong; Katti, Guruprasad; Ho, S. W.; Li Hong, Yu; Songbai, Zhang; Dutta, Rahul; Weerasekera, Roshan; Ka Fai, Chang; Jong-Kai, Lin; Vempati, Srinivasa Rao; Bhattacharya, Surya

Authors

Jong Kai Lin

Ka Fai Chang

Songbai Zhang

Li Hong Yu

Guruprasad Katti

S. W. Ho

Yu Li Hong

Zhang Songbai

Rahul Dutta

Roshan Weerasekera Roshan.Weerasekera@uwe.ac.uk
Senior Lecturer

Chang Ka Fai

Lin Jong-Kai

Srinivasa Rao Vempati

Surya Bhattacharya

Abstract

A through silicon interposer (TSI) fabrication process and detailed characterization and measurement results of redistribution layers and through silicon vias for low-cost 2.5-D integration is reviewed. Polymer-based Cu-RDL interconnects provide a CMP less low-cost fabrication alternative enabling outsourced semiconductor assembly and test (OSATs) to fabricate and assemble a 2.5-D low-cost through silicon interposer (LC-TSI) in low-cost infrastructure facilities. Standard TSV processing involving etch, isolate, seed layer deposition, and Cu-fill is employed. First, TSVs are etched using standard BOSCH etch, followed by isolation using subatmospheric chemical vapor deposition (SACVD) process and TaN barrier seed deposition and end up with the Cu electroplating (ECP) and CMP. At the first step, SiO 2 passivation is performed followed by the Ti/Cu seed layer sputtering as step 2. In step 3, photoresist (PR) is spin coated and soft baked followed by the exposure and development of PR in step 4. Comparing the manufacturing costs of Cu-damascene as well as Cu-RDL technologies, it is expected that adapting Cu-RDL technology should effectively reduce the 2.5-D TSI manufacturing cost by 20% based on our cost model. The manufacturing cost is expected to reduce further by 10%-12% when the lithography exposure wavelength is changed from i-line lithography to GHI-line lithography.

Journal Article Type	Article
Acceptance Date	Apr 20, 2013
Online Publication Date	Apr 20, 2015
Publication Date	Jan 1, 2015
Deposit Date	Feb 1, 2017
Journal	IEEE Design and Test
Print ISSN	2168-2356
Publisher	Institute of Electrical and Electronics Engineers
Peer Reviewed	Peer Reviewed
Volume	32
Issue	4
Pages	23-31
DOI	https://doi.org/10.1109/MDAT.2015.2424429
Keywords	low cost Through-Silicon Interposer (TSI), polymer based Cu-RDL technology
Public URL	https://uwe-repository.worktribe.com/output/830530
Publisher URL	http://dx.doi.org/10.1109/MDAT.2015.2424429
Contract Date	Feb 1, 2017

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Abstract

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