Bending Strength Evaluation of Si Interposers by PoEF Test Associated With Acoustic Emission Method

Autor:	Chen-Yu Huang, Ming-Yi Tsai, Chia-Ming Liu, Hsien-Lu Chen, Huan-Yin Liu
Rok vydání:	2017
Předmět:	010302 applied physics Materials science Silicon business.industry Delamination chemistry.chemical_element 02 engineering and technology Bending Structural engineering 021001 nanoscience & nanotechnology 01 natural sciences Electronic Optical and Magnetic Materials Stress (mechanics) Acoustic emission Flexural strength chemistry 0103 physical sciences Interposer Integrated circuit packaging Electrical and Electronic Engineering Composite material 0210 nano-technology Safety Risk Reliability and Quality business
Zdroj:	IEEE Transactions on Device and Materials Reliability. 17:364-370
ISSN:	1558-2574 1530-4388
DOI:	10.1109/tdmr.2017.2683505
Popis:	The 2.5-D IC packaging technology is to apply a silicon interposer with Cu through silicon vias (Cu TSVs) as a platform to interconnect and integrate heterogeneous and homogeneous chips horizontally and vertically. The existing Cu TSVs might make the silicon interposers more fragile, due to their structural non-homogeneity and weak interfaces. Thus, the strength determination of silicon interposers becomes one of the important issues for ensuring reliability of 2.5-D packages. This paper aims to determine the bending strengths of silicon interposers (with back-side and front-side surface controls—corresponding to the surfaces with C4 bumps and Cu/SiO2 layers, respectively) using a point-load-on-elastic-foundation test, associated with an acoustic emission (AE) method to detect local material cracks or delamination occurring during the test before interposer breaking. The results indicate that there are a few less-than 50-dB AE signals occurring before interposer breaking, due to the micropad crush on the Cu/SiO2 layer induced by the loading-pin contact for the back-side control case, but not for the front-side control case. In addition, interposer breaking is found to be triggered by the maximum tensile stresses located at the corner of the C4 bump pad for the back-side control case, instead of the micropad crush or Cu TSVs, while at the silicon or Cu/SiO2 layer for the front-side control case. These failure behaviors have been confirmed by theory-validated finite element simulation. The bending strengths of silicon interposers have further been determined by using experimental data associated with finite element analysis by taking into account Cu material nonlinear properties and the Cu/SiO2 layer.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::c2a5e8f1fdd49505b2af6e7b44a5a942 https://doi.org/10.1109/tdmr.2017.2683505 Zobrazit plný text záznamu