Three-dimensional integration with through-silicon vias (TSVs) has emerged as an effective solution to overcome the wiring limit imposed on device density and performance. However, thermal stresses induced in TSV structures raise serious thermomechanical reliability concerns. In this paper, we analyze the near-surface stress distribution in a TSV structure based on a semi-analytic approach and finite element method, in comparison with micro-Raman measurements. In particular, the depth dependence of the stress distribution and the effect of elastic anisotropy of Si are illustrated to properly interpret the Raman data. The effects of the surface oxide layer and metal plasticity of the via material on the stress and Raman measurements are discussed. The near-surface stress characteristics revealed by the modeling and Raman measurements are important for design of TSV structures and device integration.
Articles you may be interested inMicro-Raman spectroscopy and analysis of near-surface stresses in silicon around through-silicon vias for threedimensional interconnects J. Appl. Phys. 111, 063513 (2012); 10.1063/1.3696980Micro-scale measurement and modeling of stress in silicon surrounding a tungsten-filled through-silicon via J. Appl. Phys. 110, 073517 (2011) Abstract. Continuous scaling of on-chip wiring structures has brought significant challenges for materials and processes beyond the 32 nm technology node in microelectronics. Recently threedimensional (3-D) integration with through-silicon-vias (TSVs) has emerged as an effective solution to meet the future interconnect requirement. Thermo-mechanical reliability is a key concern for the development of TSV structures used in die stacking as 3-D interconnects. This paper examines the effect of thermal stresses on interfacial reliability of TSV structures. First, the three-dimensional distribution of the thermal stress near the TSV and the wafer surface is analyzed. Using a linear superposition method, a semi-analytic solution is developed for a simplified structure consisting of a single TSV embedded in a silicon (Si) wafer. The solution is verified for relatively thick wafers by comparing to numerical results obtained by finite element analysis (FEA). Results from the stress analysis suggest interfacial delamination as a potential failure mechanism for the TSV structure. Analytical solutions for various TSV designs are then obtained for the steady-state energy release rate as an upper bound for the interfacial fracture driving force, while the effect of crack length is evaluated numerically by FEA. Based on these results, the effects of TSV designs and via material properties on the interfacial reliability are elucidated. Finally, potential failure mechanisms for TSV pop-up due to interfacial fracture are discussed.
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