Abstract
A phase-field-crystal model is used to investigate the processing-structure-protrusion relationship of blind Cu through-silicon vias (TSVs) at the atomic scale. A higher temperature results in a larger TSV protrusion. Deformation via dislocation motion dominates at temperatures lower than around 300°C, while both diffusional and dislocation creep occur at temperatures greater than around 300°C. TSVs with smaller sidewall roughness $R_{a}$ and wavelength $\lambda _{a}$ exhibit larger protrusions. Moreover, different protrusion profiles are observed for TSVs with different grain structures. Both protrusions and intrusions are observed when a single grain is placed near the TSV top end, while the top surface protrudes near both edges when it contains more grains. Under symmetric loading, coalescence of the grains occurs near the top end, and a symmetric grain structure can accelerate this process. The strain distributions in TSVs are calculated, and the eigenstrain projection along the vertical direction can be considered an index to predict the TSV protrusion tendency.
Highlights
Three-dimensional (3D) devices, e.g., stacked high bandwidth memory (HBM) [1], are expected to be developed to keep up with the increasing package density requirements
In this study, the PFC model is used to investigate the effects of temperature, sidewall roughness and grain structure on the Cu through-silicon vias (TSVs) protrusion at the atomic scale
A larger protrusion results when the TSV is subjected to a higher temperature
Summary
Three-dimensional (3D) devices, e.g., stacked high bandwidth memory (HBM) [1], are expected to be developed to keep up with the increasing package density requirements. In realizing 3D packaging, an important idea is to utilize through-silicon via (TSV) technology [2]–[4]. The mismatch of the thermal expansion coefficients between the normal filler material Cu and the surrounding silicon frequently leads to protrusion when the TSV structures are subjected to thermal processing [5]. This protrusion causes damage to the back-end-of-line (BEoL) layers and failure of 3D packaging, posing a serious reliability issue to be solved. When investigating Cu TSV protrusion, temperature is an important processing parameter.
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