Publications

Schmitt, Rebecca P.; Perez, Carlos P.; Gonzales Kirkpatrick, Cielo M.; McClain, Jaime L.; McDow, Jessica M.; Jordan, Matthew J.; Baca, Ehren B.; Hollowell, Andrew E.

Abstract not provided.

McDow, Jessica M.; Schmitt, Rebecca P.; Hirabayashi, Mieko H.; Baca, Ehren B.; Menk, Lyle A.; Hollowell, Andrew E.; Jordan, Matthew J.

Abstract not provided.

Journal of the Electrochemical Society

Schmitt, Rebecca P.; Menk, Lyle A.; Baca, Ehren B.; Bower, John E.; Romero, Joseph A.; Jordan, Matthew J.; Jackson, Nathan; Hollowell, Andrew E.

High density interconnects are required for increased input/output for microelectronics applications, incentivizing the development of Cu electrochemical deposition (ECD) processes for high aspect ratio through-silicon vias (TSVs). This work outlines Cu ECD processes for 62.5 μm diameter TSVs, etched into a 625 μm thick silicon substrate, a 10:1 aspect ratio. Cu ECD in high aspect ratio features relies on a delicate balance of electrolyte composition, solution replenishment, and applied voltage. Implementing a CuSO4-H2SO4 electrolyte, which contains suppressor and a low chloride concentration, allows for a tunable relationship between applied voltage and localized deposition in the vias. A stepped potential waveform was applied to move the Cu growth front from the bottom of the via to the top. Sample characterization was performed through mechanical cross-sections and X-ray computed tomography (CT) scans. The CT scans revealed small seam voids in the Cu electrodeposit, and process parameters were tuned accordingly to produce void-free Cu features. During the voltage-controlled experiments, measured current data showed a characteristic current minimum, which was identified as an endpoint detection method for Cu deposition in these vias. We believe this is the first report of this novel endpoint detection method for TSV filling.

Schmitt, Rebecca P.; Menk, Lyle A.; Jordan, Matthew J.; Christopher, Jason C.; Baca, Ehren B.; McDow, Jessica M.; Jackson, Nathan J.; Hollowell, Andrew E.

Abstract not provided.

Schmitt, Rebecca P.; Menk, Lyle A.; Jordan, Matthew J.; Christopher, Jason C.; Baca, Ehren B.; Jackson, Nathan J.; Hollowell, Andrew E.

Abstract not provided.

Journal of Vacuum Science and Technology A: Vacuum, Surfaces and Films

Burkett, Susan L.; Jordan, Matthew J.; Schmitt, Rebecca P.; Menk, Lyle A.; Hollowell, Andrew E.

Through-silicon vias (TSVs) are a critical technology for three-dimensional integrated circuit technology. These through-substrate interconnects allow electronic devices to be stacked vertically for a broad range of applications and performance improvements such as increased bandwidth, reduced signal delay, improved power management, and smaller form-factors. There are many interdependent processing steps involved in the successful integration of TSVs. This article provides a tutorial style review of the following semiconductor fabrication process steps that are commonly used in forming TSVs: deep etching of silicon to form the via, thin film deposition to provide insulation, barrier, and seed layers, electroplating of copper for the conductive metal, and wafer thinning to reveal the TSVs. Recent work in copper electrochemical deposition is highlighted, analyzing the effect of accelerator and suppressor additives in the electrolyte to enable void-free bottom-up filling from a conformally lined seed metal.

McClain, Jaime L.; Hollowell, Andrew E.; Menk, Lyle A.; Schmitt, Rebecca P.; Mook, William M.; Musick, Katherine M.; Grine, Alejandro J.; Serkland, Darwin K.; Nordquist, Christopher N.; Wood, Michael G.

Abstract not provided.

Schmitt, Rebecca P.; Hollowell, Andrew E.; Menk, Lyle A.; Sadler, Corrie L.; Jordan, Matthew J.

Abstract not provided.

Menk, Lyle A.; Schmitt, Rebecca P.; Han, Sang S.; Jordan, Matthew J.; Sadler, Corrie L.; Hollowell, Andrew E.

Abstract not provided.