Papers by Author: Salvo Grasso

Abstract: The interest towards Copper RDL (Re-Distribution Layer) is due to some advantages related to this approach. First of all it is cheaper than conventional Damascene approach; moreover it allows thicknesses as high as 10µm or more whereas with Damascene architecture Cu thickness is limited to <5µm. Figure 1 introduces the architecture concept, which is based on a quite long ECD growth on a substrate with patterned PhotoResist.

Abstract: In damascene architecture, widely used both in flash memories and in DRAM as interconnect scheme since 90 nm node, copper surface is exposed after via etch. A deep understanding of the effect of different wet cleanings on Cu surface is therefore mandatory, not only to ensure an efficient post etch polymer removal, but also to provide a better surface termination, capable to minimize Cu oxidation kinetic and to reduce the growth of Cu-rich precipitates which may negatively effect contact resistance. In this work we have analyzed the Cu surface after processing with several cleaning chemistries -often present in BEOL cleaning processes- using XPS (X-ray Photoelectron Spectroscopy) and ToF-SIMS (Time of Flight – Secondary Ion Mass Spectroscopy), fast and powerful techniques widely used in Cu surface characterization [1]. In addition, the evolution of the surface with storage time has been monitored using the same techniques, in order to better understand the effect of the different cleaning chemistries. XPS has been proven to be very sensitive to monitor Cu oxidation, while ToF-SIMS has been used to reveal organic species adsorbed on the surface.

Abstract: As the detection of inorganic contaminants is of steadily increasing importance for the improvement of yields in microelectronic applications, the aim of one of the joint research activity within the European Integrated Activity of Excellence and Networking for Nano- and Micro-Electronics Analysis (ANNA, site: www.ANNA-i3.org) is the development and assessment of new methodolo¬gies and metrologies for the detection of low concentration inorganic contaminants in silicon and in novel materials. A main objective consist in the benchmarking of various analytical techniques avail¬able in the laboratories of the participating ANNA partners, including the improvement of the res¬pective detection limits as well as the quantitation reliablity of selected analytical techniques such as total-reflection x-ray fluorescence (TXRF) analysis.