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Abstract
Next generation DRAM series will rely on the ability
to obtain low resistance contact junctions in very tight spaces and narrow trenches. Current DRAM technology uses a polycrystalline plug, followed by silicidation with Ti metal to obtain a low resistance interface. The upcoming generations of DRAM series requires us to narrow the bit contact (BC) CD down to ~10 nm and further decrease the BC resistance. This requires the use of a highly doped epitaxial plug to obtain low resistance BC. In this paper, we
study the growth mechanisms and physics of SiP epitaxy. We explain the process optimizations that were undertaken to obtain an epitaxial plug close to our device specifications. We also explore the fundamental limitations of epitaxial growth, referred in this paper as Epitaxy trilemma. TEM/STEM and fundamental material characterizations showed the fundamental mechanisms
behind the growth of SiP epi. Furthermore, we also characterized the effects of post-processing on the structural integrity of the BC.
