Precision fabrication of EUVL programmed defects with helium ion beam lithography

The availability of metrology solutions, one of the critical factors to drive leading-edge semiconductor devices and processes, can be confronted with difficulties in the advanced nodes. For developing new metrology solutions, highquality test structures fabricated at specific sizes are needed. Electron-beam direct-write lithography has been utilized to manufacture such samples. However, it can encounter significant-resolution difficulties and require complicated process optimization in sub-10-nm nodes. This study investigates the feasibility and patterning control of metrology test structure fabrication by helium-ion-beam direct-write lithography (HIBDWL). Features down to IRDS 1.5-nm node are resolvable without needing any resolution enhancement technique from the lithography simulation. Further, patterns beyond 1.5-nm node can be achievable with the help of proximity effect correction technique. Preliminary results of simulation demonstrate that HIBDWL can be a promising alternative for fabricating programmed defects (PDs) and test structure to develop advanced metrology solutions in sub-7-nm nodes.

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