Gate all around stacked nanosheet FET’s have emerged as the next technology to FinFET’s for beyond 7-nm scaling. With EUV technology integrated into manufacturing at 7nm, there is great interest to enable EUV direct print patterning for nanosheet technology in the FEOL. While sheet and gate pitches expected for the beyond 7nm node fall within the EUV direct print regime (>40nm), it is unclear if direct print solutions can meet device performance requirements at technology critical sheet widths and gate lengths. Here, we demonstrate electrical performance of nanosheet FET’s with 20 – 80 nm wide sheets with 40-150 nm pitch gates patterned with single expose EUV. We compare results against a benchmark double patterning process towards meeting variability, device and critical dimension targets. We also explore the limits of process and material knobs - resists, illuminations and etch chemistries with the specific goal of reducing LER/LWR and towards shrink for further scaling. Our results demonstrate crossover points between direct print EUV and double patterning processes for nanosheet technology and identify relevant design guidelines and focus areas to successfully enable EUV for the FEOL in nanosheets.
Gate all around stacked nanosheet FET’s have emerged as the next technology to FinFET’s for beyond 7-nm scaling. With EUV technology integrated into manufacturing at 7nm, there is great interest to enable EUV direct print patterning for nanosheet patterning as a replacement to complex double patterning schemes. While front-up sheet pitches and gate pitches expected for the beyond 7nm node fall well within the EUV direct print regime (>40nm), it is unclear if direct print solutions can meet variation requirements at technology minimum sheet widths and gate lengths. Here, we explore the crossover point between direct print EUV and optical/EUV based double patterning processes for sheets and gates in the 40 – 50 nm sheet pitch/CPP regime. We demonstrate that to enable the minimum sheet widths of <20nm required for the technology, direct bright field print with shrink results in high variability. We develop a tone invert process with darkfield sheet print that utilizes a polymerizing etch to reduce variability and achieve sub-20nm sheet widths with reduced variability, comparable to a self-aligned double patterning (SADP) process. With gate length variation requirements being tighter, we show that SADP still yields a considerable improvement in line edge/width roughness over a direct print process. We project EUV technology into the future to quantify improvements that would enable direct printed gates that match SADP. Our results will provide a guideline to down-select patterning processes for the nanosheet front end while optimizing cost and complexity.
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