Atomic layer deposition and its derivatives for extreme ultraviolet (EUV) photoresist applications

Solution-processed photoresists have been forerunners in semiconductor patterning for decades. Even with the drastic reduction in photolithography wavelength, traditional spin-on resists still support the fabrication of the most advanced, sub-5 nm node logic and memory devices using EUV lithography...

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Veröffentlicht in:	Japanese Journal of Applied Physics 2023-06, Vol.62 (SG), p.SG0812
Hauptverfasser:	Le, Dan N., Park, Taehee, Hwang, Su Min, Kim, Jin-Hyun, Jung, Yong Chan, Tiwale, Nikhil, Subramanian, Ashwanth, Lee, Won-Il, Choi, Rino, Sung, Myung M., Nam, Chang-Yong, Kim, Jiyoung
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Sprache:	eng
Schlagworte:	area-selective deposition (ASD) atomic layer deposition (ALD) Atomic layer epitaxy EUVL extreme ultraviolet lithography hybrid resists MATERIALS SCIENCE Memory devices molecular atomic layer deposition (MALD) Photolithography Photoresists Resists vapor-phase infiltration (VPI)
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container_title	Japanese Journal of Applied Physics
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creator	Le, Dan N. Park, Taehee Hwang, Su Min Kim, Jin-Hyun Jung, Yong Chan Tiwale, Nikhil Subramanian, Ashwanth Lee, Won-Il Choi, Rino Sung, Myung M. Nam, Chang-Yong Kim, Jiyoung
description	Solution-processed photoresists have been forerunners in semiconductor patterning for decades. Even with the drastic reduction in photolithography wavelength, traditional spin-on resists still support the fabrication of the most advanced, sub-5 nm node logic and memory devices using EUV lithography (EUVL) ( λ = 13.5 nm). However, trade-off between resolution, sensitivity, and roughness in the conventional resists pose a critical challenge in the race towards device downscaling to 1 nm node. While great efforts are being made to improve spin-on EUV photoresist performance, there has been emergence of new approaches focused on developing novel resists via vapor-phase processing routes, such as atomic layer deposition (ALD) and its analogs. This review summarizes recent advances in EUVL photoresist development based on ALD and its derivative techniques, which include ALD-based inorganic–organic dry resists and hybrid resists synthesized by infiltrating conventional spin-on resists. Despite being in the early stage, initial studies have shown the great potential of ALD applications in EUVL photoresist development.
doi_str_mv	10.35848/1347-4065/acce43
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Center for Functional Nanomaterials (CFN)</creatorcontrib><description>Solution-processed photoresists have been forerunners in semiconductor patterning for decades. Even with the drastic reduction in photolithography wavelength, traditional spin-on resists still support the fabrication of the most advanced, sub-5 nm node logic and memory devices using EUV lithography (EUVL) ( λ = 13.5 nm). However, trade-off between resolution, sensitivity, and roughness in the conventional resists pose a critical challenge in the race towards device downscaling to 1 nm node. While great efforts are being made to improve spin-on EUV photoresist performance, there has been emergence of new approaches focused on developing novel resists via vapor-phase processing routes, such as atomic layer deposition (ALD) and its analogs. 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subjects	area-selective deposition (ASD) atomic layer deposition (ALD) Atomic layer epitaxy EUVL extreme ultraviolet lithography hybrid resists MATERIALS SCIENCE Memory devices molecular atomic layer deposition (MALD) Photolithography Photoresists Resists vapor-phase infiltration (VPI)
title	Atomic layer deposition and its derivatives for extreme ultraviolet (EUV) photoresist applications
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