极紫外光刻
材料科学
堆积
极端紫外线
平版印刷术
纳米技术
紫外线
光刻
X射线光电子能谱
光刻胶
纳米团簇
路易斯酸
抵抗
光电子学
双层
化学稳定性
分子
锡
聚合物
钨
化学工程
纳米光刻
耐化学性
氟
生物分子
作者
Yejin Ku,Gayoung Kim,Minseung Kim,Hyungju Ahn,Jin‐Kyun Lee,Jiho Kim,Byeong‐Gyu Park,Dohyun Moon,Sangsul Lee,Seohyeon Lee,Yu Ha Jang,Byung Jun Jung,Hyun Seok Kim,Changhyeon Lee,Su‐Mi Hur,Ji Young Park,Chawon Koh,Tsunehiro Nishi,Hyunwoo Kim
标识
DOI:10.1002/adfm.202525300
摘要
Abstract To unlock the full potential of extreme ultraviolet lithography (EUVL) utilizing high numerical aperture (NA) optics, tin‐oxo nanoclusters (TOCs) have emerged as a promising platform for photoresists (PRs). Although TOC‐based PRs offer distinct advantages, their intrinsic Lewis acidity must be carefully managed to prevent undesirable interactions during lithographic processing. To address this, fluoroalkylated TOCs are devised, exploiting the unique properties of carbon–fluorine (C–F) bonds. By employing targeted counter‐anion selection, N‐TOC6 is synthesized, a material exhibiting robust etch resistance and solubility‐switching behavior under EUV exposure, demonstrating the potential of fabricating sub‐10 nm patterns. Supported by 19 F NMR and XPS analyses, it is proposed that the presence of C–F bonds reduces the affinity of Sn atoms for airborne Lewis basic molecules by forming coordination contacts with the Lewis acidic Sn centers, thereby improving pattern stability post‐exposure. Additionally, N‐TOC6 exhibits chemical orthogonality with non‐fluorinated TOCs, facilitating bilayer stacking that enhances EUVL sensitivity. This study highlights the critical role of fluorine chemistry in achieving high‐performance, energy‐efficient lithographic materials for next‐generation chip manufacturing in the artificial intelligence era.
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