光学
平版印刷术
材料科学
超材料
等离子体子
电子束光刻
贝塞尔光束
光刻
光刻胶
栅栏
表面等离子体子
下一代光刻
梁(结构)
X射线光刻
等离子透镜
无光罩微影
光电子学
表面等离子体激元
图层(电子)
抵抗
物理
纳米技术
作者
Qijian Jin,Gaofeng Liang,Gang Chen,Fen Zhao,Shaokui Yan,Kun Zhang,Mengyu Yang,Qi Zhang,Zhongquan Wen,Zhihai Zhang
出处
期刊:Optics Letters
[Optica Publishing Group]
日期:2020-05-07
卷期号:45 (11): 3159-3159
被引量:7
摘要
Plasmonic lithography can utilize evanescent waves to produce subdiffraction patterns. However, the high loss and shallow depth of patterns severely obstruct its application in practice. In this work, a large focal depth is achieved for deep subwavelength lithography. It is accomplished by employing radially polarized light to excite surface plasmons on a concentric annular grating and combining designed epsilon-near-zero metamaterial to select a high spatial frequency mode, which can shape an evanescent Bessel beam in a photoresist (PR). Moreover, the intensity distribution of the subdiffraction beam can be further enhanced and uniformized by adding reflective layers. It is shown that a needle-like beam with a focal depth of over 500 nm (1.23λ) is formed in the PR layer, and the full width at half maximum of the beam is widened from only 80 nm (0.2λ) to 94 nm (0.23λ). The analyses indicate that this design is applicable for direct writing lithography to produce super-resolution patterns with small feature size, high aspect ratio, and strong field intensity.
科研通智能强力驱动
Strongly Powered by AbleSci AI