Methods for extending working distance using modified photonic crystal for near-field lithography.

Nanotechnology

Key Laboratory of Optoelectronic Technology & Systems (Chongqing University), Ministry of Education, and College of Optoelectronic Engineering, Chongqing University, Chongqing 400044, People's Republic of China.

Published: November 2023

AI Article Synopsis

  • Near-field lithography excels at creating super-resolution nano-patterns, but it has limitations due to a short working distance (WD) caused by the decay of evanescent waves.
  • A new photolithography method using a modified photonic crystal with an embedded defect layer can significantly enhance wave properties, allowing for a much larger WD under air conditions, which helps tackle challenges in real-world manufacturing applications.
  • This technique can produce deep subwavelength patterns (32 nm half-pitch) and various two-dimensional designs with a single exposure using linearly polarized light, making it effective for generating high-quality periodic patterns with strong field intensity and uniformity.

Article Abstract

Near-field lithography has evident advantages in fabricating super-resolution nano-patterns. However, the working distance (WD) is limited due to the exponential decay characteristic of the evanescent waves. Here, we proposed a novel photolithography method based on a modified photonic crystal (PC), where a defect layer is embedded into the all-dielectric multilayer structure. It is shown that this design can amend the photonic band gap and enhance the desired high-waves dramatically, then the WD in air conditions could be extended greatly, which would drastically relax the engineering challenges for introducing the near-field lithography into real-world manufacturing applications. Typically, deep subwavelength patterns with a half-pitch of 32 nm (i.e.,/6) could be formed in photoresist layer at an air WD of 100 nm. Moreover, it is revealed that diversified two-dimensional patterns could be produced with a single exposure using linear polarized light. The analyses indicate that this improved dielectric PC is applicable for near-field lithography to produce super-resolution periodic patterns with large WD, strong field intensity, and great uniformity.

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Source
http://dx.doi.org/10.1088/1361-6528/ad0591DOI Listing

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