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Language: English

Conflict of Interest: In relation to this article, we declare that there is no conflict of interest.

Publication history: Received September 12, 2025
Revised November 7, 2025
Accepted November 13, 2025
Available online March 25, 2026

This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/bync/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Facile Fabrication of Metallic Nanoembossing Surfaces Using Anodic Aluminum Oxide-Derived Nanobowl Templates

Hyun-Soo Chang Taeyeong Yun Jang Hwan Kim^† Joonwon Lim^† Hyeong Min Jin^†

Department of Organic Materials Engineering , Chungnam National University ¹Department of Materials Science and Engineering , Chungnam National University ²ICT Nano Conversion Technology Research Center , Korea Electronics Technology Institute ³Department of Materials Science and Engineering , Ajou University ⁴Department of Energy Systems Research , Ajou University ⁵Department of Information Display, College of Science , Kyung Hee University

janghwankim@ajou.ac.kr, joonwon.lim@khu.ac.kr, hyeongmin@cnu.ac.kr

Korean Journal of Chemical Engineering, March 2026, 43(4), 1129-1136(8)
https://doi.org/10.1007/s11814-025-00608-9

Abstract

Periodic nanostructures interact strongly with light, producing unique optical responses such as structural coloration, surface

plasmon resonance (SPR), and photonic-crystal eff ects that are promising for optical devices and sensing applications.

However, conventional nanofabrication techniques are costly, complex, and challenging to scale to large areas. Here, we

introduce a facile, highly reproducible replication strategy for fabricating large-area Au and Ag nanoembossing surfaces

from anodic aluminum oxide (AAO) based nanobowl templates. Microscopic analyses confi rm faithful, high-fi delity transfer

of the nanobowl morphology into the metallic fi lms, while UV–ozone (UVO) pre-treatment tailors surface wettability

and enables defect-free stripping of the noble-metal layers. Notably, the optical response critically depends on structural

periodicity: substrates with a larger periodicity (~ 260 nm) exhibit pronounced spectral modulations and vivid structural

coloration, whereas those with a smaller periodicity (~ 80 nm) show no visible color change, underscoring periodicity and

geometry as key design parameters governing plasmonic responses. The proposed replication strategy is simple, reproducible,

and extendable to various metals and dimensions, off ering a versatile platform for next-generation plasmonic devices,

including structural color fi lters, anti-counterfeiting tags, and optical sensors.

Keywords

Nanoembossing surface · Photonic crystal · Plasmonics · Nanopattern