材料科学
制作
纳米技术
薄脆饼
拉曼散射
纳米光刻
基质(水族馆)
罗丹明6G
溅射
拉曼光谱
分子
薄膜
光学
医学
海洋学
替代医学
物理
化学
有机化学
病理
地质学
作者
Qiang Zhao,Huan Yang,Bangbang Nie,Yongsong Luo,Jinyou Shao,Gang Li
标识
DOI:10.1021/acsami.1c22465
摘要
The metallic nanogap has been proved as an efficient architecture for surface-enhanced Raman scattering (SERS) applications. Although a lot of nanogap fabrication methods have been proposed in the last few decades, the economical and high-yield manufacturing of sub-10 nm gaps remains a challenge. Here, we present a convenient and cost-effective fabrication method for wafer-scale patterning of metallic nanogaps, which simply combines photolithographic metal patterning, swelling-induced nanocracking, and superimposition metal sputtering without requiring expensive nanofabrication equipment. By controlling the swelling time and metal deposition thickness, the gap size can be precisely defined, down to the sub-10 nm scale. Furthermore, we demonstrate that the fabricated nanogap array can be used as an excellent SERS substrate for molecule measurements and shows a high Raman enhancement factor of ∼108 and a high sensitivity for the detection of rhodamine 6G (R6G) molecules, even down to 10-14 M, indicating an extraordinary capability for single-molecule detection. Due to its high controllability and wafer-scale fabrication capability, this nanogap fabrication method offers a promising route for highly sensitive and economical SERS detections.
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