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Shape-Controlled and Well-Arrayed Heterogeneous Nanostructures via Melting Point Modulation at the Nanoscale

Zhi‐Jun Zhao, Junseong Ahn, Jiwoo Ko, Yongrok Jeong, Moonjeong Bok, Soon Hyoung Hwang, Hyeok-Joong Kang, Sohee Jeon, Jungrak Choi, Inkyu Park, Jun-Ho Jeong

2020ACS Applied Materials & Interfaces27 citationsDOI

Abstract

A novel method for fabricating shape-controlled and well-arrayed heterogeneous nanostructures by altering the melting point of the metal thin film at the nanoscale is proposed. Silver nanofilms (AgNFs) are transformed into silver nanoislands (AgNIs), silver nanoparticles (AgNPs), and silver nanogaps (AgNGs) that are well-ordered and repositioned inside the gold nanoholes (AuNHs) depending on the diameter of the AuNHs, the thickness of the AgNF, and the heating temperature (120–200 °C). This method demonstrates the ability to fabricate uniform, stable, and unique structures with a fast, simple, and mass-producible process. For demonstrating the diverse applicability of the developed structures, high-density AgNGs inside the AuNHs are utilized as surface-enhanced Raman spectroscopy (SERS) substrates. These AgNGs-based SERS substrates exhibit a performance enhancement, which is 1.06 × 106 times greater than that of a metal film, with a relative standard deviation of 19.8%. The developed AgNP/AgNI structures are also used as nonreproducible anti-counterfeiting signs, and the anti-counterfeiting/readout system is demonstrated via image processing. Therefore, our method could play a vital role in the nanofabrication of high-demand nanostructures.

Topics & Concepts

Materials scienceNanostructureNanoscopic scaleNanotechnologyNanolithographyRaman spectroscopySurface-enhanced Raman spectroscopyThin filmMetalFabricationRaman scatteringOpticsMedicineAlternative medicinePhysicsPathologyMetallurgyNanomaterials and Printing TechnologiesGold and Silver Nanoparticles Synthesis and ApplicationsZnO doping and properties
Shape-Controlled and Well-Arrayed Heterogeneous Nanostructures via Melting Point Modulation at the Nanoscale | Litcius