• Bantz, Kyle C.
• Lee, Si Hoon
• Lindquist, Nathan C.
• Oh, Sang Hyun

Abstract

<p>We present a simple and massively parallel nanofabrication technique to produce self-assembled periodic nanohole arrays over a millimeter-sized area of metallic film, with a tunable hole shape, diameter, and periodicity. Using this method, 30 × 30 μm ² defect-free areas of 300 nm diameter or smaller holes were obtained in silver; this area threshold is critical because it is larger than the visible wavelength propagation length of surface plasmon waves (∼27 μm) in the silver film. Measured optical transmission spectra show highly homogeneous characteristics across the millimeter-size patterned area, and they are in good agreement with FDTD simulations. The simulations also reveal intense electric fields concentrated near the air/silver interface, which was used for surface-enhanced Raman spectroscopy (SERS). Enhancement factors (EFs) measured with different hole shape and excitation wavelengths on the self-assembled nanohole arrays were 10 ⁴-10 ⁶.With an additionalAg electroless plating step, theEFwas further increased up to 3×10 ⁶.The periodic nanohole arrays produced using this tunable self-assembly method show great promise as inexpensive SERS substrates as well as surface plasmon resonance biosensing platforms.</p>

Topics

• impedance spectroscopy
• surface
• silver
• simulation
• defect
• Raman spectroscopy
• self-assembly