::::: μNOEL - 서울대학교 자연과학대학 물리천문학부 ::::: > Publication > High-contrast infrared absorption spectroscopy via mass-produced coaxial zero-mode resonators with sub-10 nm gaps

::::: μNOEL - 서울대학교 자연과학대학 물리천문학부 :::::

Untitled Document

HOME > Publications > Publications

Name : 한창현

2018-02-23 13:39:08

Title : High-contrast infrared absorption spectroscopy via mass-produced coaxial zero-mode resonators with sub-10 nm gaps

: Daehan Yoo, Daniel A. Mohr, Ferran Vidal-Codina, Aurelian John-Herpin, Minsik Jo, Sunghwan Kim, Joseph Matson, Joshua D. Caldwell, Heonsu Jeon, Ngoc-Cuong Nguyen, Luis Martin-Moreno, Jaime Peraire, Hatice Altug and Sang-Hyun Oh

: Nano Lett. 18(3) 1930–1936 (2018)

We present a wafer-scale array of resonant coaxial nanoapertures as a practical
platform for surface-enhanced infrared absorption spectroscopy (SEIRA).
Coaxial nanoapertures with sub-10 nm gaps are fabricated via photolithography,
atomic layer deposition of a sacrificial Al2O3 layer to define the nanogaps, and
planarization via glancing-angle ion milling. At the zeroth-order Fabry-Perot
resonance condition, our coaxial apertures act as a ”zero-mode resonator (ZMR)”,
efficiently funneling as much as 34% of incident infrared (IR) light along
10 nm annular gaps. After removing Al2O3 in the gaps and inserting silk protein, we can
couple the intense optical fields of the annular nanogap into the vibrational
modes of protein molecules. From 7 nm gap ZMR devices coated with a 5 nm
thick silk protein film, we observe high contrast IR absorbance signals drastically
suppressing 58% of the transmitted light and infer a strong IR absorption enhancement
factor of 104∼105. These single nanometer gap ZMR devices can be mass-produced
via batch processing and offer promising routes for broad applications of SEIRA

Untitled Document

Untitled Document