Template fabricated plasmonic nanoholes on analyte-sensitive substrates for real-time vapor sensing

Authors

Nathan C. Lindquist, Bethel University
Mark A. Turner, Bethel University
Benjamin P. Heppner, Bethel University

Document Type

Article

Abstract

Sensing with nanostructured plasmonic devices has become an important research field due to their proven ability to be extremely sensitive, compact, multiplexed, and compatible with low-cost fabrication techniques. In this paper, we employ a modified template stripping method to produce plasmonic nanohole arrays on analyte-sensitive substrates for real-time vapor sensing. The device operates by exploiting simultaneous plasmonic resonances within the substrate as well as within the vapor being tested. Because the substrate is in contact with vapor due to the open-hole geometry, red-shifts (air-side resonances) and blue-shifts (substrate-side resonances) are seen at the same time during exposure to m-xylene, as well as multiplex sensing potential with chemically patterned substrates. Our devices could operate as low-cost gas sensors for environmental monitoring, security, or food safety. © the Partner Organisations 2014.

Department(s)

Physics and Engineering

Publication Title

RSC Advances

Volume

4

Issue

29

First Page

15115

Last Page

15121

Publication Date

1-1-2014

DOI

10.1039/c4ra01797h

E-ISSN

20462069

Recommended Citation

Lindquist, Nathan C.; Turner, Mark A.; and Heppner, Benjamin P., "Template fabricated plasmonic nanoholes on analyte-sensitive substrates for real-time vapor sensing" (2014). Physics and Engineering Faculty Publications. 32.
https://spark.bethel.edu/physics-faculty/32