Authors:	A. Dhakal, P.C. Wuytens, A. Raza, N. Le Thomas, R. Baets
Title:	Silicon Nitride Background in Nanophotonic Waveguide Enhanced Raman Spectroscopy
Format:	International Journal
Publication date:	2/2017
Journal/Conference/Book:	Materials
Editor/Publisher:	MDPI,
Volume(Issue):	10(140)
DOI:	10.3390/ma10020140
Citations:	40 (Dimensions.ai - last update: 24/11/2024) 32 (OpenCitations - last update: 27/6/2024) Look up on Google Scholar
Download:	(1.6MB)

Abstract

Recent studies have shown that evanescent Raman spectroscopy using a silicon nitride (SiN)
nanophotonic waveguide platform has higher signal enhancement when compared to free-space
systems. However, signal-to-noise ratio from the waveguide at a low analyte concentration is
constrained by the shot-noise from the background light originating from the waveguide itself.
Hence, understanding the origin and properties of this waveguide background luminescence (WGBL)
is essential to developing mitigation strategies. Here, we identify the dominating component of
the WGBL spectrum composed of a broad Raman scattering due to momentum selection-rule
breaking in amorphous materials, and several peaks specific to molecules embedded in the core.
We determine the maximum of the Raman scattering efficiency of the WGBL at room temperature
for 785 nm excitation to be 4.5  1  10..9 cm..1
sr..1, at a Stokes shift of 200 cm..1. This efficiency
decreases monotonically for higher Stokes shifts. Additionally, we also demonstrate the use of slotted
waveguides and quasi-transverse magnetic polarization as some mitigation strategies.

Related Research Topics

• Raman spectroscopy on a siliconnitride waveguide platform
• Siliconnitride photonic integrated circuit platform

Related Projects

• ERC-AdG: InSpectra (Silicon-photonics-based laser spectroscopy platform: towards a paradigm shift in environmental monitoring and health care)