par Raza, Ali;Clemmen, Stéphane 
;Wuytens, Pieter C.;De Goede, Michiel;Tong, Amy;Le Thomas, Nicolas;Liu, Chengyu;Suntivich, Jin;Skirtach, Andre;Garcia-Blanco, Sonia;Blumenthal, Daniel;Wilkinson, James;Baets, Roel
Référence Optics express, 27, 16, page (23067-23079)
Publication Publié, 2019-08-01
;Wuytens, Pieter C.;De Goede, Michiel;Tong, Amy;Le Thomas, Nicolas;Liu, Chengyu;Suntivich, Jin;Skirtach, Andre;Garcia-Blanco, Sonia;Blumenthal, Daniel;Wilkinson, James;Baets, RoelRéférence Optics express, 27, 16, page (23067-23079)
Publication Publié, 2019-08-01
Article révisé par les pairs
| Résumé : | Nanophotonic waveguide enhanced Raman spectroscopy (NWERS) is a sensing technique that uses a highly confined waveguide mode to excite and collect the Raman scattered signal from molecules in close vicinity of the waveguide. The most important parameters defining the figure of merit of an NWERS sensor include its ability to collect the Raman signal from an analyte, i.e. AND#x201C;the Raman conversion efficiencyAND#x201D; and the amount of AND#x201C;Raman backgroundAND#x201D; generated from the guiding material. Here, we compare different photonic integrated circuit (PIC) platforms capable of on-chip Raman sensing in terms of the aforementioned parameters. Among the four photonic platforms under study, tantalum oxide and silicon nitride waveguides exhibit high signal collection efficiency and low Raman background. In contrast, the performance of titania and alumina waveguides suffers from a strong Raman background and a weak signal collection efficiency, respectively. |
