[Optics Letter] Optofluidic biomolecule sensors based on a-Si:H microrings embedded in silicon–glass
The large-scale and low-cost fabrication of high sensitivity sensors for the real-time detection of biochemicals and molecular substances opens up new opportunities in the areas of bioanalytic screening and medical diagnostics. Planar integrated photonic resonators that can be fabricated with a low footprint, in spatial and wavelength multiplexed arrangements, and that enable integration with microfluidics on the wafer scale have emerged as a promising sensing platform for these application fields. We realized an optofluidic and label-free biosensor that is based on hydrogenated amorphous silicon microring resonators embedded in silicon/glass microfluidic channels for analyte injection and biomolecule immobilization. The optofluidic sensor merits for refractive index and biomolecule sensing are evaluated by sensitivity and detection limit simulations, whereas a proof of concept is demonstrated by real-time protein immobilization experiments of functionalized resonators.
T. Lipka,* L. Moldenhauer, L. Wahn, and H. K. Trieu
Institute of Microsystems Technology, Hamburg University of Technology, Eissendorferstr. 42, Hamburg, Germany
*Corresponding author: firstname.lastname@example.org
Optics Letters Vol. 42, Issue 6, pp. 1084-1087 (2017) •https://doi.org/10.1364/OL.42.001084