Alhareeb, NadeemNadeemAlhareebVermeer, MatthiasMatthiasVermeerRennpferdt, LukasLukasRennpferdtTrieu, Hoc KhiemHoc KhiemTrieuLipka, TimoTimoLipka2024-06-052024-06-052022-119th GMM-Workshops on Mikro-Nano-Integration (2022)[9783800759910]https://hdl.handle.net/11420/47744Optical resonators based on integrated silicon photonic technology are promising sensor components for lab-on-chip applications. We present a novel optofluidic biochemical sensor platform manufactured solely on quartz glass substrates. The manufacturing is described, and initial experimental results are demonstrated. The final sensor chip consists of two parts: the microfluidic channel and the photonic chip, which are bonded together after their respective production. The photonic components are manufactured with hydrogenated amorphous silicon (a-Si:H) which was deposited by plasma-enhanced chemical vapor deposition (PECVD) serving as the waveguide core for the micro-ring sensors. In combination with the glass substrate this results in a high index contrast photonic platform with high integration density. In a second step selective laser-induced etching (SLE) is applied to produce the microfluidic channels in another glass substrate. A 10 µm radius ring resonator is used as a sensing configuration. The quality factor of the ring is about before applying any fluids, i.e. with air cladding. To characterize the sensor performance, various 0% to 8% concentrations of Isopropyl alcohol (IPA) diluted with deionized (DI) water (H2O) were used as test analytes. The linear regression of the resonance peak shift due to different IPA concentrations indicates a sensitivity of S = 103 pm/%.enConference PaperConference Paper