Biosensing using porous silicon photonic bandgap structures

Abstract: Photonic bandgap (PBG) structures have remarkable optical properties that can be exploited for biosensing applications. We describe the fabrication of 1-D PBG biosensors using porous silicon. The optical properties of porous silicon PBGs are sensitive to small changes of refractive index in the porous layers, which makes them a good sensing platform capable of detecting binding of the target molecules to the bioreceptors. The material nanostructure and device configuration that lead to optimum performance of t… Show more

“…In this sense the quality (Q) factor (defined as / ) provides an indication of the degree to which the light at the resonance frequency is confined into the cavity. For sensing applications where the shift of the resonance peak is monitored, high Q factor values increase the ability to resolve small wavelength shifts [21]. The obtained Q factors of the as etched PSiMc (solid lines in Fig.…”

Functionalization of nanostructured porous silicon microcavities for glucose oxidase detection

“…In this sense the quality (Q) factor (defined as / ) provides an indication of the degree to which the light at the resonance frequency is confined into the cavity. For sensing applications where the shift of the resonance peak is monitored, high Q factor values increase the ability to resolve small wavelength shifts [21]. The obtained Q factors of the as etched PSiMc (solid lines in Fig.…”

Functionalization of nanostructured porous silicon microcavities for glucose oxidase detection

“…The Q value, i.e. the amount of energy stored within the microcavity (Jenie et al, 2014;Ouyang and Fauchet, 2005), was 27 and 20 for MC-1 and MC-2, respectively. Pore sizes were in the range of 39-48 nm for the L layer and 65-100 nm for the H layer.…”

Development of l-lactate dehydrogenase biosensor based on porous silicon resonant microcavities as fluorescence enhancers

“…Macroporous n-type PSi may accommodate larger molecules, whose size depends on the pores' diameter. It can be prepared with pores in the 100 nm -few µm range, depending on the formation condition (Gruning and Lehmann 1996;Ouyang and Fauchet 2005). The pores' diameter can be further modified after formation by means of one or more of the several available techniques able to enlarge the pores' diameter to better adapt to the size of the molecule of interest.…”

Porous Silicon-based Electrochemical Biosensors