Abstract
We present a novel integration method for packaging silicon photonic sensors with polymer microfluidics, designed to be suitable for wafer-level production methods. The method addresses the previously unmet manufacturing challenges of matching the microfluidic footprint area to that of the photonics, and of robust bonding of microfluidic layers to biofunctionalized surfaces. We demonstrate the fabrication, in a single step, of a microfluidic layer in the recently introduced OSTE polymer, and the subsequent unassisted dry bonding of the microfluidic layer to a grating coupled silicon photonic ring resonator sensor chip. The microfluidic layer features photopatterned through holes (vias) for optical fiber probing and fluid connections, as well as molded microchannels and tube connectors, and is manufactured and subsequently bonded to a silicon sensor chip in less than 10 minutes. Combining this new microfluidic packaging method with photonic waveguide surface gratings for light coupling allows matching the size scale of microfluidics to that of current silicon photonic biosensors. To demonstrate the new method, we performed successful refractive index measurements of liquid ethanol and methanol samples, using the fabricated device. The minimum required sample volume for refractive index measurement is below one nanoliter.
Highlights
The combination of a biological recognition element with a physical transducer makes biosensing a powerful tool for biological and medical analysis
We present a one-step integration of microfluidics onto silicon photonic sensors able to match the size scale of the liquid handling system with that of the silicon photonics, by using a self-bonding offstoichiometry thiol-ene (OSTE) polymer microfluidic layer that is structured using a combined photolithography and micromolding process
We have presented a novel one-step microfluidic integration technique for silicon photonic waveguide based sensors with surface grating couplers
Summary
The combination of a biological recognition element with a physical transducer makes biosensing a powerful tool for biological and medical analysis. Molded polydimethylsiloxane (PDMS) constitutes the current academic solution for silicon photonic biosensor microfluidics [10], but drawbacks such as large wafer area consumption, long curing times, adsorption of small biomolecules into the PDMS, and lack of bonding techniques compatible with surface biofunctionalization, make industrial application questionable [10] These limitations are apparent in [11], in which stamping with an epoxy glue for bonding results in channel clogging. PDMS based soft-lithography molding of vias (through holes) is hampered by squeeze-film formation, necessitating a second low resolution via fabrication step by hole punching [12] To address these limitations, the Off-Stoichiometry Thiol-Ene (OSTE) polymer was introduced [13] and microfluidic integration on silicon at wafer level demonstrated [14]. These tube connectors can be substituted by compact manifold connectors, if needed, for a higher integration density at wafer level. 3) We dry bond the microfluidic layer to patterned silicon surfaces by click chemistry
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