Nicolas M.-Catafard scite author profile

Nicolas M.-Catafard

2Publications

32Citation Statements Received

111Citation Statements Given

How they've been cited

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108

Affiliations

University of Ottawa

Publications

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Field-Flow Fractionation and Hydrodynamic Chromatography on a Microfluidic Chip

et al. 2013

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We present gravitational field-flow fractionation and hydrodynamic chromatography of colloids eluting through 18 μm microchannels. Using video microscopy and mesoscopic simulations, we investigate the average retention ratio of colloids with both a large specific weight and neutral buoyancy. We consider the entire range of colloid sizes, including particles that barely fit in the microchannel and nanoscopic particles. Ideal theory predicts four operational modes, from hydrodynamic chromatography to Faxén-mode field-flow fractionation. We experimentally demonstrate, for the first time, the existence of the Faxén-mode field-flow fractionation and the transition from hydrodynamic chromatography to normal-mode field-flow fractionation. Furthermore, video microscopy and simulations show that the retention ratios are largely reduced above the steric-inversion point, causing the variation of the retention ratio in the steric- and Faxén-mode regimes to be suppressed due to increased drag. We demonstrate that theory can accurately predict retention ratios if hydrodynamic interactions with the microchannel walls (wall drag) are added to the ideal theory. Rather than limiting the applicability, these effects allow the microfluidic channel size to be tuned to ensure high selectivity. Our findings indicate that particle velocimetry methods must account for the wall-induced lag when determining flow rates in highly confining systems.

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Using the fringing electric field in microfluidic volume sensors to enhance sensitivity and accuracy

Riordon¹,

M.-Catafard²,

Godin³

2012

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The particle trajectory above impedance-monitoring coplanar electrodes in a microfluidic channel dramatically influences the measured electric current change. We use finite element modeling to predict changes in ionic current for microspheres flowing in highly fringing fields, and validate these results by introducing a buoyancy-based particle focusing technique. Using 6 μm polystyrene particles in solutions of varying density, we control the height of the particle trajectories near the sensing electrodes and show that sensitivity can be increased by up to 3.5× when particles flow close to the electrodes compared to particles flowing further away, while simultaneously improving accuracy.

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