Surface Tension & Wetting

Bubble Entrapment in Microchannels

Bubbles trapped in microchannels can distort the fluid flow and impact the device performance. Veryst developed a multiphase CFD model to predict the effect of geometry and surface properties on the likelihood of bubble entrapment.

Fluid Flow Through Porous Media

Quantifying the rate of fluid flow through a porous matrix is important in many applications, including diagnostic devices, inkjet printing, textile fabrication, soil and groundwater remediation, and energy storage. In this project, Veryst used computational fluid dynamics to predict the transient rate of capillary imbibition through paper-based devices of varying geometry to help the client achieve the desired flow rate time profile for their fluidic device.

Reagent Dry-Down in a Microwell

Manufacturing medical diagnostic kits involves drying reagents to be reconstituted later, during use. For this project, Veryst simulated reagent dry-down of a small volume of liquid in a microwell to investigate the effect of process parameters including oven temperature and humidity.

Computational Fluid Dynamics (CFD)

Veryst offers state-of-the-art consulting in the design and analysis of gaseous and fluid systems and products. We employ advanced CFD analysis to solve problems involving fluid mixing, multiphase flow, phase change, non-Newtonian fluids, and microfluidic effects.

Fluidic Mixing

Veryst has deep expertise in fluidic mixing processes, which we leverage for our clients across industries.  A fundamental aspect of mixing is the stretching and folding of the interface between initially separated substances.  This occurs in many forms a

Microfluidics

Veryst offers a comprehensive approach to solving problems in microfluidic device development.  We employ an array of modeling tools, such as scaling arguments, analytical formulas, computational simulations, and laboratory testing to inform the design and integration of common components.