Flow focusing with miscible fluids in microfluidic devices

The interfacial instability between miscible fluids in a channel is determined by many factors, such as viscosity contrast and the inclination angle. Considering the effect of the gravity field, we investigate the displacement phenomenon between two miscible fluids with different viscosities in an inclined channel. The results show that when the concentration Rayleigh number RaC {less than or equal to} 105, the inclination angle θ ranges from 0{degree sign} to 90º, and the natural logarithm of the viscosity ratio R>0, there are three fluid-fluid interfacial instability regions, namely viscous fingering, "Kelvin-Helmholtz" (K-H) instability and "Rayleigh-Taylor" (R-T) instability. A scaling analysis is developed to describe the time evolution of the displacement as described by the displacement efficiency at a fixed viscous ratio. Our analysis indicates that in the viscous fingering region, the time evolution of the displacement efficiency gradually increases with t scaling due to fingering formations; in the the K-H and R-T region, the displacement efficiency rapidly increases with t1+RaC/10^6. When considering the effect of the viscosity ratio in the K-H instability region, the displacement efficiency scales as η∼ t1+RaC/10^6 R0.1. In addition, when the inclination angle is negative or R < 0, the instability phenomenon is not obvious, and the displacement efficiency decreases as the inclination angle or R decreases.

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Deep reinforcement learning-based digital twin for droplet microfluidics control

Gyimah,

Scheler,

Rang

et al. 2023

Physics of Fluids

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This study applied deep reinforcement learning (DRL) with the Proximal Policy Optimization (PPO) algorithm within a two-dimensional computational fluid dynamics (CFD) model to achieve closed-loop control in microfluidics. The objective was to achieve the desired droplet size with minimal variability in a microfluidic capillary flow-focusing device. An artificial neural network was utilized to map sensing signals (flow pressure and droplet size) to control actions (continuous phase inlet pressure). To validate the numerical model, simulation results were compared with experimental data, which demonstrated a good agreement with errors below 11%. The PPO algorithm effectively controlled droplet size across various targets (50, 60, 70, and 80 μm) with different levels of precision. The optimized DRL + CFD framework successfully achieved droplet size control within a coefficient of variation (CV%) below 5% for all targets, outperforming the case without control. Furthermore, the adaptability of the PPO agent to external disturbances was extensively evaluated. By subjecting the system to sinusoidal mechanical vibrations with frequencies ranging from 10 Hz to 10 KHz and amplitudes between 50 and 500 Pa, the PPO algorithm demonstrated efficacy in handling disturbances within limits, highlighting its robustness. Overall, this study showcased the implementation of the DRL+CFD framework for designing and investigating novel control algorithms, advancing the field of droplet microfluidics control research.

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Flow focusing with miscible fluids in microfluidic devices

Cited by 7 publications

References 37 publications

Soft-template regulation of magnetic microsphere topology from a microfluidic device

Soft-template regulation of magnetic microsphere topology from a microfluidic device

Numerical simulations of miscible displacement in an inclined channel by lattice Boltzmann method

Deep reinforcement learning-based digital twin for droplet microfluidics control

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