A passive microfluidic mixer with high performance is designed and fabricated in this work. Diamond-shaped obstacles
were chosen to split the flow into several streams, which are then guided back together after the obstacle. To keep
pressure drop low, the channel cross-sectional area was maintained equal to the input cross-sectional area, and this was
held constant throughout the device. The proposed design was modeled using computational fluid dynamics (CFD)
software. The effects of channel width, channel length, location of obstructions, and Reynolds Number (Re) were
investigated. The simulated results were verified experimentally. Simulation data showed that the designed micromixer
achieved 90% mixing at a channel length of 4.35 mm with pressure drop of 584 Pa at Re = 1, while experimental data for
Re = 0.1 showed 90% mixing at 7 mm. The mixer functions well especially at the low Re (Re = 0.1).
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