Quantitative assessment of parallel acoustofluidic device

The advantage of ultrasonic fields in harmless and label-free applications intrigued researchers to develop this technology. capability acoustofluidic technology for medical has not been thoroughly analyzed visualized. Toward efficient design, research, flowing fluid a microchannel excited by acoustic waves is fully investigated. To study the behavior streaming, main interfering parameters such as inlet velocity, working frequency, displacement amplitude, buffer material, hybrid effect rectangular water-filled actuated standing surface are studied. Governing equations field laminar flow derived employing perturbation theory. For each set equations, appropriate boundary conditions applied. Results demonstrate parallel device capable increasing rapid operations. Frequency increment raises streaming velocity magnitude. Displacement amplitude amplification increases helps dominate over incoming flow. qualitative analysis shows using hard walls can significantly increase power without depleting excessive energy. A combination several effective provides an energy-efficient controllable biomedical mixing cell lysis.