The introduction of flows within sessile droplets is highly effective for many lab-on-a-chip chemical and biomedical applications.However,generating such flows is difficult due to the typically small droplet volumes.H...The introduction of flows within sessile droplets is highly effective for many lab-on-a-chip chemical and biomedical applications.However,generating such flows is difficult due to the typically small droplet volumes.Here,we present a simple,non-contact strategy to generate internal flows in sessile droplets for enhancing mixing and mass transport.The flows are driven by actuating a rigid substrate into oscillation with certain amplitude distributions without relying on the resonance of the droplet itself.Substrate oscillation characteristics and corresponding flow patterns are documented herein.Mixing indices and mass transfer coefficients of sessile droplets on the substrate surface are measured using optical and electrochemical methods.They demonstrate complete mixing within the droplets in 1.35 s and increases in mass transfer rates of more than seven times static values.Proof of concept was conducted with experiments of silver nanoparticle synthesis and with heavy metal ion sensing employing the sessile droplet as a microreactor for synthesis and an electrochemical cell for sensing.The degrees of enhancement of synthesis efficiency and detection sensitivity attributed to the internal flows are experimentally documented.展开更多
基金supported by the National Science Foundation through the National Nano Coordinated Infrastructure Network(NNCI)under Award Number ECCS-2025124.
文摘The introduction of flows within sessile droplets is highly effective for many lab-on-a-chip chemical and biomedical applications.However,generating such flows is difficult due to the typically small droplet volumes.Here,we present a simple,non-contact strategy to generate internal flows in sessile droplets for enhancing mixing and mass transport.The flows are driven by actuating a rigid substrate into oscillation with certain amplitude distributions without relying on the resonance of the droplet itself.Substrate oscillation characteristics and corresponding flow patterns are documented herein.Mixing indices and mass transfer coefficients of sessile droplets on the substrate surface are measured using optical and electrochemical methods.They demonstrate complete mixing within the droplets in 1.35 s and increases in mass transfer rates of more than seven times static values.Proof of concept was conducted with experiments of silver nanoparticle synthesis and with heavy metal ion sensing employing the sessile droplet as a microreactor for synthesis and an electrochemical cell for sensing.The degrees of enhancement of synthesis efficiency and detection sensitivity attributed to the internal flows are experimentally documented.