This work reports the actuation of droplets of nanofluid by the electrowetting on dielectric (EWOD) effect. The nanofluid is comprised of an aqueous (deionized water) suspension of 3 nm diameter bismuth telluride nanoparticles capped with thioglycolic acid (TGA). Microdroplets of nanofluid are cast on Si(001) wafers coated with 100 nm thick layers of silicon dioxide and AF Teflon. Applying an electric field between the substrate and an electrode immersed in the nanofluid droplet results in a strong change in the contact angle from 110 deg to 84 deg for a 0-60 V voltage range. The droplets of nanofluid exhibit enhanced stability and absence of contact angle saturation in the tested voltage range when compared with droplets of aqueous solutions of 0.01 M Na_2SO_4 or thioglycolic acid in deionized water. We propose that ion generation due to capping-agent desorption is a key factor determining the EWOD effect in the bismuth telluride nanofluid along with the nanoparticle contribution to charge transport. Our results open up new vistas for using nanofluids for microscale actuator device applications.
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机译:这项工作报告了电介质上电润湿(EWOD)效应对纳米流体液滴的驱动作用。纳米流体由直径为3 nm的碲化铋纳米颗粒的水性(去离子水)悬浮液组成,并用巯基乙酸(TGA)封端。将纳米流体的微滴浇铸在涂有100 nm厚的二氧化硅和AF Teflon层的Si(001)晶圆上。在0-60 V电压范围内,在基板和浸入纳米流体液滴中的电极之间施加电场会导致接触角从110度到84度的强烈变化。与在去离子水中的0.01 M Na_2SO_4或巯基乙酸的水溶液液滴相比,在测试电压范围内,纳米流体液滴表现出增强的稳定性,并且没有接触角饱和。我们建议由于封端剂解吸而产生的离子是决定碲化铋纳米流体中EWOD效应以及纳米粒子对电荷传输的贡献的关键因素。我们的结果为将纳米流体用于微型执行器设备应用开辟了新的前景。
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