论文信息 - Experimental investigation of curved electrode actuator dynamics in viscous dielectric media

Experimental investigation of curved electrode actuator dynamics in viscous dielectric media

Micromanipulation of biological cells inside a liquid environment requires an actuator that has a small footprint to reduce viscous drag and low actuation voltage to prevent electrolysis and Joule heating. Curved electrode actuators hold promise for underwater micromanipulation because they yield large displacements at low actuation voltages for a small footprint. In this letter, we report on the frequency-domain characteristics of the actuator and demonstrate that the actuator can achieve large displacements (1–10 μm) and generate large forces (1–21 μN) at low actuation voltages (8 V) over the 1–1000 Hz frequency range in a viscous dielectric media.Micromanipulation of biological cells inside a liquid environment requires an actuator that has a small footprint to reduce viscous drag and low actuation voltage to prevent electrolysis and Joule heating. Curved electrode actuators hold promise for underwater micromanipulation because they yield large displacements at low actuation voltages for a small footprint. In this letter, we report on the frequency-domain characteristics of the actuator and demonstrate that the actuator can achieve large displacements (1–10 μm) and generate large forces (1–21 μN) at low actuation voltages (8 V) over the 1–1000 Hz frequency range in a viscous dielectric media.

David J. Hoelzle | Sindhu Preetham Burugupally

[1] J. Fluitman,et al. Electrostatic curved electrode actuators , 1995 .

[2] L. Meirovitch,et al. Fundamentals of Vibrations , 2000 .

[3] Clara K. Chan,et al. A large displacement, high frequency, underwater microelectromechanical systems actuator , 2015 .

[4] T. Kenny,et al. What is the Young's Modulus of Silicon? , 2010, Journal of Microelectromechanical Systems.

[5] B.L. Pruitt,et al. MEMS Electrostatic Actuation in Conducting Biological Media , 2009, Journal of Microelectromechanical Systems.

[6] Sindhu Preetham Burugupally,et al. Performance evaluation of a curved electrode actuator fabricated without gold/chromium conductive layers , 2018 .

[7] S. Warnat,et al. PolyMUMPs MEMS device to measure mechanical stiffness of single cells in aqueous media , 2015 .

[8] M. Brenner,et al. Deep-reactive ion-etched compliant starting zone electrostatic zipping actuators , 2005, Journal of Microelectromechanical Systems.

[9] David J. Hoelzle,et al. A curved electrode electrostatic actuator designed for large displacement and force in an underwater environment , 2017 .

[10] S. Senturia,et al. M-TEST: A test chip for MEMS material property measurement using electrostatically actuated test structures , 1997 .

[11] T. Michalske,et al. Frequency-dependent electrostatic actuation in microfluidic MEMS , 2003, Journal of Microelectromechanical Systems.