Acoustically-actuated bubble-powered rotational micro-propellers

•Gear-inspired contactless micro-propellers powered by vibrating bubbles are presented•The propellers consist of symmetric distribution of bubbles that enable fast rotation.•Combined magneto-acoustic fields are used to steer the propellers to specific targets.•The propellers can function like a micr...

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Veröffentlicht in:	Sensors and actuators. B, Chemical Chemical, 2021-11, Vol.347, p.130589, Article 130589
Hauptverfasser:	Mohanty, Sumit, Zhang, Jiena, McNeill, Jeffrey M., Kuenen, Thom, Linde, Frederic P., Rouwkema, Jeroen, Misra, Sarthak
Format:	Artikel
Sprache:	eng
Schlagworte:	Acoustic streaming Acoustics Acoustofluidics Actuation Air bubbles Bubble-powered motors Direct laser writing Microfluidics Micromixing Microrobotics Microrobots Minimally-invasive surgeries Mixers Propellers Self-propulsion Sound waves Substrates Ultrasound
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container_title	Sensors and actuators. B, Chemical
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creator	Mohanty, Sumit Zhang, Jiena McNeill, Jeffrey M. Kuenen, Thom Linde, Frederic P. Rouwkema, Jeroen Misra, Sarthak
description	•Gear-inspired contactless micro-propellers powered by vibrating bubbles are presented•The propellers consist of symmetric distribution of bubbles that enable fast rotation.•Combined magneto-acoustic fields are used to steer the propellers to specific targets.•The propellers can function like a micro-mixer without any tethered contact to a substrate. Bubble-powered acoustic microsystems span a plethora of applications that range from lab-on-chip diagnostic platforms to targeted interventions as microrobots. Numerous studies strategize this bubble-powered mechanism to generate autonomous self-propulsion of microrobots in response to high frequency sound waves. Herein, we present two micro-propeller designs which contain an axis-symmetric distribution of entrapped bubbles that vibrate to induce fast rotational motion. Our micro-propellers are synthesized using 3D Direct Laser Writing and chemically-functionalized to selectively trap air bubbles at their micro-cavities which function as propulsion units. These rotational acoustic micro-propellers offer a dual advantage of being used as mobile microfluidic mixers, and as autonomous microrobots for targeted manipulation. With regards to targeted manipulation, we demonstrate magneto-acoustic actuation of our first propeller design that can be steered to a desired location to perform rotational motion. Furthermore, our second propeller design comprises of a helical arrangement of bubble-filled cavities which makes it suitable for spatial micro-mixing. Our acoustic propellers can reach speeds of up to 400 RPM (rotations per minute) without requiring any direct contact with a vibrating substrate in contrast to the state-of-the-art rotary acoustic microsystems.
doi_str_mv	10.1016/j.snb.2021.130589
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Bubble-powered acoustic microsystems span a plethora of applications that range from lab-on-chip diagnostic platforms to targeted interventions as microrobots. Numerous studies strategize this bubble-powered mechanism to generate autonomous self-propulsion of microrobots in response to high frequency sound waves. Herein, we present two micro-propeller designs which contain an axis-symmetric distribution of entrapped bubbles that vibrate to induce fast rotational motion. Our micro-propellers are synthesized using 3D Direct Laser Writing and chemically-functionalized to selectively trap air bubbles at their micro-cavities which function as propulsion units. These rotational acoustic micro-propellers offer a dual advantage of being used as mobile microfluidic mixers, and as autonomous microrobots for targeted manipulation. 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B, Chemical</title><description>•Gear-inspired contactless micro-propellers powered by vibrating bubbles are presented•The propellers consist of symmetric distribution of bubbles that enable fast rotation.•Combined magneto-acoustic fields are used to steer the propellers to specific targets.•The propellers can function like a micro-mixer without any tethered contact to a substrate. Bubble-powered acoustic microsystems span a plethora of applications that range from lab-on-chip diagnostic platforms to targeted interventions as microrobots. Numerous studies strategize this bubble-powered mechanism to generate autonomous self-propulsion of microrobots in response to high frequency sound waves. Herein, we present two micro-propeller designs which contain an axis-symmetric distribution of entrapped bubbles that vibrate to induce fast rotational motion. 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B, Chemical</jtitle><date>2021-11-15</date><risdate>2021</risdate><volume>347</volume><spage>130589</spage><pages>130589-</pages><artnum>130589</artnum><issn>0925-4005</issn><eissn>1873-3077</eissn><abstract>•Gear-inspired contactless micro-propellers powered by vibrating bubbles are presented•The propellers consist of symmetric distribution of bubbles that enable fast rotation.•Combined magneto-acoustic fields are used to steer the propellers to specific targets.•The propellers can function like a micro-mixer without any tethered contact to a substrate. Bubble-powered acoustic microsystems span a plethora of applications that range from lab-on-chip diagnostic platforms to targeted interventions as microrobots. Numerous studies strategize this bubble-powered mechanism to generate autonomous self-propulsion of microrobots in response to high frequency sound waves. Herein, we present two micro-propeller designs which contain an axis-symmetric distribution of entrapped bubbles that vibrate to induce fast rotational motion. Our micro-propellers are synthesized using 3D Direct Laser Writing and chemically-functionalized to selectively trap air bubbles at their micro-cavities which function as propulsion units. These rotational acoustic micro-propellers offer a dual advantage of being used as mobile microfluidic mixers, and as autonomous microrobots for targeted manipulation. With regards to targeted manipulation, we demonstrate magneto-acoustic actuation of our first propeller design that can be steered to a desired location to perform rotational motion. Furthermore, our second propeller design comprises of a helical arrangement of bubble-filled cavities which makes it suitable for spatial micro-mixing. 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subjects	Acoustic streaming Acoustics Acoustofluidics Actuation Air bubbles Bubble-powered motors Direct laser writing Microfluidics Micromixing Microrobotics Microrobots Minimally-invasive surgeries Mixers Propellers Self-propulsion Sound waves Substrates Ultrasound
title	Acoustically-actuated bubble-powered rotational micro-propellers
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