Autonomous Movement of Silica and Glass Micro‐Objects Based on a Catalytic Molecular Propulsion System

Stöck, Christoph; Heureux, Nicolas; Browne, Wesley R.; Feringa, Ben L.

doi:10.1002/chem.200701227

Cited by 26 publications

(18 citation statements)

References 99 publications

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“…It is only in the past decade that researchers have managed to design self-powered synthetic nano-and micromachines (1,2) that convert chemical energy into mechanical motion. The initial discoveries have sparked tremendous interest in this emerging field , and a wide repertoire of synthetic machines that can be powered by chemical fuels (5,12,18,(38)(39)(40)(41)(42)(43)(44)(45)(46)(47) or externally applied fields that deliver magnetic (48)(49)(50)(51)(52)(53)(54)(55)(56), electrical (14,57), light (58)(59)(60)(61), acoustic (62)(63)(64), or thermal (65)(66)(67) energy have been designed.…”

Section: Introductionmentioning

confidence: 99%

Synthetic Nano- and Micromachines in Analytical Chemistry: Sensing, Migration, Capture, Delivery, and Separation

Duan

Wang

Das

et al. 2015

Annual Rev. Anal. Chem.

151

108

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Synthetic nano- and microscale machines move autonomously in solution or drive fluid flows by converting sources of energy into mechanical work. Their sizes are comparable to analytes (sub-nano- to microscale), and they respond to signals from each other and their surroundings, leading to emergent collective behavior. These machines can potentially enable hitherto difficult analytical applications. In this article, we review the development of different classes of synthetic nano- and micromotors and pumps and indicate their possible applications in real-time in situ chemical sensing, on-demand directional transport, cargo capture and delivery, as well as analyte isolation and separation.

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Section: Introductionmentioning

confidence: 99%

Synthetic Nano- and Micromachines in Analytical Chemistry: Sensing, Migration, Capture, Delivery, and Separation

Duan

Wang

Das

et al. 2015

Annual Rev. Anal. Chem.

151

108

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“…Thus far, environmental cues such as chemical gradients and chemical reactions, magnetic, electric, light, sound, and temperature gradients have been successfully used to power synthetic nano‐ and microswimmers. However, very few of them meet the requirements of the ideal energy source for powering nano‐/microscale machines, especially for biomedical applications which are most heatedly anticipated for these devices.…”

Section: Introductionmentioning

confidence: 99%

A Force to Be Reckoned With: A Review of Synthetic Microswimmers Powered by Ultrasound

Rao

Meng

et al. 2015

Small

217

196

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Synthetic microswimmers are a class of artificial nano- or microscale particle capable of converting external energy into motion. They are similar to natural microswimmers such as bacteria in behavior and are, therefore, of great interest to the study of active matter. Additionally, microswimmers show promise in applications ranging from bioanalytics and environmental monitoring to particle separation and drug delivery. However, since their sizes are on the nano-/microscale and their speeds are in the μm s(-1) range, they fall into a low Reynolds number regime where viscosity dominates. Therefore, new propulsion schemes are needed for these microswimmers to be able to efficiently move. Furthermore, many of the hotly pursued applications call for innovations in the next phase of development of biocompatible microswimmers. In this review, the latest developments of microswimmers powered by ultrasound are presented. Ultrasound, especially at MHz frequencies, does little harm to biological samples and provides an advantageous and well-controlled means to efficiently power microswimmers. By critically reviewing the recent progress in this research field, an introduction of how ultrasound propels colloidal particles into autonomous motion is presented, as well as how this propulsion can be used to achieve preliminary but promising applications.

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“…In this paper we investigate for the first time the self-propulsion of micro-disks pinned upright at a liquid/air interface. The propulsion mechanism is based on catalytic conversion of H 2 O 2 to water and oxygen by platinum/palladium (Pt/Pd) alloy and gold (Au) (Ismagilov et al (2002), Stock et al (2008), Gibbs and Zhao (2009)), and the upright disks are driven by oxygen bubble growth on the disks inside the liquid and their burst upon contact with the liquid/air interface. The synthesis of the disks is based on a simple method to produce 'Janus' rods that self-propel in the direction perpendicular to their long axis (Reddy et al (2013)).…”

Section: Introductionmentioning

confidence: 99%

Self-propelling micro-disks

Reddy

Clasen

2014

Korea-Aust. Rheol. J.

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In this paper we introduce a simple and scalable method to produce micrometer sized 'Janus' disks whose rim is coated half with platinum/palladium and half with gold. The disks pinned upright to the air/liquid interface disks exhibit self-propulsion of ∼100 µm/s when submerged in H 2 O 2 solution, due to the catalytic growth of oxygen bubbles at the disks upper (platinum/palladium-coated) rim. The disks exhibit two different travel trajectories, linear and rotary, depending on the bubble growth position, and are propelled via two different mechanisms, the bubble growth and the bubble burst. The displacement speed due to the bubble burst is three orders of magnitude larger than from the bubble growth process, whereas displacement distances are of similar order of magnitude for both processes.

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Autonomous Movement of Silica and Glass Micro‐Objects Based on a Catalytic Molecular Propulsion System

Cited by 26 publications

References 99 publications

Synthetic Nano- and Micromachines in Analytical Chemistry: Sensing, Migration, Capture, Delivery, and Separation

Synthetic Nano- and Micromachines in Analytical Chemistry: Sensing, Migration, Capture, Delivery, and Separation

A Force to Be Reckoned With: A Review of Synthetic Microswimmers Powered by Ultrasound

Self-propelling micro-disks

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