Self‐Propelled Micro/Nanoparticle Motors

Guix, Maria; Weiz, Sonja M.; Schmidt, Oliver G.; Medina‐Sánchez, Mariana

doi:10.1002/ppsc.201700382

Cited by 84 publications

(81 citation statements)

References 162 publications

(296 reference statements)

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“…In the case of vanishing noise ( f (t) = 0, g(t) = 0) the trajectories are deterministic. In the rotating frame, (8) and (9) have the solutions of a circular trajectory with a spinning frequency…”

Section: Noise-free Limitmentioning

confidence: 99%

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Active particles in noninertial frames: How to self-propel on a carousel

Löwen

2019

Phys. Rev. E

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Typically the motion of self-propelled active particles is described in a quiescent environment establishing an inertial frame of reference. Here we assume that friction, self-propulsion and fluctuations occur relative to a non-inertial frame and thereby the active Brownian motion model is generalized to non-inertial frames. First, analytical solutions are presented for the overdamped case, both for linear swimmers and circle swimmers. For a frame rotating with constant angular velocity ("carousel"), the resulting noise-free trajectories in the static laboratory frame trochoids if these are circles in the rotating frame. For systems governed by inertia, such as vibrated granulates or active complex plasmas, centrifugal and Coriolis forces become relevant. For both linear and circling self-propulsion, these forces lead to out-spiraling trajectories which for long times approach a spira mirabilis. This implies that a self-propelled particle will typically leave a rotating carousel. A navigation strategy is proposed to avoid this expulsion, by adjusting the self-propulsion direction at wish. For a particle, initially quiescent in the rotating frame, it is shown that this strategy only works if the initial distance to the rotation centre is smaller than a critical radius Rc which scales with the self-propulsion velocity. Possible experiments to verify the theoretical predictions are discussed. arXiv:1904.12755v1 [cond-mat.soft]

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Section: Noise-free Limitmentioning

confidence: 99%

“…The quantity r (t) − r (0) measures the mean displacement a self-propelled particle has achieved after a time t provided its orientationn (0) has been prescribed at time t = 0. According to the equations (8) and (9), we can use the standard results for a linear swimmer (M = 0) and a circle swimmer. For a linear swimmer [9,42]…”

Section: Effects Of Noisementioning

confidence: 99%

Active particles in noninertial frames: How to self-propel on a carousel

Löwen

2019

Phys. Rev. E

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“…The design and control of nanomotors and molecular machines is a subject of great interest that has undergone enormous development in recent years. Particularly appealing are the so-called "nanoswimmers", suspended nanoparticles (NPs) that navigate through a fluid thanks to mechanical forces that arise from inhomogeneities in their surroundings [1][2][3][4][5][6][7][8] . Such inhomogeneities can be, e.g., gradients of concentration (diffusiophoresis) [9][10][11][12][13][14] or temperature (thermophoresis) [15][16][17][18] .…”

Section: Introductionmentioning

confidence: 99%

Theoretical Analysis of Metallic-Nanodimer Thermoplasmonics for Phototactic Nanoswimmers

Bertoni

Passarelli

Bustos-Marún

2020

ACS Appl. Nano Mater.

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We assess the potentiality of several geometries of metallic nanodimers (one of the simplest thermoplasmonic systems) as candidates for active particles (nanoswimmers) propelled and controlled by light (phototaxis). The studied nanodimers are formed by two spherical nanoparticles of gold, silver, or copper with radii ranging from 20 to 100 nm. Contrary to most proposals, which assume the asymmetry of the systems as a requirement for self-propulsion, our results show that nanodimers made of identical nanoparticles are excellent candidates for phototactic self-thermophoretic systems. Nonsymmetrical nanodimers, although having a tunable effective diffusion, possess much lower or zero average thermophoretic forces. We show that the effective diffusion and the net thermophoretic force in both types of systems depend strongly on the wavelength of the incident light, which makes these properties highly tunable. Our study may be useful for the design of simple-to-make but controllable self-propelled nanoparticles. This can find numerous applications ranging from autonomous drug-carrying to controlling the self-assembly of complex nanomaterials. arXiv:1912.06209v2 [cond-mat.mes-hall]

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“…Light‐powered nano/micromotors have recently received great attention of the nano/micromachines communities, since the light energy source can be used simultaneously for motors propulsion and photocatalytic activation to degrade different pollutants in water‐purification applications . Unlike catalytic micromotors, which require destructive/toxic chemical fuels such as H 2 O 2 , the use of light power to activate the motion of these micromachines represents a more environmentally friendly approach that guarantees their potential use in disinfection applications.…”

Section: Introductionmentioning

confidence: 99%

“…Light-powered nano/micromotors have recently received great attention of the nano/micromachines communities, [1][2][3][4][5][6][7][8][9] since the light energy source can be used simultaneously for motors propulsion and photocatalytic activation to degrade different pollutants in water-purification applications. [10][11][12] Unlike protons (H + ).…”

Section: Introductionmentioning

confidence: 99%

Light‐Driven Sandwich ZnO/TiO₂/Pt Janus Micromotors: Schottky Barrier Suppression by Addition of TiO₂ Atomic Interface Layers into ZnO/Pt Micromachines Leading to Enhanced Fuel‐Free Propulsion

et al. 2019

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Conventional binary light‐driven micromotors, based on semiconducting photocatalysts and metal junctions, have mostly shown limited speed and charge separation/transport due to their not well‐designed interfaces. Here ZnO/Pt Janus micromotors with atomically smooth interfaces are introduced, which show fast light‐driven and fuel‐free propulsion (15 body‐length s−1). Furthermore, the speed of ZnO/Pt micromotors is increased by ≈60% with a few atomic amorphous TiO2 photocatalyst interlayers. The new photocatalysts' interfaces, i.e., ZnO/TiO2, provide type II heterojunctions, leading to an increase in the number of electron/hole pairs and then improving the electron transfer to Pt metal. This effective charge separation/transfer results in a faster electrophoretic motion of the novel ternary ZnO/TiO2/Pt micromotors. The concept of the type II heterojunction, which is well known in photocatalysis communities, is used in light‐driven micromotors as a new approach and paves the way for the next‐generation of faster fuel‐free “green” micromotors.

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Self‐Propelled Micro/Nanoparticle Motors

Cited by 84 publications

References 162 publications

Active particles in noninertial frames: How to self-propel on a carousel

Active particles in noninertial frames: How to self-propel on a carousel

Theoretical Analysis of Metallic-Nanodimer Thermoplasmonics for Phototactic Nanoswimmers

Light‐Driven Sandwich ZnO/TiO₂/Pt Janus Micromotors: Schottky Barrier Suppression by Addition of TiO₂ Atomic Interface Layers into ZnO/Pt Micromachines Leading to Enhanced Fuel‐Free Propulsion

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Self‐Propelled Micro/Nanoparticle Motors

Cited by 84 publications

References 162 publications

Active particles in noninertial frames: How to self-propel on a carousel

Active particles in noninertial frames: How to self-propel on a carousel

Theoretical Analysis of Metallic-Nanodimer Thermoplasmonics for Phototactic Nanoswimmers

Light‐Driven Sandwich ZnO/TiO2/Pt Janus Micromotors: Schottky Barrier Suppression by Addition of TiO2 Atomic Interface Layers into ZnO/Pt Micromachines Leading to Enhanced Fuel‐Free Propulsion

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About

Light‐Driven Sandwich ZnO/TiO₂/Pt Janus Micromotors: Schottky Barrier Suppression by Addition of TiO₂ Atomic Interface Layers into ZnO/Pt Micromachines Leading to Enhanced Fuel‐Free Propulsion