Ultrafast Growth and Locomotion of Dandelion‐Like Microswarms with Tubular Micromotors

Lu, Xiaolong; Shen, Hui; Wei, Ying; Ge, Haitao; Wang, Joseph; Peng, Hanmin; Liu, Wenjuan

doi:10.1002/smll.202003678

Cited by 40 publications

(48 citation statements)

References 62 publications

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“…Because of the free-swimming strategy, the control of the motion direction is not essential here; however, it could be regulated by a magnetic field after incorporating the magnetic coating for further target capture, delivery, and killing. 10,40,41 The association of ultrasound with chemically-driven micromotors will give distinct motility, such as group assembly and ultrafast zigzag motion, 42 therefore, leading to concentrated liberated ions in localized regions and a rapid mass transfer. Typically, these bubble-propelled micromotors could result in a violent mixture in the localized-region and ought to accelerate the mass transfer.…”

Section: Resultsmentioning

confidence: 99%

Cubic nano-silver-decorated manganese dioxide micromotors: enhanced propulsion and antibacterial performance

Liu

Ding

et al. 2020

Nanoscale

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Section: Resultsmentioning

confidence: 99%

Cubic nano-silver-decorated manganese dioxide micromotors: enhanced propulsion and antibacterial performance

Liu

Ding

et al. 2020

Nanoscale

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“…[70] A number of tubular Mn-micro/nanomotors are able to construct a group schooling on the bigger oscillated bubbles, which are formed at the bottom opening of an individual Mn-micro/nanomotor. [71] The intelligent collective motion opens a new gate to condense more functionalized Mn-micro/nanomotors in a small region, promoting the efficiency of functionalization (e.g., removing contaminants and killing cancer cells).…”

Section: Motion Behaviors Of Mn-micro/nanomotorsmentioning

confidence: 99%

Manganese‐Based Micro/Nanomotors: Synthesis, Motion, and Applications

Yang

Zhang

et al. 2021

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As emerging micro/nano‐scale devices, micro/nanomotors have been innovatively applied in the environmental and biomedical applications. In this paper, the recent advances of Mn‐based micro/nanomotors (Mn‐micro/nanomotors) in catalytic oxidation of organic contaminants and the mechanisms in decomposition of H2O2 (e.g., the generation of O2 bubbles and reactive oxygen species) are reviewed. The intrinsic characteristics and synthetic strategies of Mn‐based materials are discussed, aiming to gain comprehensive understandings on the asymmetric design of micro/nanomotors. Mn‐micro/nanomotors have many advantages such as flexible structures, biocompatibility, powerful motion, long lifetime, and low‐cost as compared to noble‐metal micro/nanomotors. These merits fulfil Mn‐micro/nanomotors great promises from proof‐of‐concept studies to realistic applications, including pollutant decomposition, trace detection of heavy metal ions, oil removal, drug delivery, isolation of biological targets, and killing bacteria and cancer cells. The great flexibility in fabrication enables diverse and innovative strategies to address challenges for Mn‐micro/nanomotors, including high consumption of H2O2 and non‐directional motion. Meanwhile, a perspective of Mn‐micro/nanomotors in water remediation by coupling the motors with other Fenton/Fenton‐like systems to enhance the catalytic activity and to yield more reactive oxygen species is presented. Directions to the design of on‐demand H2O2‐fueled Mn‐micro/nanomotors for advanced purification of organic contaminants in aquatic systems are also proposed.

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“…[ 1–8 ] The characteristic self‐propulsion exhibited by micromotors enables their use in a variety of applications, such as drug delivery, [ 9–16 ] environmental clean‐up, [ 17–21 ] or self‐assembly of active ensembles. [ 22–28 ] Most commonly, self‐propelling micromotors exhibit a two‐sided Janus morphology, thus termed a Janus micromotor (JM). One face of the JM is typically inert, while the other face is either catalytic, producing local anisotropic chemical gradients, [ 29–34 ] or interacts with an external field (such as light [ 19,21,35–38 ] or magnetic fields [ 32,39 ] ).…”

Section: Introductionmentioning

confidence: 99%

Investigating Time‐Dependent Active Motion of Janus Micromotors using Dynamic Light Scattering

McGlasson

Bradley

2021

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Advances in fabrication methods have positioned Janus micromotors (JMs) as candidates for use as autonomous devices in applications across diverse fields, spanning drug delivery to environmental remediation. While the design of most micromotors is straightforward, the non‐steady state active motion exhibited by these systems is complex and difficult to characterize. Traditionally, JM active motion is characterized using optical microscopy single particle tracking for systems confined in 2D. Dynamic light scattering (DLS) offers an alternative high‐throughput method for characterizing the 3D active motion in bulk JM dispersions with additional capabilities to quantify time‐dependent behavior for a broader range of JM sizes. Here, the active motion of spherical JMs is examined by DLS and it is demonstrated that the method enables decoupling of the translational and rotational diffusion. Systematic studies quantifying the time‐dependent diffusive properties as a function of fuel concentration, JM concentration, and time after fuel addition are presented. The analyses presented in this work position DLS to facilitate future advances of JM systems by serving as a fast‐screening characterization method for active motion.

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Ultrafast Growth and Locomotion of Dandelion‐Like Microswarms with Tubular Micromotors

Cited by 40 publications

References 62 publications

Cubic nano-silver-decorated manganese dioxide micromotors: enhanced propulsion and antibacterial performance

Cubic nano-silver-decorated manganese dioxide micromotors: enhanced propulsion and antibacterial performance

Manganese‐Based Micro/Nanomotors: Synthesis, Motion, and Applications

Investigating Time‐Dependent Active Motion of Janus Micromotors using Dynamic Light Scattering

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