3D Motion Manipulation for Micro‐ and Nanomachines: Progress and Future Directions

Huang, Hai; Yang, Shihao; Ying, Yulong; Chen, Xiangzhong; Puigmartí‐Luis, Josep; Zhang, Li; Pané, Salvador

doi:10.1002/adma.202305925

Cited by 4 publications

(3 citation statements)

References 196 publications

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“…Micro/nanorobots are artificial machines characterized by motion abilities, usually powered by nearby chemicals (e.g., H 2 O 2 , enzymes), external energy fields (light, magnetic, acoustic, and electric), or inherent self-propulsion mechanisms. − Endowed by programmable functionalities or collective behaviors, micro/nanorobots strongly improve the performance of nonmotile systems. − Among them, magnetically driven micro/nanorobots with swarming behavior hold immense promise for achieving more intricate functionalities. Microrobot swarms can be likened to singular robotic entities working collaboratively, emulating the collective behaviors observed in natural swarms. − Microrobot collectives’ synchronized and controlled actions can further amplify functional efficiency as compared to individual units’ capacities and enable them to collaborate and generate higher-order functionalities. ,− …”

Section: Introductionmentioning

confidence: 99%

Magnetic Microrobot Swarms with Polymeric Hands Catching Bacteria and Microplastics in Water

Ussia,

Urso,

Oral

et al. 2024

ACS Nano

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The forefront of micro-and nanorobot research involves the development of smart swimming micromachines emulating the complexity of natural systems, such as the swarming and collective behaviors typically observed in animals and microorganisms, for efficient task execution. This study introduces magnetically controlled microrobots that possess polymeric sequestrant "hands" decorating a magnetic core. Under the influence of external magnetic fields, the functionalized magnetic beads dynamically self-assemble from individual microparticles into well-defined rotating planes of diverse dimensions, allowing modulation of their propulsion speed, and exhibiting a collective motion. These mobile microrobotic swarms can actively capture free-swimming bacteria and dispersed microplastics "on-the-fly", thereby cleaning aquatic environments. Unlike conventional methods, these microrobots can be collected from the complex media and can release the captured contaminants in a second vessel in a controllable manner, that is, using ultrasound, offering a sustainable solution for repeated use in decontamination processes. Additionally, the residual water is subjected to UV irradiation to eliminate any remaining bacteria, providing a comprehensive cleaning solution. In summary, this study shows a swarming microrobot design for water decontamination processes.

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Section: Introductionmentioning

confidence: 99%

Magnetic Microrobot Swarms with Polymeric Hands Catching Bacteria and Microplastics in Water

Ussia,

Urso,

Oral

et al. 2024

ACS Nano

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“…Current nanorobot designs rely on the use of different materials to provide a specific response to external energy input. For example, photocatalytic semiconductors are typically used to fabricate light-driven nanomotors; , polystyrene or silica-based structures coated with enzymes or metallic caps are often used for developing chemically fueled nanomotors, , and ferromagnetic materials are usually employed to steer the direction of the nanomotors through magnetic fields (MFs) . Consequently, these nanomotors have shown promise in numerous applications ranging from targeted drug delivery, − cargo manipulation, ,,, water purification − to nanoscale assembly. , …”

Section: Introductionmentioning

confidence: 99%

“…For example, photocatalytic semiconductors are typically used to fabricate light-driven nanomotors; 3 , 4 polystyrene or silica-based structures coated with enzymes or metallic caps are often used for developing chemically fueled nanomotors, 5 , 6 and ferromagnetic materials are usually employed to steer the direction of the nanomotors through magnetic fields (MFs). 7 Consequently, these nanomotors have shown promise in numerous applications ranging from targeted drug delivery, 8 − 11 cargo manipulation, 5 , 6 , 12 , 13 water purification 14 − 17 to nanoscale assembly. 18 , 19 …”

Section: Introductionmentioning

confidence: 99%

Boosting the Efficiency of Photoactive Rod-Shaped Nanomotors via Magnetic Field-Induced Charge Separation

Ferrer Campos,

Bakenecker,

Chen

et al. 2024

ACS Appl. Mater. Interfaces

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Photocatalytic nanomotors have attracted a lot of attention because of their unique capacity to simultaneously convert light and chemical energy into mechanical motion with a fast photoresponse. Recent discoveries demonstrate that the integration of optical and magnetic components within a single nanomotor platform offers novel advantages for precise motion control and enhanced photocatalytic performance. Despite these advancements, the impact of magnetic fields on energy transfer dynamics in photocatalytic nanomotors remains unexplored. Here, we introduce dual-responsive rod-like nanomotors, made of a TiO2/NiFe heterojunction, able to (i) self-propel upon irradiation, (ii) align with the direction of an external magnetic field, and (iii) exhibit enhanced photocatalytic performance. Consequently, when combining light irradiation with a homogeneous magnetic field, these nanomotors exhibit increased velocities attributed to their improved photoactivity. As a proof-of-concept, we investigated the ability of these nanomotors to generate phenol, a valuable chemical feedstock, from benzene under combined optical and magnetic fields. Remarkably, the application of an external magnetic field led to a 100% increase in the photocatalytic phenol generation in comparison with light activation alone. By using various state-of-the-art techniques such as photoelectrochemistry, electrochemical impedance spectroscopy, photoluminescence, and electron paramagnetic resonance, we characterized the charge transfer between the semiconductor and the alloy component, revealing that the magnetic field significantly improved charge pair separation and enhanced hydroxyl radical generation. Consequently, our work provides valuable insights into the role of magnetic fields in the mechanisms of light-driven photocatalytic nanomotors for designing more effective light-driven nanodevices for selective oxidations.

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Revolutionizing Tetracycline Hydrochloride Remediation: 3D Motile Light‐Driven MOFs Based Micromotors in Harsh Saline Environments

Zhao,

Lin,

et al. 2024

Advanced Science

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Traditional light‐driven metal‐organic‐frameworks (MOFs)‐based micromotors (MOFtors) are typically constrained to two‐dimensional (2D) motion under ultraviolet or near‐infrared light and often demonstrate instability and susceptibility to ions in high‐saline environments. This limitation is particularly relevant to employing micromotors in water purification, as real wastewater is frequently coupled with high salinity. In response to these challenges, ultrastable MOFtors capable of three‐dimensional (3D) motion under a broad spectrum of light through thermophoresis and electrophoresis are successfully synthesized. The MOFtors integrated photocatalytic porphyrin MOFs (PCN‐224) with a photothermal component made of polypyrrole (PPy) by three distinct methodologies, resulting in micromotors with different motion behavior and catalytic performance. Impressively, the optimized MOFtors display exceptional maximum velocity of 1305 ± 327 µm s−1 under blue light and 2357 ± 453 µm s−1 under UV light. In harsh saline environments, these MOFtors are not only maintain high motility but also exhibit superior tetracycline hydrochloride (TCH) removal efficiency of 3578 ± 510 mg g−1, coupling with sulfate radical‐based advanced oxidation processes and peroxymonosulfate. This research underscores the significant potential of highly efficient MOFtors with robust photocatalytic activity in effectively removing TCH in challenging saline conditions, representing a substantial advancement in applying MOFtors within real‐world water treatment technologies.

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3D Motion Manipulation for Micro‐ and Nanomachines: Progress and Future Directions

Cited by 4 publications

References 196 publications

Magnetic Microrobot Swarms with Polymeric Hands Catching Bacteria and Microplastics in Water

Magnetic Microrobot Swarms with Polymeric Hands Catching Bacteria and Microplastics in Water

Boosting the Efficiency of Photoactive Rod-Shaped Nanomotors via Magnetic Field-Induced Charge Separation

Revolutionizing Tetracycline Hydrochloride Remediation: 3D Motile Light‐Driven MOFs Based Micromotors in Harsh Saline Environments

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