Utilizing Iron's Attractive Chemical and Magnetic Properties in Microrocket Design, Extended Motion, and Unique Performance

Karshalev, Emil; Chen, Chuanrui; Marolt, Gregor; Martin, Adam C.; Campos, Isaac; Castillo, Roxanne; Wu, Tianlong; Wang, Joseph

doi:10.1002/smll.201700035

Cited by 25 publications

(26 citation statements)

References 35 publications

(46 reference statements)

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“…For instance, the use of dual stimuli offers multiple practical solutions to precisely guide nanomotors through a hybrid trigger. Chemically and physically propelled nanomotors have been integrated with diverse ferromagnetic segments (Ni, Fe, and Co) to establish control over the nanomotor directionality, by aligning them with a magnetic field or via magnetic torque applied to the motor structure . Such magnetic fields can be produced by a magnetic bar which offers direct manipulation or with a Helmholtz coil that produces a highly accurate 3D control.…”

Section: Multistimuli‐enabled Advanced Motion Controlmentioning

confidence: 99%

Hybrid Nanovehicles: One Machine, Two Engines

Chen

Soto

Karshalev

et al. 2018

Adv Funct Materials

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Nanomotors have emerged as promising and versatile nanorobotic tools in a variety of medical, sensing, decontamination, and manufacturing applications due to their unique ability to operate and perform task at small scales. This review focuses on the current progress and future perspectives of hybrid nanomotors based on two power sources, with a special highlight on their distinct advantages, unique propulsion behaviors, adaptive operation, and potential applications. Such incorporation of multiple engines into a single nanoscale vehicle addresses certain limitations of nanomotors based on a single propulsion mode and adds new dimensions for advanced motion management. These attractive capabilities of hybrid nanoscale vehicles are discussed along with the challenges and opportunities when coupling several propulsion modes into a single device. With continuous innovations, it is expected that hybrid nanomotors will have a profound impact upon the field of nanorobotics.

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Section: Multistimuli‐enabled Advanced Motion Controlmentioning

confidence: 99%

Hybrid Nanovehicles: One Machine, Two Engines

Chen

Soto

Karshalev

et al. 2018

Adv Funct Materials

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“…The Fe‐NP aggregates submerged in an aqueous solution of 3.38 wt% citric acid and 1% SDS moved with a speed of 7–20 µm s −1 . The electrodeposited multilayered PEDOT/Au/Fe‐based micromotors propelled by reaction with 1.2 m HCl to the speed of ≈35 µm s −1 . The chemical reaction involved is represented as Fe(s) + 2H 3 O + → Fe 2+ (aq) + 2H 2 O + H 2 (g).…”

Section: Catalytic Materials For Mnmsmentioning

confidence: 99%

Progress toward Catalytic Micro‐ and Nanomotors for Biomedical and Environmental Applications

2018

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Synthetic micro- and nanomotors (MNMs) are tiny objects that can autonomously move under the influence of an appropriate source of energy, such as a chemical fuel, magnetic field, ultrasound, or light. Chemically driven MNMs are composed of or contain certain reactive material(s) that convert chemical energy of a fuel into kinetic energy (motion) of the particles. Several different materials have been explored over the last decade for the preparation of a wide variety of MNMs. Here, the discovery of materials and approaches to enhance the efficiency of chemically driven MNMs are reviewed. Several prominent applications of the MNMs, especially in the fields of biomedicine and environmental science, are also discussed, as well as the limitations of existing materials and future research directions.

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“…Later, Solovev et al found that an incorporated ferromagnetic layer in rolled-up microtubes can be used to control the motion of microjet engines with magnetic fields [ 137 ]. Subsequently, magnetic control of microjets was improved [ 138 , 139 , 140 ] as well as other NMs including nanowire motors [ 141 ], Janus particles [ 142 , 143 ], paperbots [ 144 ], liquibots [ 145 ], freestyle nanoswimmer [ 146 ], fish-like nanoswimmers [ 147 ], liquid metal motors [ 148 ], flexible and linked superparamagnetic colloidal chains [ 149 ], chemo-magnetic structures [ 150 ], magneto-electric structures [ 151 ], magneto-acoustic structures [ 152 ] and chiral nanomagnets [ 153 ]. Fuel free NMs have advantages in biomedical applications, since there are no reaction products produced during the navigation [ 154 ].…”

Section: Motion Control and Externally Powered Micromotorsmentioning

confidence: 99%

Geometry Design, Principles and Assembly of Micromotors

et al. 2018

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Discovery of bio-inspired, self-propelled and externally-powered nano-/micro-motors, rotors and engines (micromachines) is considered a potentially revolutionary paradigm in nanoscience. Nature knows how to combine different elements together in a fluidic state for intelligent design of nano-/micro-machines, which operate by pumping, stirring, and diffusion of their internal components. Taking inspirations from nature, scientists endeavor to develop the best materials, geometries, and conditions for self-propelled motion, and to better understand their mechanisms of motion and interactions. Today, microfluidic technology offers considerable advantages for the next generation of biomimetic particles, droplets and capsules. This review summarizes recent achievements in the field of nano-/micromotors, and methods of their external control and collective behaviors, which may stimulate new ideas for a broad range of applications.

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Utilizing Iron's Attractive Chemical and Magnetic Properties in Microrocket Design, Extended Motion, and Unique Performance

Cited by 25 publications

References 35 publications

Hybrid Nanovehicles: One Machine, Two Engines

Hybrid Nanovehicles: One Machine, Two Engines

Progress toward Catalytic Micro‐ and Nanomotors for Biomedical and Environmental Applications

Geometry Design, Principles and Assembly of Micromotors

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