Magnetization‐Induced Self‐Assembling of Bendable Microneedle Arrays for Triboelectric Nanogenerators

Chen, Zhipeng; Rui, Yong; Lee, Weihsien; Jin, Dianwen; Zhang, Yuanxi; Jiang, Liyuan; Yang, Yilin; Ren, Lei; Jiang, Lelun

doi:10.1002/aelm.201800785

Cited by 18 publications

(11 citation statements)

References 62 publications

(62 reference statements)

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“…Further, the device can refine the design of damping forces in different directions to realize the control of damping variation in multi-directions. Furthermore, using a drawing lithography approach, some MRF microneedles were fabricated for minimally invasive surgery, transdermal drug delivery, and smart wearable equipment (Chen Z. P. et al, 2018;Chen et al 2019a;Chen et al, 2019b). In a gradient magnetic field, the MRF is magnetized and generates fusiform patterns, which results in different forms of microneedle arrays after heating and solidifying, as shown in Figure 10C.…”

Section: Magnetorheological Fluid Based Devices In Medical Applicationsmentioning

confidence: 99%

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A Review on Structural Configurations of Magnetorheological Fluid Based Devices Reported in 2018–2020

Hua

Liu

Li³

et al. 2021

Front. Mater.

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Magnetorheological fluid (MRF) is a kind of smart materials with rheological behavior change by means of external magnetic field application, which has been widely adopted in many complex systems of different technical fields. In this work, the state-of-the-art MRF based devices are reviewed according to structural configurations reported from 2018 to 2020. Based on the rheological characteristic, the MRF has a variety of operational modes, such as flow mode, shear mode, squeeze mode and pinch mode, and has unique advantages in some special practical applications. With reference to these operational modes, improved engineering mechanical devices with MRF are summarized, including brakes, clutches, dampers, and mounts proposed over these 3 years. Furthermore, some new medical devices using the MRF are also investigated, such as surgical assistive devices and artificial limbs. In particular, some outstanding advances on the structural innovations and application superiority of these devices are introduced in detail. Finally, an overview of the significant issues that occur in the MRF based devices is reported, and the developing trends for the devices using the MRF are discussed.

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Section: Magnetorheological Fluid Based Devices In Medical Applicationsmentioning

confidence: 99%

“…(B) Smart ball-socket actuator for upper limb rehabilitation (Wahed and Balkhoyor, 2018). (C) Magnetization-induced self-assembling process of microneedle array (Chen Z. P. et al, 2018;Chen et al 2019a;Chen et al, 2019b).…”

Section: Magnetorheological Fluid Based Devices In Medical Applicationsmentioning

confidence: 99%

A Review on Structural Configurations of Magnetorheological Fluid Based Devices Reported in 2018–2020

Hua

Liu

Li³

et al. 2021

Front. Mater.

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“…The formation process of magnetization-induced pillars is illustrated in Figure 6a. According to the classic Rosensweig pattern [25,34] in a homogeneous perpendicular magnetic field, λ π σ ρ…”

Section: Theoretical Considerationsmentioning

confidence: 99%

“…[3,4] Various mechanisms, such as triboelectric sensing, [5] mechanic-capacitive, [6] and systems, including functional medical implants, smart packaging, non-contact human-machine interaction elements, etc. [25][26][27][28][29] Some strategies have indeed been tried by packaging conventional magnetic film sensors (e.g., hall sensor, giant magnetoresistive sensor) with soft materials or fabricating them on flexible substrates. [30][31][32] However, the brittle/rigid nature of permanent magnetic materials severely affect their long-term use in deformation.…”

Section: Introductionmentioning

confidence: 99%

Ultrasensitive Multifunctional Magnetoresistive Strain Sensor Based on Hair‐Like Magnetization‐Induced Pillar Forests

Ding

Pei

Xuan

et al. 2019

Adv Elect Materials

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mechanic-resistive, [7] have been proposed and implemented in the design of electronic systems. Although such systems have undergone rapid growth and can satisfy or surpass the subtle sensing properties of human skin, it is still challenging to develop flexible electronics with multimodal sensing capabilities to detect manifold environmental changes. The contact-type mechanic-resistive sensors convert mechanical displacements into impedance changes and have gained tremendous interest owing to their simple read-out mechanism and higher sensitivity to pressure. [8-10] Herein, the micropillar or microdome array has been widely investigated for the potential high pixel density. Various techniques have been developed to prepare the arrays, such as the subtractive processes, additive processes, and micromolding technique. [11-15] However, the technologies still have limitations to apply for businesses large-scale manufacturing, such as complex processes, difficult operations, time-consuming steps, costly materials or machines, and relatively low production efficiency. For example, in the subtractive processes, the three-dimensional structures are selectively carved out of a two-dimensional (2D) substrate, including lithography with wet or dry etching, micromachining, laser cutting, electroplating, and wire electrode cutting. [15,16] Moreover, most precision technology manufacturing array structures are rigid, which are incompatible for the required flexible electronic components. Above all, challenges remain for the simple, scalable, low-cost, and rapid fabrication. Remarkably, there are many attempts to realize the functions and capabilities beyond the human skin, such as superhydrophobicity, [17] anti-freezing, [18] proximity detection, [19] magnetoreception, [20] self-healing, [21] and electromagnetic interference shielding. [22] These additional features that humans do not possess are challenging and attractive, which may greatly expand the application range of artificial electronic systems. [23,24] Among them, magneto-reception is a sensing capability which allows organisms, such as bacteria, ants, bees, pigeons, and whales to detect the earth's magnetic field for orientation and navigation. By endowing artificial electronics with magnetic field sensing capability, flexible magnetic sensors are believed to open up new areas for the future of intelligent wearable An ultrasensitive multifunctional sensor which integrates tactile sensing and magnetism sensing together in one device is presented. The sensor, dubbed L-MPF, consists of two interlocking hair-like magnetizationinduced pillar forests, which are self-formed under a magnetic field and a loading pressure. An L-MPF endows intelligent electronics with magnetic field reception, which is the sense of bacteria, birds, and whales, rather than human beings. It is found that the L-MPF precisely detects the magnitude and the loading path of the dynamic load, including pressure, shear, and magnetic field, with fast response, high reversibility, excellent sensitivity, a...

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“…Methods for fabricating artificial cilia can generally be classified according to whether they use templates. [33] Template-based approaches usually involve lithography or pre-defined molds that can require complex, lengthy, or expensive fabrication processes, [13,34,35] but there has been some progress in developing simpler template-based fabrication methods. For example, templates can be fabricated through mechanical punching.…”

Section: Introductionmentioning

confidence: 99%

Photothermally Reconfigurable Shape Memory Magnetic Cilia

Liu

Evans

Tracy

2020

Adv Materials Technologies

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Stimulus-responsive polymers are attractive for microactuators because they can be easily miniaturized and remotely actuated, enabling untethered operation. In this work, magnetic Fe microparticles are dispersed in a thermoplastic polyurethane shape memory polymer matrix and formed into artificial, magnetic cilia by solvent casting within the vertical magnetic field in the gap between two permanent magnets. Interactions of the magnetic moments of the microparticles, aligned by the applied magnetic field, drive self-assembly of magnetic cilia along the field direction. The resulting magnetic cilia are reconfigurable using light and magnet fields as remote stimuli. Temporary shapes obtained through combined magnetic actuation and photothermal heating can be locked by switching off the light and magnetic field. Subsequently turning on the light without the magnetic field drives recovery of the permanent shape. The permanent shape can also be reprogrammed after preparing the cilia by applying mechanical constraints and annealing at high temperature. Spatially controlled actuation is demonstrated by applying a mask for optical pattern transfer into the array of magnetic cilia. A theoretical model is developed for predicting the response of shape memory magnetic cilia and elucidates physical mechanisms behind observed phenomena, enabling the design and optimization of ciliary systems for specific applications.

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Magnetization‐Induced Self‐Assembling of Bendable Microneedle Arrays for Triboelectric Nanogenerators

Cited by 18 publications

References 62 publications

A Review on Structural Configurations of Magnetorheological Fluid Based Devices Reported in 2018–2020

A Review on Structural Configurations of Magnetorheological Fluid Based Devices Reported in 2018–2020

Ultrasensitive Multifunctional Magnetoresistive Strain Sensor Based on Hair‐Like Magnetization‐Induced Pillar Forests

Photothermally Reconfigurable Shape Memory Magnetic Cilia

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