Bioinspired Microsphere-Embedded Adhesive Architectures for an Electrothermally Actuating Transport Device of Dry/Wet Pliable Surfaces

Baik, Sangyul; Hwang, Gui Won; Jang, Siyeon; Jeong, Suyeon; Kim, Ki Hyun; Yang, Tae‐Heon; Pang, Changhyun

doi:10.1021/acsami.0c21847

Cited by 22 publications

(18 citation statements)

References 51 publications

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“…Numerous gecko-inspired synthetic adhesives employ a force-sensitive peeling mechanism to achieve debonding. [219][220][221][222][223][224][225][226] While many of these materials rely on light or heat to induce the peeling behavior, it is the driving force of that peeling motion that causes debonding. In a representative example, Zhou and coworkers utilized a poly(acrylamideisopropyl acrylamide-acrylic acid) hydrogel coupled with a PDMS micropillar array to achieve force-sensitive bonding and debonding (Fig.…”

Section: Gecko-inspired Adhesives Are Force-sensitivementioning

confidence: 99%

Stimuli-responsive temporary adhesives: enabling debonding on demand through strategic molecular design

2021

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Section: Gecko-inspired Adhesives Are Force-sensitivementioning

confidence: 99%

Stimuli-responsive temporary adhesives: enabling debonding on demand through strategic molecular design

2021

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“…Commonly utilized electrical conductive layers are made of metals (e.g., Au, [166,167] Ag nanowires [AgNWs], [168] Ni-Cr wires [169] ), carbons (e.g., CNTs, [138] graphene, [170] and carbon fibers [171] ), MXenes (e.g., Ti 3 C 2 T x [172,173] ), conductive polymers (e.g., PEDOT:PSS [174] ), or conductive composites (e.g., AgNW/polydimethylsiloxane [PDMS], [175] Ag/graphene/ silicon rubber, [145] and Cu/Ni-coated fabric, [176] CNT/chitosan, [140] MXene/cellulose nanofiber, [173] PEDOT:PSS/paper, [19] AgNW/ PEDOT:PSS/paper [177] ). Insulating films are generally made of semicrystalline and elastomer polymers with either a low TEC (as the passive layer) or a high TEC (as the active layer), e.g., polyimide (PI), [167,169,174] polyethylene terephthalate (PET), [178] SU-8, [166] cellulose, [177] polycarbonate (PC), [173] polyethylene (PE), [168] polypropylene (PP), [176,177] PVC, [168] PDMS, [138,139,179] and liquid crystal elastomer (LCE). [167,169,180] As compared with semicrystalline polymers, elastomers generally show higher TECs and may generate higher strains/displacements but possibly lower stresses/forces.…”

Section: Film-based Soft Etasmentioning

confidence: 99%

“…Specially designed microgrippers based on ETAs can be fabricated by microfabrication techniques and were used to manipulate nanoscale/microscale objects such as cells and characterize mechanical performance of nanomaterials. [193,194] Macroscale soft grippers based on ETAs are easier to be fabricated in various configurations (e.g., with multiple arms or suckers) for manipulating small/fragile/sensitive objects, [169,174] and more functionalities such as sensing can be integrated with the ETA to produce intelligent interactive grippers. [180,184] A touch-triggered gripper/artificial flytrap using a self-sensing PDMS/liquid metal/ LCE ETA (Figure 11a) was made by rationally designed liquid metal circuit layer functioned as the electrical heater and mechanosensor simultaneously.…”

Section: Potential Applications For Ihmimentioning

confidence: 99%

Low‐Voltage Soft Actuators for Interactive Human–Machine Interfaces

Chen

Tan

Gong

et al. 2021

Advanced Intelligent Systems

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Soft electrical actuators driven by low voltages are promising for interactive human-machine interfaces (iHMI) applications including executing orders to complete various tasks and communicating with humans. The attractive features of low-voltage soft electrical actuators include their good safety, low power consumption, small system size, and nonrigid or deformable characteristics. This review covers three typical classes of electrical actuators, namely, electrochemical, electrothermal, and other electrical (dielectric, electrostatic, ferroelectric, and plasticized gel) actuators according to their mechanism and working potential range. For each kind of actuators, the advantages, working principle, device configuration/design, materials selection, recent progress, and potential applications for iHMI are summarized, with the strategies for enhancing the actuation performance under low voltages being highlighted. Finally, the challenges for those soft actuators and possible solutions are discussed.

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“…In addition, photothermal polymers were adapted to micropatterned soft grippers for a fast switchable dry adhesive, where the adhesion strength could increase up to a maximum of 2.5 times after exposure to UV light (Figure 4E) . A gripper system with an electrothermally controllable sucker was presented, which was capable of fast underwater adhesion control (Figure 4F) (Baik et al, 2021).…”

Section: Bioinspired Adhesives On Advanced Grippersmentioning

confidence: 99%

Applications of Bioinspired Reversible Dry and Wet Adhesives: A Review

et al. 2021

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Bioinspired adhesives that emulate the unique dry and wet adhesion mechanisms of living systems have been actively explored over the past two decades. Synthetic bioinspired adhesives that have recently been developed exhibit versatile smart adhesion capabilities, including controllable adhesion strength, active adhesion control, no residue remaining on the surface, and robust and reversible adhesion to diverse dry and wet surfaces. Owing to these advantages, bioinspired adhesives have been applied to various engineering domains. This review summarizes recent efforts that have been undertaken in the application of synthetic dry and wet adhesives, mainly focusing on grippers, robots, and wearable sensors. Moreover, future directions and challenges toward the next generation of bioinspired adhesives for advanced industrial applications are described.

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Bioinspired Microsphere-Embedded Adhesive Architectures for an Electrothermally Actuating Transport Device of Dry/Wet Pliable Surfaces

Cited by 22 publications

References 51 publications

Stimuli-responsive temporary adhesives: enabling debonding on demand through strategic molecular design

Stimuli-responsive temporary adhesives: enabling debonding on demand through strategic molecular design

Low‐Voltage Soft Actuators for Interactive Human–Machine Interfaces

Applications of Bioinspired Reversible Dry and Wet Adhesives: A Review

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