Symmetry-Breaking Actuation Mechanism for Soft Robotics and Active Metamaterials

Wu, Shu-Pao; Ze, Qiji; Zhang, Rundong; Hu, Nan; Cheng, Yong; Yang, Fengyuan; Zhao, Ruike Renee

doi:10.1021/acsami.9b13840

Cited by 141 publications

(80 citation statements)

References 55 publications

(104 reference statements)

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“…Figure illustrates the working principle of these unit cells. They are constructed using the concept of the magnetic‐responsive asymmetric joint design, [ 13a ] in which two oppositely polarized hmSAM beams are connected side‐by‐side with a small gap placed between them. When a downward magnetic field (negative B ) is applied, the hmSAMs tend to rotate in the opposite directions, closing the gap between them and causing a bending deformation of the joint, referred to as the bending mode (Figure 1a, left).…”

Section: Resultsmentioning

confidence: 99%

“…The architecture of this new metamaterial employs an asymmetric joint design using hmSAMs that allows rapid transition between two distinct actuation modes (bending and folding) under opposite‐direction magnetic fields. [ 13a ] The subsequent application of mechanical forces leads the metamaterial architecture to transform into two distinct shapes, a process referred to as deformation mode branching, which is otherwise unobtainable using either stimulus independently. The deformation mode branching also leads to dramatically different physical behaviors and allows the new metamaterial to have a much broader range of tunability in properties such as mechanical stiffness and acoustic bandgaps.…”

Section: Introductionmentioning

confidence: 99%

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Magneto‐Mechanical Metamaterials with Widely Tunable Mechanical Properties and Acoustic Bandgaps

Montgomery

Xiao

et al. 2020

Adv Funct Materials

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130

122

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Mechanical metamaterials are architected manmade materials that allow for unique behaviors not observed in nature, making them promising candidates for a wide range of applications. Existing metamaterials lack tunability as their properties can only be changed to a limited extent after the fabrication. Herein, a new magneto-mechanical metamaterial is presented that allows great tunability through a novel concept of deformation mode branching. The architecture of this new metamaterial employs an asymmetric joint design using hard-magnetic soft active materials that permits two distinct actuation modes (bending and folding) under opposite-direction magnetic fields. The subsequent application of mechanical compression leads to the deformation mode branching where the metamaterial architecture transforms into two distinctly different shapes, which exhibit very different deformations and enable great tunability in properties such as mechanical stiffness and acoustic bandgaps. Furthermore, this metamaterial design can be incorporated with magnetic shape memory polymers with global stiffness tunability, which also allows for the global shift of the acoustic behaviors. The combination of magnetic and mechanical actuations, as well as shape memory effects, impart wide tunable properties to a new paradigm of metamaterials.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Magneto‐Mechanical Metamaterials with Widely Tunable Mechanical Properties and Acoustic Bandgaps

Montgomery

Xiao

et al. 2020

Adv Funct Materials

Self Cite

130

122

View full text Add to dashboard Cite

show abstract

“…Researchers have also shown techniques to exploit combinations of bending and folding in magnetically‐actuated, square metamaterial unit cells that exhibited as much as 200% stiffness change under application of magnetic field. [ 208 ] Tuning of internal resonances is studied in ref. [ 209 ] to manipulate wave propagation in a metamaterial frame consisting of a lattice structure and a pair of embedded electromagnets for each unit cell.…”

Section: Active Mechanical Metamaterialsmentioning

confidence: 99%

Foundations for Soft, Smart Matter by Active Mechanical Metamaterials

Pishvar

Harne

2020

Advanced Science

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Emerging interest to synthesize active, engineered matter suggests a future where smart material systems and structures operate autonomously around people, serving diverse roles in engineering, medical, and scientific applications. Similar to biological organisms, a realization of active, engineered matter necessitates functionality culminating from a combination of sensory and control mechanisms in a versatile material frame. Recently, metamaterial platforms with integrated sensing and control have been exploited, so that outstanding non‐natural material behaviors are empowered by synergistic microstructures and controlled by smart materials and systems. This emerging body of science around active mechanical metamaterials offers a first glimpse at future foundations for autonomous engineered systems referred to here as soft, smart matter. Using natural inspirations, synergy across disciplines, and exploiting multiple length scales as well as multiple physics, researchers are devising compelling exemplars of actively controlled metamaterials, inspiring concepts for autonomous engineered matter. While scientific breakthroughs multiply in these fields, future technical challenges remain to be overcome to fulfill the vision of soft, smart matter. This Review surveys the intrinsically multidisciplinary body of science targeted to realize soft, smart matter via innovations in active mechanical metamaterials and proposes ongoing research targets that may deliver the promise of autonomous, engineered matter to full fruition.

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“…[130] The authors found that this increased freedom of the tail was possible by discretizing magnetically susceptible parts in the elastic tail instead of making a continuum. The widespread availability of multimaterial 3D printing and origami/kirigami technologies at the time, indeed, boosted creativity to realize more complex structures with discretized magnetic parts, such as frog-like swimmers by Zhao and coworkers, [99] starfish-like simmers by Nuzzo and coworkers, [90] and jellyfish-like swimmers by Sitti and coworkers (Figure 3c) [131] and Huang and coworkers. [132] There are a few other recent magnetic swimmer studies that deserve special mention.…”

Section: Magnetic Swimmersmentioning

confidence: 99%

Magnetically Controlled Soft Robotics Utilizing Elastomers and Gels in Actuation: A Review

Chung

Parsons

Zheng

2020

Advanced Intelligent Systems

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A magnetic field has unique advantages in controlling soft robotics inside of an enclosed space, such as surgical catheters or untethered drug‐delivering robots operating in the human body. Soft actuators, made of elastomers and gels functionalized with magnetically active materials, are natural choices to drive magnetically controlled motions of soft robots. Recent innovations in soft material technologies, including 3D printing, origami/kirigami, tough hydrogels, mechanical metamaterials, and liquid metal‐injected elastomers, offer technological foundations to develop soft actuators and robots with significantly enhanced performance. Herein, an overview of magnetic soft actuators and robots from a materials engineer's perspective is provided. First, the historical background and recent trends of magnetic soft actuators are discussed. Second, the motions of tethered or untethered magnetic soft robotics are classified into aquatic swimmers, terrestrial locomotors, and grippers. Herein, preprogrammed motion under patterned magnetic stimuli is achieved by controlled magnetization of elastomeric materials containing hard magnetic particles. Finally, the applications of magnetically controlled soft robotics in surgical and therapeutic medical devices are discussed.

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Symmetry-Breaking Actuation Mechanism for Soft Robotics and Active Metamaterials

Cited by 141 publications

References 55 publications

Magneto‐Mechanical Metamaterials with Widely Tunable Mechanical Properties and Acoustic Bandgaps

Magneto‐Mechanical Metamaterials with Widely Tunable Mechanical Properties and Acoustic Bandgaps

Foundations for Soft, Smart Matter by Active Mechanical Metamaterials

Magnetically Controlled Soft Robotics Utilizing Elastomers and Gels in Actuation: A Review

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