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      Shape Memory Alloy (SMA) Actuators: The Role of Material, Form, and Scaling Effects

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          Abstract

          Shape memory alloys (SMAs) are smart materials that are widely used to create intelligent devices because of their high energy density, actuation strain, and biocompatibility characteristics. Given their unique properties, SMAs are found to have significant potential for implementation in many emerging applications in mobile robots, robotic hands, wearable devices, aerospace/automotive components, and biomedical devices. Here, the state–of–the–art of thermal and magnetic SMA actuators in terms of their constituent materials, form, and scaling effects are summarized, including their surface treatments and functionalities. The motion performance of various SMA architectures (wires, springs, smart soft composites, and knitted/woven actuators) is also analyzed. Based on the assessment, current challenges of SMAs that need to be addressed for their practical application are emphasized. Finally, how to advance SMAs by synergistically considering the effects of material, form, and scale is suggested.

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          Advances in engineering hydrogels.

          Yu Shrike Zhang, Ali Khademhosseini (2017)
          Hydrogels are formed from hydrophilic polymer chains surrounded by a water-rich environment. They have widespread applications in various fields such as biomedicine, soft electronics, sensors, and actuators. Conventional hydrogels usually possess limited mechanical strength and are prone to permanent breakage. Further, the lack of dynamic cues and structural complexity within the hydrogels has limited their functions. Recent developments include engineering hydrogels that possess improved physicochemical properties, ranging from designs of innovative chemistries and compositions to integration of dynamic modulation and sophisticated architectures. We review major advances in designing and engineering hydrogels and strategies targeting precise manipulation of their properties across multiple scales.
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            Hydraulic hydrogel actuators and robots optically and sonically camouflaged in water

            Hyunwoo Yuk, Shaoting Lin, Chu Jian Ma (2017)
            Sea animals such as leptocephali develop tissues and organs composed of active transparent hydrogels to achieve agile motions and natural camouflage in water. Hydrogel-based actuators that can imitate the capabilities of leptocephali will enable new applications in diverse fields. However, existing hydrogel actuators, mostly osmotic-driven, are intrinsically low-speed and/or low-force; and their camouflage capabilities have not been explored. Here we show that hydraulic actuations of hydrogels with designed structures and properties can give soft actuators and robots that are high-speed, high-force, and optically and sonically camouflaged in water. The hydrogel actuators and robots can maintain their robustness and functionality over multiple cycles of actuations, owing to the anti-fatigue property of the hydrogel under moderate stresses. We further demonstrate that the agile and transparent hydrogel actuators and robots perform extraordinary functions including swimming, kicking rubber-balls and even catching a live fish in water.
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              Soft micromachines with programmable motility and morphology

              Hen-Wei Huang, Mahmut Sakar, Andrew Petruska (2016)
              Nature provides a wide range of inspiration for building mobile micromachines that can navigate through confined heterogenous environments and perform minimally invasive environmental and biomedical operations. For example, microstructures fabricated in the form of bacterial or eukaryotic flagella can act as artificial microswimmers. Due to limitations in their design and material properties, these simple micromachines lack multifunctionality, effective addressability and manoeuvrability in complex environments. Here we develop an origami-inspired rapid prototyping process for building self-folding, magnetically powered micromachines with complex body plans, reconfigurable shape and controllable motility. Selective reprogramming of the mechanical design and magnetic anisotropy of body parts dynamically modulates the swimming characteristics of the micromachines. We find that tail and body morphologies together determine swimming efficiency and, unlike for rigid swimmers, the choice of magnetic field can subtly change the motility of soft microswimmers.
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                Author and article information

                Contributors
                Salvador Pané: (View ORCID Profile)
                Journal
                Title: Advanced Materials
                Abbreviated Title: Advanced Materials
                ISSN (Print): 0935-9648
                ISSN (Electronic): 1521-4095
                Publication date Created: August 2023
                Publication date (Electronic): June 29 2023
                Publication date (Print): August 2023
                Volume: 35
                Issue: 33
                Affiliations
                [1 ] Institute of Robotics and Intelligent Systems ETH Zurich Zurich CH‐8092 Switzerland
                [2 ] Department of Mechanical Engineering Seoul National University Seoul 08826 Republic of Korea
                [3 ] School of Mechanical Engineering Sungkyunkwan University Gyeonggido 16419 Republic of Korea
                [4 ] Department of Mechanical Engineering Inha University Incheon 22212 Republic of Korea
                [5 ] Department of Mechanical, Robotics and Energy Engineering Dongguk University Seoul 04620 Republic of Korea
                [6 ] Institute of Advanced Machines and Design Seoul National University Seoul 08826 Republic of Korea
                Article
                DOI: 10.1002/adma.202208517
                SO-VID: 15edde6e-7608-4ff1-9e21-71b2cc2c21b6
                Copyright © © 2023
                License:

                http://creativecommons.org/licenses/by-nc/4.0/

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