Magnetic Putty as a Reconfigurable, Recyclable, and Accessible Soft Robotic Material

Li, Meng; Pal, Aniket; Byun, Junghwan; Gardi, Gaurav; Sitti, Metin

doi:10.1002/adma.202304825

Cited by 8 publications

(4 citation statements)

References 52 publications

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“…Various types of ferromagnetic materials with different structures have been reported, and their magnetic properties can be regulated by structural design. [35][36][37][38][39] However, the intershell magnetic interactions of ferromagnetic materials to guide structural design has not been systematically simulated to guide the structural design. To address this problem, micromagnetic simulations of ferromagnetic materials were performed.…”

Section: Micromagnetic Simulation For the Intershell Magnetic Interac...mentioning

confidence: 99%

Visualizing Nanoscale Interlayer Magnetic Interactions and Unconventional Low‐Frequency Behaviors in Ferromagnetic Multishelled Structures

Chen,

Zhang,

Yuan

et al. 2024

Advanced Materials

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Precise manipulation of van der Waals forces within two‐dimensional atomic layers allows for exact control over electron‐phonon coupling, leading to the exceptional quantum properties. However, applying this technique to diverse structures such as three‐dimensional materials is challenging. Therefore, investigating new hierarchical structures and different interlayer forces is crucial for overcoming these limitations and discovering novel physical properties. In this work, a multi‐shelled ferromagnetic material with controllable shell numbers is developed. By strategically regulating the magnetic interactions between these shells, the magnetic properties of each shell are fine‐tuned. This approach reveals distinctive magnetic characteristics including regulated magnetic domain configurations and enhanced effective fields. The nanoscale magnetic interactions between the shells were observed and analyzed, which shed light on the modified magnetic properties of each shell, enhancing the understanding and control of ferromagnetic materials. The distinctive magnetic interaction significantly boosts electromagnetic absorption at low‐frequency frequencies used by fifth‐generation (5G) wireless devices, outperforming ferromagnetic materials without multilayer structures by several folds. The application of magnetic interactions in materials science reveals thrilling prospects for technological and electronic innovation.This article is protected by copyright. All rights reserved

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Section: Micromagnetic Simulation For the Intershell Magnetic Interac...mentioning

confidence: 99%

Visualizing Nanoscale Interlayer Magnetic Interactions and Unconventional Low‐Frequency Behaviors in Ferromagnetic Multishelled Structures

Chen,

Zhang,

Yuan

et al. 2024

Advanced Materials

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show abstract

Section: Introductionmentioning

confidence: 99%

“…Flexible electronics has been regarded as the forthcoming revolution within the electronics industry and has found extensive applications across diverse fields, such as photovoltaics, − flexible sensors, , electronic skin, − human–machine interfaces, , soft robotics, , emerging display, and so on. , Recently, many fabrication approaches for flexible electronics have been reported, including screen printing, inkjet printing, , and three-dimensional (3D) printing. ,,, Screen printing is a printing technique that involves applying ink by exerting pressure to force it through a specially designed stencil using a squeegee . Despite its advantage in mass production and compatibility with roll-to-roll technology in various industries, screen printing still faces limitations when it comes to depositing functional metallic films in the submicroscale range. , Inkjet printing offers the advantage of being maskless and capable of depositing materials on demand .…”

Section: Introductionmentioning

confidence: 99%

Multiscale Transfer Printing via Shape Memory Polymer with High Adhesion and Modulus Switchability

Fan,

Chen,

Zhou

et al. 2024

ACS Appl. Mater. Interfaces

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Flexible electronics have gained significant attention as an innovative solution to meet the growing need for information collection from the human body and the environment. However, a critical challenge lies in the need for a transfer printing technique that can fabricate rigid and brittle devices on flexible organic substrates. Here, we develop a multiscale transfer printing technique using an ultraviolet-curable shape memory polymer (SMP) that serves as both the stamp and the receiver substrate. The SMP demonstrates exceptional mechanical performance with toughness at room temperature and remarkable flexibility near its glass transition temperature. The SMP material exhibits an impressive shape recovery ratio and remarkable adhesion switchability. We demonstrate robust transfer printing of diverse objects with different materials and morphologies and in situ transfer of multiscale metallic structures. In addition, the in situ fabricated transparent hyperthermia patches with embedded metal grids are demonstrated, offering potential application in the field of sensors, wearable devices, and electronic skin.

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“…Soft elastomers and gels reinforced with hard structures like woven/knitted fibres or 3D printed structures, frequently with conductive/magnetic components for active capabilities, have been widely used in biomedical and soft robotics research [9][10][11][12][13]. The use of variable stiffness technologies, meticulous structural design, and programmable actuation has led to the development of new classes of materials and robotic systems that facilitate more natural interactions between robots and people [14]. Although research has concentrated on developing structures with less stiff components [15][16][17], there are still downsides to using only soft materials.…”

Section: Introductionmentioning

confidence: 99%

Fabrication and Applications of Magnetic Polymer Composites for Soft Robotics

Ganguly,

Margel

2023

Micromachines

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The emergence of magnetic polymer composites has had a transformative impact on the field of soft robotics. This overview will examine the various methods by which innovative materials can be synthesized and utilized. The advancement of soft robotic systems has been significantly enhanced by the utilization of magnetic polymer composites, which amalgamate the pliability of polymers with the reactivity of magnetic materials. This study extensively examines the production methodologies involved in dispersing magnetic particles within polymer matrices and controlling their spatial distribution. The objective is to gain insights into the strategies required to attain the desired mechanical and magnetic properties. Additionally, this study delves into the potential applications of these composites in the field of soft robotics, encompassing various devices such as soft actuators, grippers, and wearable gadgets. The study emphasizes the transformative capabilities of magnetic polymer composites, which offer a novel framework for the advancement of biocompatible, versatile soft robotic systems that utilize magnetic actuation.

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Magnetic Putty as a Reconfigurable, Recyclable, and Accessible Soft Robotic Material

Cited by 8 publications

References 52 publications

Visualizing Nanoscale Interlayer Magnetic Interactions and Unconventional Low‐Frequency Behaviors in Ferromagnetic Multishelled Structures

Visualizing Nanoscale Interlayer Magnetic Interactions and Unconventional Low‐Frequency Behaviors in Ferromagnetic Multishelled Structures

Multiscale Transfer Printing via Shape Memory Polymer with High Adhesion and Modulus Switchability

Fabrication and Applications of Magnetic Polymer Composites for Soft Robotics

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