A micropolar shell model for hard‐magnetic soft materials

Dadgar‐Rad, Farzam; Hossain, Mokarram

doi:10.1002/nme.7188

Cited by 10 publications

(6 citation statements)

References 82 publications

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“…A model based on micropolar continuum shell theory (where each material particle was coupled with a microstructure that can undergo micro-rotation) was proposed and verified with FE simulations [289,322]. Xing and Yong [323] investigated the viscoelastic effects of hMSMs in finite deformation and the instabilities they induce using a numerical model with a micro-mechanically motivated formulation.…”

Section: Microstructurally-guided Homogenization Modelsmentioning

confidence: 99%

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Hard magnetics and soft materials—a synergy

Narayanan,

Pramanik,

Arockiarajan

2024

Smart Mater. Struct.

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Hard-magnetic soft materials (hMSMs) are smart composites that consist of a mechanically soft polymer matrix impregnated with mechanically hard magnetic filler particles. This dual-phase composition renders them with exceptional magneto-mechanical properties that allow them to undergo large reversible deformations under the influence of external magnetic fields. Over the last decade, hMSMs have found extensive applications in soft robotics, adaptive structures, and biomedical devices. However, despite their widespread utility, they pose considerable challenges in fabrication and magneto-mechanical characterization owing to their multi-phase nature, miniature length scales, and nonlinear material behavior. Although noteworthy attempts have been made to understand their coupled nature, the rudimentary concepts of inter-phase interactions that give rise to their mechanical nonlinearity remain insufficiently understood, and this impedes their further advancements. This holistic review addresses these standalone concepts and bridges the gaps by providing a thorough examination of their myriad fabrication techniques, applications, and experimental, and modeling approaches. Specifically, the review presents a wide spectrum of fabrication techniques, ranging from traditional molding to cutting-edge four-dimensional (4D) printing, and their unbounded prospects in diverse fields of research. The review covers various modeling approaches, including continuum mechanical frameworks encompassing phenomenological and homogenization models, as well as microstructural models. Additionally, it addresses emerging techniques like machine learning-based modeling in the context of hMSMs. Finally, the expansive landscape of these promising material systems is provided for a better understanding and prospective research.

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Section: Microstructurally-guided Homogenization Modelsmentioning

confidence: 99%

“…The prevalent method in studying magneto-mechanical problems often assumes an ideal homogeneous magnetic field [272,289]. Yet, relying solely on this idealization might lead to significant disparities from observations in real setups.…”

Section: Importance Of Accounting For Magnetic Bcs and Surrounding Sp...mentioning

confidence: 99%

Hard magnetics and soft materials—a synergy

Narayanan,

Pramanik,

Arockiarajan

2024

Smart Mater. Struct.

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“…Their findings suggest that when modeling incompressible materials, the F-bar formulation can be computationally expensive, and the mixed displacementpotential formulation is somewhat sensitive to changes in the modulus. In the context of thin HMS materials, Dadgar-Rad and Hossain [329] developed a micro-based shell model for simulating their deformation. They extended the 7-degrees of freedom (DoF) formulation of Sansour [330] to a 10-DoF formulation scheme that accounted for the microrotation of the microstructure.…”

Section: Temperature Effectmentioning

confidence: 99%

“…In the context of thin HMS materials, Dadgar–Rad and Hossain [ 329 ] developed a micro‐based shell model for simulating their deformation. They extended the 7‐degrees of freedom (DoF) formulation of Sansour [ 330 ] to a 10‐DoF formulation scheme that accounted for the microrotation of the microstructure.…”

Section: Modeling Of Mresmentioning

confidence: 99%

The Modeling of Magnetorheological Elastomers: A State‐of‐the‐Art Review

Saber

2023

Adv Eng Mater

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The magnetorheological elastomers (MREs) are novel multifunctional materials wherein their viscoelastic properties can be varied instantly under an application of applied magnetic field. Due to their field‐dependent stiffness and damping properties, MREs are widely used in the development and design of MRE‐based adaptive vibration isolators and absorbers and also biomedical engineering. Moreover, MREs due to their inherent magnetostriction effect have enormous potential for the development of soft actuators. The dynamic behavior of MREs is affected by various material parameters (e.g., matrix and particle types, particle concentration, additives) as well as mechanical and magnetic loading parameters (e.g., frequency, amplitude, temperature, magnetic flux density). Understanding and predicting the effect of materials and loading parameters on the response behavior of MREs are of paramount importance for the design of MRE‐based adaptive structures and systems. This review paper mainly aims to provide a comprehensive study of material constitutive models to predict the nonlinear magnetomechanical behavior of MREs. Particular emphasis is paid to physics‐based models including continuum‐ and microstructure‐based models. Moreover, phenomenological models describing the dynamic magnetoviscoelastic behavior of MREs as well as the effect of temperature on the magnetomechanical behavior of such materials are properly addressed.

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“…Notably, Sun et al [12] have demonstrated that an augmentation in magnetic flux leads to smoother frequency response peaks, attributed to an amplified damping effect within the structure. Several other authors have investigated the viscoelastic modeling of MREs and their application [13][14][15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Flutter analysis of laminated fiber-reinforced magnetorheological elastomer sandwich plate resting on an elastic foundation using an improved first-order shear deformation theory

Aboutalebi,

Eshaghi

2024

Smart Mater. Struct.

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Magnetorheological elastomers (MREs) are polymers with viscoelastic properties that can be adjusted by manipulating the magnetic field. When MREs are combined with reinforcing fabrics, a new category of materials known as MRE Composites (MRECs) can be created, which not only possess the characteristics of MREs but also enhance their rigidity. This study focuses on investigating the supersonic aeroelastic instability of a rectangular sandwich plate with a laminated MREC core layer and functionally graded materials (FGMs) with porosities as face layers. Additionally, the sandwich plate is supported by an elastic foundation and subjected to supersonic airflow. This investigation presents an improved first-order shear deformation theory (FSDT), postulating a parabolic distribution of shear stresses. Consequently, the transverse shear stresses are rendered as zero at the surface of every individual layer; thus, the requirement for shear correction in this theory is eliminated. In addition, 8-node elements are implemented to circumvent the necessity for distinct handling of shear-locking. The aeroelastic pressure acting on the structure is considered using first-order piston theory. Micromechanical approaches, such as Halpin‐Tsai and rule of mixture approaches, are employed to determine the effective mechanical properties of the core and face layers. The dynamic equations of the structure are derived using Hamilton's principle and the finite element method (FEM). The study also examines the impact of different magnetic fields, fiber volume fraction, elastic foundation factors, layering angles, geometry, and boundary conditions on flutter frequency.

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A micropolar shell model for hard‐magnetic soft materials

Cited by 10 publications

References 82 publications

Hard magnetics and soft materials—a synergy

Hard magnetics and soft materials—a synergy

The Modeling of Magnetorheological Elastomers: A State‐of‐the‐Art Review

Flutter analysis of laminated fiber-reinforced magnetorheological elastomer sandwich plate resting on an elastic foundation using an improved first-order shear deformation theory

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