Investigation of the strain‐rate‐dependent mechanical behavior of a photopolymer matrix composite with fumed nano‐silica filler

Asif, Muhammad; Ramezani, Maziar; Khan, Kamran A.; Khan, Muhammad Ali; Aw, Kean C.

doi:10.1002/pen.25168

Cited by 7 publications

(5 citation statements)

References 52 publications

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“…The pristine (filler-free) Ecoflex material is a silicone elastomer that has been tested and modeled by several researchers, who have demonstrated that it exhibits predominantly hyperelastic behavior; which implies the material can be subject to a large deformation without significant internal energy dissipation. [18][19][20][21][22][23] In this research we have studied and explored viscous properties in addition to hyperelasticity, brought about by the addition of BTO filler particles to the Ecoflex, through a series of stress relaxation experiments.…”

Section: Introductionmentioning

confidence: 99%

The effect of barium titanate ceramic loading on the stress relaxation behavior of barium titanate‐silicone elastomer composites

Cholleti

Stringer

Kelly

et al. 2020

Polymer Engineering & Sci

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The stress relaxation behavior of barium titanate (BTO)‐elastomer (Ecoflex) composites, as used in large strain sensors, is studied using the generalized Maxwell‐Wiechert model. In this article, we examine the stress relaxation behavior of ceramic polymer composites by conducting stress relaxation tests on samples prepared with varying the particle loading by 0, 10, 20, 30, and 40 wt% of 100 and 200 nm BTO ceramic particles embedded in a Ecoflex silicone‐based hyperelastic elastomer. The influence of BTO on the Maxwell‐Wiechert model parameters was studied through the stress relaxation results. While a pristine Ecoflex silicone elastomer is predominantly a hyperelastic material, the addition of BTO made the composite behave as a visco‐hyperelastic material. However, this behavior was shown to have a negligible effect on the electrical sensing performance of the large strain sensor.

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Section: Introductionmentioning

confidence: 99%

The effect of barium titanate ceramic loading on the stress relaxation behavior of barium titanate‐silicone elastomer composites

Cholleti

Stringer

Kelly

et al. 2020

Polymer Engineering & Sci

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“…This finding might be because the synthesized nano‐silica was a rigid particle and could not deform, limiting the movement ability of the macromolecular chain and causing local stress concentration to a certain extent. [ 34 ] The brittleness of the composites was increased. Meanwhile, the interfacial interaction between EPDM and nano‐silica‐AP caused difficulty in stretching the matrix around the nano‐silica particles, resulting in higher strength and lower elongation.…”

Section: Resultsmentioning

confidence: 99%

Study on supercritical CO₂‐assisted modification of aramid pulp and properties of its reinforced EPDM composites

Kong

Qin³

et al. 2022

Polymer Engineering & Sci

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Aramid pulp (AP) is often used as a composite reinforcement due to its excellent properties, but poor dispersion and interfacial adhesion restrict its application in composite materials. In this work, tetraethyl orthosilicate (TEOS) was carried on the surface of AP by supercritical CO2 (scCO2) and hydrolyzed to synthesize the nano‐silica, which improves the dispersion of AP in ethylene‐propylene‐diene elastomer (EPDM). The nano‐silica particles were deposited on the AP surface, and th modified AP was evenly dispersed in the EPDM composites based on the SEM results. Moreover, a silane coupling agent (KH‐560) was brought by scCO2 to further modify the nano‐silica on the surface of the AP to improve the interfacial adhesion. Fourier transform infrared spectroscopy and X‐ray photoelectron spectroscopy results show that after KH‐560 modification, active epoxy groups were introduced on the surface of AP. The tensile strength and tear strength of the KH‐560‐nano‐silica‐AP/EPDM composites were significantly improved, reaching 8.98 and 42.06 MPa, which increased by 26% and 88.10%, respectively, compared with untreated‐AP/EPDM composites. Dynamic mechanical analysis shows that the storage modulus of KH‐560‐nano‐silica‐AP/EPDM composites increased to 2456 MPa compared with the pure EPDM for 1873 MPa, and the loss factor decreased. When the AP was modified in scCO2 with nano‐silica and KH‐560, the composites' oil resistance was also improved.

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“…To address these challenges, researchers have been exploring the potential of nanocomposites to enhance the performance of medical implants [4,5]. Nanocomposites are materials composed of nanoparticles or nanofillers dispersed in a matrix material, such as a polymer or metal [6]. These materials have unique properties that make them well suited for medical implant applications, including high strength, flexibility, and biocompatibility.…”

Section: Introductionmentioning

confidence: 99%

An Overview of Enhancing the Performance of Medical Implants with Nanocomposites

Ramezani

Ripin

2023

J. Compos. Sci.

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Medical implants are essential tools for treating chronic illnesses, restoring physical function, and improving the quality of life for millions of patients worldwide. However, implant failures due to infection, mechanical wear, corrosion, and tissue rejection continue to be a major challenge. Nanocomposites, composed of nanoparticles or nanofillers dispersed in a matrix material, have shown promising results in enhancing implant performance. This paper provides an overview of the current state of research on the use of nanocomposites for medical implants. We discuss the types of nanocomposites being developed, including polymer-, metal-, and ceramic-based materials, and their advantages/disadvantages for medical implant applications. Strategies for improving implant performance using nanocomposites, such as improving biocompatibility and mechanical properties and reducing wear and corrosion, are also examined. Challenges to the widespread use of nanocomposites in medical implants are discussed, such as biocompatibility, toxicity, long-term stability, standardisation, and quality control. Finally, we discuss future directions for research, including the use of advanced fabrication techniques and the development of novel nanocomposite materials. The use of nanocomposites in medical implants has the potential to improve patient outcomes and advance healthcare, but continued research and development will be required to overcome the challenges associated with their use.

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Investigation of the strain‐rate‐dependent mechanical behavior of a photopolymer matrix composite with fumed nano‐silica filler

Cited by 7 publications

References 52 publications

The effect of barium titanate ceramic loading on the stress relaxation behavior of barium titanate‐silicone elastomer composites

The effect of barium titanate ceramic loading on the stress relaxation behavior of barium titanate‐silicone elastomer composites

Study on supercritical CO₂‐assisted modification of aramid pulp and properties of its reinforced EPDM composites

An Overview of Enhancing the Performance of Medical Implants with Nanocomposites

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Investigation of the strain‐rate‐dependent mechanical behavior of a photopolymer matrix composite with fumed nano‐silica filler

Cited by 7 publications

References 52 publications

The effect of barium titanate ceramic loading on the stress relaxation behavior of barium titanate‐silicone elastomer composites

The effect of barium titanate ceramic loading on the stress relaxation behavior of barium titanate‐silicone elastomer composites

Study on supercritical CO2‐assisted modification of aramid pulp and properties of its reinforced EPDM composites

An Overview of Enhancing the Performance of Medical Implants with Nanocomposites

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Product

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Study on supercritical CO₂‐assisted modification of aramid pulp and properties of its reinforced EPDM composites