Effect of interfiber bonding on the rupture of electrospun fibrous mats

Chavoshnejad, Poorya; Alsmairat, Ohood; Ke, Changhong; Razavi, Mir Jalil

doi:10.1088/1361-6463/abba95

Cited by 15 publications

(11 citation statements)

References 84 publications

(101 reference statements)

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“…45 It shows that fiber strength is typically determined by the strength of the lateral bond between the molecules. A similar observation is also reported by Chavoshnehad et al 46 and Negi et al 47 on the failure mode of electrospun non-woven fiber mat during tensile loading on account of slippage or displacement of fibers between welded (fused) and unbonded fibers. It was suggested that, compared to the van der Waals interaction between nearby chains, the covalent connections along the polymer molecular chains support better energy transmission.…”

Section: Fractographic Analysissupporting

confidence: 87%

Enhancement of electrospun UHMWPE fiber performance through post‐processing treatment

Nayak

Ghosh

Bhatnagar

2023

J of Applied Polymer Sci

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In this study, the mechanical performance of electrospun ultra-high molecular weight polyethylene (UHMWPE) fiber was successfully improved by postprocessing treatment. It is performed by stretching the electrospun UHMWPE mat under constant load at temperatures ranging from 90 to 150 C. The temperature is varied in order to achieve the highest possible draw ratio. The prepared fibers were characterized for their morphological and thermal properties. Moreover, the induced fiber morphology and their performance due to the effect of high-temperature stretching were evaluated using different characterization techniques such as scanning electron microscopy, wide-angle X-ray diffraction, and tensile testing analysis. In addition, the characteristics of prepared yarns were also compared with a commercial grade of Spectra ® fibers. This analysis shows that the post-processing of the mat resulted in the production of axially elongated microfibrillar yarn. Maximum tensile strength of 11.14 ± 3.65 GPa was attained at a stretching temperature of 130 C. However, further raising the temperature causes a decline in performance, demonstrating that the stretching temperature dramatically influences the properties of the fiber.

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Section: Fractographic Analysissupporting

confidence: 87%

Enhancement of electrospun UHMWPE fiber performance through post‐processing treatment

Nayak

Ghosh

Bhatnagar

2023

J of Applied Polymer Sci

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“…It is expected the latter can promote solution’s movement from one side to the other side of the substrate during coating, which leads to more contact between solution and wire’s surface, resulting in more uniform coverage. The topography of the coating surface for mesh size 200 (smaller wire diameter) is smoother than mesh size 100 due to the overall flatter pattern: reduced wire bending at the junctions and smaller distance between wire peaks and valleys. , …”

Section: Resultsmentioning

confidence: 99%

“…The topography of the coating surface for mesh size 200 (smaller wire diameter) is smoother than mesh size 100 due to the overall flatter pattern: reduced wire bending at the junctions and smaller distance between wire peaks and valleys. 39,40 3.2.3. Coating Thickness.…”

Section: Effect Of Mesh Sizementioning

confidence: 99%

Improved Biocompatible, Flexible Mesh Composites for Implant Applications via Hydroxyapatite Coating with Potential for 3-Dimensional Extracellular Matrix Network and Bone Regeneration

Naderi

Zhang

Belgodere

et al. 2021

ACS Appl. Mater. Interfaces

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Hydroxyapatite (HA)-coated metals are biocompatible composites, which have potential for various applications for bone replacement and regeneration in the human body. In this study, we proposed the design of biocompatible, flexible composite implants by using a metal mesh as substrate and HA coating as bone regenerative stimulant derived from a simple sol–gel method. Experiments were performed to understand the effect of coating method (dip-coating and drop casting), substrate material (titanium and stainless steel) and substrate mesh characteristics (mesh size, weave pattern) on implant’s performance. HA-coated samples were characterized by X-ray diffractometer, transmission electron microscope, field-emission scanning electron microscope, nanoindenter, polarization and electrochemical impedance spectroscopy, and biocompatibility test. Pure or biphasic nanorod HA coating was obtained on mesh substrates with thicknesses varying from 4.0 to 7.9 μm. Different coating procedures and number of layers did not affect crystal structure, shape, or most intense plane reflections of the HA coating. Moduli of elasticity below 18.5 GPa were reported for HA-coated samples, falling within the range of natural skull bone. Coated samples led to at least 90% cell viability and up to 99.5% extracellular matrix coverage into a 3-dimensional network (16.4% to 76.5% higher than bare substrates). Fluorescent imaging showed no antagonistic effect of the coatings on osteogenic differentiation. Finer mesh size enhanced coating coverage and adhesion, but a low number of HA layers was preferable to maintain open mesh areas promoting extracellular matrix formation. Finally, electrochemical behavior studies revealed that, although corrosion protection for HA-coated samples was generally higher than bare samples, galvanic corrosion occurred on some samples. Overall, the results indicated that while HA-coated titanium grade 1 showed the best performance as a potential implant, HA-coated stainless steel 316 with the finest mesh size constitutes an adequate, lower cost alternative.

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“…In recent decades, employing polymers in various applications such as protective coatings, aerospace industry, filtration, biomembrane has increased dramatically. [1][2][3] Among different polymers, excellent properties of epoxy resins, like good mechanical and adhesion performance, dielectric properties, and high corrosion resistance, have made them ideal for the protective coatings' matrix. However, together with the broad advantages of epoxy materials, high flammability, poor thermal stability, and low impact strength have restricted their applications as coatings.…”

Section: Introductionmentioning

confidence: 99%

Mechanical properties of an epoxy-based coating reinforced with silica aerogel and ammonium polyphosphate additives

Riahipour

Nemati

Zadehmohamad

et al. 2022

Polymers and Polymer Composites

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Flame retardant (FR) additives may degrade polymers’ mechanical performance. In this work, FR epoxy composites fabricated based on two popular FR agents of ammonium polyphosphate (APP) and silica aerogel (SAG) are investigated. Several mechanical properties of these composites, including compressive, micro-hardness, and Izod impact, were investigated for different filler loadings. Although the addition of 10 vol.% APP improved compressive modulus, yield strength, and micro-hardness, it degraded the impact strength. The incorporation of SAG made the composites more ductile, improved the impact strength, but deteriorated their compressive properties. Samples containing both SAG and APP demonstrated synergetic effects evident by their enhanced compressive properties and hardness. The findings of this study can guide the design of epoxies with both exceptional FR and mechanical performance.

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Effect of interfiber bonding on the rupture of electrospun fibrous mats

Cited by 15 publications

References 84 publications

Enhancement of electrospun UHMWPE fiber performance through post‐processing treatment

Enhancement of electrospun UHMWPE fiber performance through post‐processing treatment

Improved Biocompatible, Flexible Mesh Composites for Implant Applications via Hydroxyapatite Coating with Potential for 3-Dimensional Extracellular Matrix Network and Bone Regeneration

Mechanical properties of an epoxy-based coating reinforced with silica aerogel and ammonium polyphosphate additives

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