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1. Sub-microscale speckle pattern creation on single carbon fibers for scanning electron microscope-digital image correlation (SEM-DIC) experiments

   Shah, Karan ; Sockalingam, Subramani ; O'Brien, Hannah ; El Loubani, Mohammad ; Lee, Dongkyu ; Sutton, Michael ( November 2022 , Composites Part A Applied science and manufacturing)

   High performance carbon fibers are widely used as fiber reinforcements in composite material systems for aerospace, automotive, and defense applications. Longitudinal tensile failure of such composite systems is a result of clustering of single fiber tensile failures occurring at the microscale, on the order of a few microns to a few hundred microns. Since fiber tensile strength at the microscale has a first order effect on composite strength, it is important to characterize the strength of single fibers at microscale gage lengths which is extremely challenging. An experimental technique based on a combination of transverse loading of single fibers under SEM with DIC is a potential approach to access microscale gage lengths. The SEM-DIC technique requires creation of uniform, random, and contrastive sub-microscale speckle pattern on the curved fiber surface for accurate strain measurements. In this paper, we investigate the formation of such sub-microscale speckle patterns on individual sized IM7 carbon fibers of nominal diameter 5.2 µm via sputter coating. Various process conditions such as working pressure, sputtering current, and coating duration are investigated for pattern creation on fiber surface using a gold-palladium (Au-Pd) target. A nanocluster type sub-microscale pattern is obtained on the fiber surface for different coating conditions. Numerical translation experiments are performed using the obtained patterns to study image correlation and identify a suitable pattern for SEM-DIC experiments. The pattern obtained at a working pressure of 120–140 mTorr with 50 mA current for a duration of 10 min is found to have an average speckle size of 53 nm and good contrast for image correlation. Rigid body translation SEM experiments for drift/distortion correction using a sized IM7 carbon fiber coated with the best patterning conditions showed that Stereo-SEM-DIC is needed for accurately characterizing fiber strain fields due to its curved surface. The effect of sputter coating on fiber tensile strength and strain is investigated via single fiber tensile tests. Results showed that there is no significant difference in the mean tensile strength and failure strain between uncoated and coated fibers (average increment in fiber diameter of ∼221 nm due to coating) at 5% significance level. SEM images of failure surfaces for uncoated and coated fibers also confirmed a tensile failure of fibers as observed for polyacrylonitrile PAN-based fibers in literature. 

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2. Measurement of Intrinsic Residual Stresses in 3D Woven Composites Using Measurement of the Displacement Fields from Hole Drilling by Electronic Speckle Pattern Interferometry and Digital Image Correlation

   https://doi.org/10.12783/asc33/26127  

   GROSS, TODD ; BUNTROCK, HILARY ; TSUKROV, IGOR ; DRACH, BORYS ; VASYLEVSKYI, KOSTIANTYN ; CHAGNON, NICHOLAS ( November 2018 , Measurement of Intrinsic Residual Stresses in 3D Woven Composites Using Measurement of the Displacement Fields from Hole Drilling by Electronic Speckle Pattern Interferometry and Digital Image Correlation)

   Intrinsic residual stresses in woven composites result from the coefficient of thermal expansion mismatch between the fibers and the matrix. Extrinsic residual stresses result from large scale thermal gradients during curing and cooling. Intrinsic residual stresses in 3D woven composites are sometimes severe enough to cause micro-cracking in the matrix. They are also expected to impact the fatigue resistance and the impact resistance. To the best of our knowledge, there have been no spatially resolved measurements of the intrinsic residual stress field as a function of position in the repeating weave pattern. We used digital image correlation (DIC) and electronic speckle pattern interferometry (ESPI) to measure the surface displacement field resulting from drilling a 1 mm diameter hole at four selected locations in two different 3D woven composite architectures that represent low and high through-the-thickness constraint. The two methods are used because the displacements sometimes on the lower end of the resolution for the DIC method and the displacement gradients are sometimes too steep to resolve the fringes for the ESPI method. Finite element models constructed with realistic fiber geometry using Dynamic Fabric Mechanic Analyzer software were utilized to estimate the residual stress field from cooling from the curing temperature. Holes were manually inserted by deactivating the elements in the hole region and the resultant displacement fields were compared to the measurements. In general, the measured displacement fields were lower in magnitude than the model predictions. In some cases, the sign of the predicted displacement field is opposite to the observed field which could be attributed to differences between the actual hole location and the hole in the model. 

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3. Etching anisotropic surface topography onto fibrin microthread scaffolds for guiding myoblast alignment

   https://doi.org/10.1002/jbm.b.34566  

   Carnes, Meagan E. ; Pins, George D. ( January 2020 , Journal of Biomedical Materials Research Part B: Applied Biomaterials)

   To regenerate functional muscle tissue, engineered scaffolds should impart topographical features to induce myoblast alignment by a phenomenon known as contact guidance. Myoblast alignment is an essential step towards myotube formation, which is guidedin vivoby extracellular matrix structure and micron‐scale grooves between adjacent muscle fibers. Fibrin microthread scaffolds mimic the morphological architecture of native muscle tissue and have demonstrated promise as an implantable scaffold for treating skeletal muscle injuries. While these scaffolds promote modest myoblast alignment, it is not sufficient to generate highly functional muscle tissue. The goal of this study is to develop and characterize a new method of etching the surface of fibrin microthreads to incorporate aligned, sub‐micron grooves that promote myoblast alignment. To generate these topographic features, we placed fibrin microthreads into 2‐(N‐morpholino)ethane‐sulfonic acid (MES) acidic buffer and evaluated the effect of buffer pH on the generation of these features. Surface characterization with atomic force microscopy and scanning electron microscopy indicated the generation of aligned, sub‐micron sized grooves on microthreads in MES buffer with pH 5.0. Microthreads etched with surface features had tensile mechanical properties comparable to controls, indicating that the surface treatment does not inhibit scaffold bulk properties. Our data demonstrate that etching threads in MES buffer with pH 5.0 enhanced alignment and filamentous actin stress fiber organization of myoblasts on the surface of scaffolds. The ability to tune topographic features on the surfaces of scaffolds independent of mechanical properties provides a valuable tool for designing microthread‐based scaffolds to enhance regeneration of functional muscle tissue.

    

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4. Fabrication of Light‐Weight and Highly Conductive Copper–Carbon Nanotube Core–Shell Fibers Through Interface Design

   https://doi.org/10.1002/admi.202000779  

   Daneshvar, Farhad ; Chen, Hengxi ; Zhang, Tan ; Sue, Hung‐Jue ( August 2020 , Advanced Materials Interfaces)

   Metal‐carbon nanotube (CNT) hybrid fibers are emerging materials for light‐weight conductors that can replace common metallic conductors. One of the main challenges to their development is the poor affinity between CNT and metals. In this work, a new approach for fabrication of CNT/Cu core‐shell fibers is demonstrated that outperforms the commercial Cu wires in terms of specific conductivity, ampacity, and strength. By introducing thiol groups to the surface of CNT fibers, a dense Cu coating with enhanced adhesion is obtained. Consequently, CNT/Cu core‐shell fibers with specific conductivity of 3.6 × 10⁷S m⁻¹and tensile strength of 1 GPa, which is almost five times higher than commercial Cu wires, are produced. Due to strong interaction of thiol functional groups and Cu atoms, the fiber can preserve its integrity and conductivity after >500 fatigue bending cycles. Furthermore, the ampacity of the composite wire reaches to 1.04 × 10⁵A cm⁻², which corresponds to a specific ampacity two times higher than that of commercial Cu wires. The interfacial design between Cu and CNT presented here is versatile and can be implemented in other processing and deposition methods.

    

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5. Effect of the spin‐line temperature profile on the mechanical properties of melt electrospun polyethylene fibers

   https://doi.org/10.1002/app.50668  

   Shabani, Elnaz ; Gorga, Russell E. ( March 2021 , Journal of Applied Polymer Science)

   The covid‐19 pandemic has revealed the need for alternative production approaches with low startup costs like electrospinning for filter needs, the most imperative element of the personal protective equipment (PPE). Current attempts in advancing melt electrospinning deal with developing strategies for fiber diameter attenuation toward sub‐micron scale. Here, the attunement in the spinning‐zone temperature known as ''spin‐line temperature profile'' was utilized as a baseline for fiber diameter reduction. The mechanical performance of the melt‐electrospun linear low‐density polyethylene (LLDPE) fibers is reported to characterize their structural transformation with respect to various spin‐line temperature profiles. With an increase in the spin‐line temperature to above 100°C in the area of cone formation, an increased tensile and yield strength along with fiber diameter reduction by four‐folds was demonstrated. A significant increase in toughness, by almost three times, without compromising the stiffness and Young's modulus was observed. The dynamic mechanical analysis revealed that spinning in high temperatures produces changes in the alpha (α) relaxation, contributing to the significant increase in strain at break. These results are significant because polyolefin fibers are an imperative element of medical textiles and PPE. Therefore, developing a correlation for process‐structure‐properties for emerging production techniques like melt electrospinning becomes critical.

    

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