Wet‐spinning and carbonization of graphene/PAN‐based fibers: Toward improving the properties of carbon fibers

Sayyar, Sepidar; Moskowitz, Jeremy D.; Fox, Bronwyn; Wiggins, Jeffrey S.; Wallace, Gordon G.

doi:10.1002/app.47932

Cited by 15 publications

(12 citation statements)

References 67 publications

(74 reference statements)

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“…Current methods of preparing fibers mainly include melt spinning,14 wet spinning,15,16 and electrospinning 17–19. However, the presence of high temperatures and volatile solvents in the melt spinning and electrospinning processes limits the encapsulation of cells, microtissues, and other bioactive molecules in fibers 20.…”

Section: Introductionmentioning

confidence: 99%

Simple Fabrication of Multicomponent Heterogeneous Fibers for Cell Co‐Culture via Microfluidic Spinning

Yao

et al. 2020

Macromolecular Bioscience

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Microfluidic spinning, as a combination of wet spinning and microfluidic technology, has been used to develop microfibers with special structures to facilitate cell 3D culture/co‐culture and microtissue formation in vitro. In this study, a simple microchip‐based microfluidic spinning strategy is presented for the fabrication of multicomponent heterogeneous calcium alginate microfibers. The use of two kinds of microchip enables the one‐step preparation of multicomponent heterogeneous microfibers with various arrangement patterns, including the preparation of one‐, two‐, and three‐component microfibers by a two‐layer microchip and preparation of four component microfibers with different arrangement by a membrane‐sandwiched three‐layer microchip. The obtained microfibers could be used to encapsulate various kinds of cells, such as the human non‐small cell lung cancer cell NCI‐H1650, the human fetal lung fibroblast HFL1, the normal pulmonary bronchial epithelial cell 16HBE, and human umbilical vein endothelial cells. By adding chitosan to the medium to keep the fibers stable, 3D long‐term in vitro cell co‐culture has been carried out up to 21 days. This method is very simple and easy to operate, continuously produces spatially well‐defined heterogeneous microfibers, has important applications for composite functional biomaterials, and shows great potential in organs‐on‐a‐chip and biomimetic systems.

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Section: Introductionmentioning

confidence: 99%

Simple Fabrication of Multicomponent Heterogeneous Fibers for Cell Co‐Culture via Microfluidic Spinning

Yao

et al. 2020

Macromolecular Bioscience

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“…The comparable mechanical performance of the high-loading composite precursor to the raw PAN fiber provides a potential for manufacturing biomass-derived carbon fibers. [114], copyright 2015 American Chemical Society).…”

Section: Functional Additivesmentioning

confidence: 99%

“…Cellulose nanomaterials with high tensile strength (7.5 GPa) and modulus (110–220 GPa) have been applied as low-cost and biobased alternative reinforcements [ 114 , 115 ]. By compositing cellulose nanocrystal to the PAN matrix up to 10 wt%, Young’s modulus of the precursor fibers was increased from 14.5 to 19.6 GPa according to the rule of mixture ( Figure 13 ), and the tensile strength improved from 624 to 709 MPa owing to the microstructural changes, such as better chain alignment and crystallinity increases from 50 to 62% [ 114 ]. It was confirmed that the cellulose nanocrystal reinforcements also contributed to the advancement of the mechanical performance of carbon fibers [ 115 , 116 ].…”

Section: Functional Additivesmentioning

confidence: 99%

“…It was confirmed that the cellulose nanocrystal reinforcements also contributed to the advancement of the mechanical performance of carbon fibers [ 115 , 116 ]. In fact, the main purpose of the search for biomass additives, such as cellulose, lignin, and alpaca fiber, is eco-friendliness and cost effectiveness [ 114 , 117 , 118 , 119 , 120 , 121 , 122 , 123 , 124 ]. It is inevitable to avoid deterioration of the mechanical performance following the composition with the biomass-derived additives owing to the low carbon atomic content and ineffective molecular structure that is intended to be carbonized.…”

Section: Functional Additivesmentioning

confidence: 99%

“… Young’s modulus change as the cellulose nanocrystal (CNC) content increased. Insets are SEM images of fracture surface of fibers of PAN and PAN/CNC 10 wt% (reprinted with permission from [ 114 ], copyright 2015 American Chemical Society). …”

Section: Figurementioning

confidence: 99%

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Designing Materials and Processes for Strong Polyacrylonitrile Precursor Fibers

2021

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Although polyacrylonitrile (PAN)-based carbon fibers have been successfully commercialized owing to their excellent material properties, their actual mechanical performance is still much lower than the theoretical values. Meanwhile, there is a growing demand for the use of superior carbon fibers. As such, many studies have been conducted to improve the mechanical performance of carbon fibers. Among the various approaches, designing a strong precursor fiber with a well-developed microstructure and morphology can constitute the most effective strategy to achieve superior performance. In this review, the efforts used to modulate materials, processing, and additives to deliver strong precursor fibers were thoroughly investigated. Our work demonstrates that the design of materials and processes is a fruitful pathway for the enhancement of the mechanical performance of carbon fibers.

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Trithiocarbonates in RAFT Polymerization

Moad¹

2021

RAFT Polymerization

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Wet‐spinning and carbonization of graphene/PAN‐based fibers: Toward improving the properties of carbon fibers

Cited by 15 publications

References 67 publications

Simple Fabrication of Multicomponent Heterogeneous Fibers for Cell Co‐Culture via Microfluidic Spinning

Simple Fabrication of Multicomponent Heterogeneous Fibers for Cell Co‐Culture via Microfluidic Spinning

Designing Materials and Processes for Strong Polyacrylonitrile Precursor Fibers

Trithiocarbonates in RAFT Polymerization

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