Capillary Effects in Fiber Reinforced Polymer Composite Processing: A Review

Teixidó, Helena; Staal, Jeroen; Caglar, Baris; Michaud, Véronique

doi:10.3389/fmats.2022.809226

Cited by 18 publications

(13 citation statements)

References 227 publications

(341 reference statements)

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“…The fluorescence lifetime (435 nm) of the CNDs was monitored, and the corresponding lifetime was about 1.69 ns, as shown in Figure 1c. When we wrote using the CND aqueous solution as ink, the ink was absorbed by the paper through the capillarity of paper fibers, 36,37 and multiple hydrogen bonds were thus formed after drying, as illustrated in Figure 1d. The strong confinement of the formed hydrogen bonds can activate triplet excitons of the CNDs; thus, the written word "spider" showed a lasting phosphorescence after ceasing excitation (Figure S2).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Paper-Fiber-Activated Triplet Excitons of Carbon Nanodots for Time-Resolved Anti-counterfeiting Signature with Artificial Intelligence Authentication

Mao

Liu

Cao

et al. 2023

ACS Appl. Mater. Interfaces

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The easy-to-imitate character of a personal signature may cause significant economy loss due to the lack of speed and strength information. In this work, we report a time-resolved anti-counterfeiting signature strategy with artificial intelligence (AI) authentication based on the designed luminescent carbon nanodot (CND) ink, whose triplet excitons can be activated by the bonding between the paper fibers and the CNDs. Paper fibers can bond with the CNDs through multiple hydrogen bonds, and the activated triplet excitons release photons for about 13 s; thus, the speed and strength of the signature are recorded through recording the changes in luminescence intensity over time. The background noise from commercial paper fluorescence is completely suppressed, benefiting from the long phosphorescence lifetime of the CNDs. In addition, a reliable AI authentication method with quick response based on a convolutional neural network is developed, and 100% identification accuracy of the signature based on the CND ink is achieved, which is higher than that of the signature with commercial ink (78%). This strategy can also be expanded for painting, calligraphy identification.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Paper-Fiber-Activated Triplet Excitons of Carbon Nanodots for Time-Resolved Anti-counterfeiting Signature with Artificial Intelligence Authentication

Mao

Liu

Cao

et al. 2023

ACS Appl. Mater. Interfaces

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“…It is evident from Figure 6 and Table 4 that cotton fabrics that are not coated exhibit wicking behaviour and have a wicking height of 8 cm ± 1 cm. This might be caused by the capillaries that exist within the structure of the yarn (intra-yarn spaces) and between the yarns (inter-yarn spaces) [48,49]. Conversely, the cotton fabric treated with silica sol, chitosan and HDTMS displayed zero evidence of wicking.…”

Section: Resultsmentioning

confidence: 99%

Study on the Hydrophobicity and Antibacterial Activity of Silica Sol-Chitosan-HDTMS Treated Cotton Fabric Dipped in an Aquas Media

Das

Roy

Ghosh

2023

TEKS

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A hydrophobic surface with an antibacterial property has numerous uses, including self-cleaning, anti-sticking, anti-contamination, sports apparel, and wound healing/implant materials. The durability of the coating in an aquas media (pH 7.4) is a vital requirement for use in technical textile sectors, particularly in medical applications. In this study, we used silica sol, chitosan and hexadecyltrimethoxysilane (HDTMS) to create exceptionally hydrophobic surfaces with antibacterial properties on cotton fabrics. First, cotton fabric was treated with silica sol, which was produced by the hydrolysis and condensation of tetraethoxysilane (TEOS) in an alkaline environment. After that, chitosan was applied on the silica sol-treated fabric to add an antibacterial characteristic. The silica sol-chitosan-treated fabric was then given a hydrolysed HDTMS treatment to give a highly hydrophobic property. The hydrophobicity was assessed by measuring the water contact angle, while the AATCC-147 test protocol was used to assess the antibacterial property. The developed fabric exhibited a strong hydrophobic property. The fabric samples were immersed in an aquas media for 30 days to assess the coating durability by observing changes in hydrophobicity and anti-bacterial activity in terms of the zone of inhibition (ZOI). After 30 days of immersion in the aquas media, it was observed that the contact angle decreased from 151.7° to 129.5°, and the ZOI increased from 1 mm to 5 mm, which indicates an increase in anti-bacterial activity in relation to time of immersion. The wicking characteristics of coated and uncoated fabrics were also measured to determine how coating affects the wicking behaviour of fabric. EDS was performed to observe the coating stability for coated-dipped fabric samples after 30 days. SEM analysis was performed to examine the surface morphology, while FTIR was used to determine the surface functional groups after coating and changes after dipping in the aquas media. The developed hydrophobic cotton fabrics with anti-bacterial properties may help in the fabrication of natural biomaterials and other technical textile products.

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“…As X-Ray Computed tomography became more readily available in the recent years, 3D imaging of an RVE is now becoming routinely accessible, leading to precise geometrical descriptions of the porous medium, including the presence of non-connected pores ( [10][11][12][13][14][15]). As mentioned, textiles are most often formed of tows or yarns that are assembled into a preform, the porous medium is thus generally described by a bi-modal pore size distribution, as illustrated in Figure 1, and the dual scale nature of the pore size distribution can lead to exacerbated capillary/hydrodynamic effects, as compared to more uniform porous media such as encountered in soil science [16,17]. The underlying physical phenomena for LCM processes include capillary or surface phenomena, transport of fluid, heat, and mass, the mechanics of preform deformation before and during infiltration, matrix chemical cross-linking, and potential matrix/reinforcement chemical reaction during and after the process.…”

Section: Liquid Composite Molding Principlesmentioning

confidence: 99%

“…The underlying physical phenomena for LCM processes include capillary or surface phenomena, transport of fluid, heat, and mass, the mechanics of preform deformation before and during infiltration, matrix chemical cross-linking, and potential matrix/reinforcement chemical reaction during and after the process. For a complete description, the reader is referred to recent reviews [17,19]. In the following, for the sake of simplicity, we consider the general case of infiltration by a liquid of a rigid porous preform (constant volume fraction) in which all initial porosity is interconnected (no closed pores).…”

Section: Liquid Composite Molding Principlesmentioning

confidence: 99%

LCM of thermoset-based fiber reinforced composites for large-scale applications: are process kinetics and structural properties antagonistic?

Michaud

2023

IOP Conf. Ser.: Mater. Sci. Eng.

Self Cite

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This article reviews the main methods to manufacture large-scale composite parts, with a focus on Liquid Composite Molding techniques of thermoset-based fiber reinforced structural parts. As this process relies on the impregnation of a dry textile stack, this manufacturing step is crucial in terms of part production rate, and part quality. To increase the process kinetics, a large effort has been devoted to increase the permeability of the textile preforms, while keeping a similar fiber content. An increase of almost two orders of magnitude can be attained if the textile shows a strong separation of scales between densely packed tows and large intra-two spaces. This however leads to a potential degradation in the resulting structural properties, particularly in dynamic mode due to the presence of the resin rich pockets. Alternative solutions emerge, which may help reach a cost-effective compromise.

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Capillary Effects in Fiber Reinforced Polymer Composite Processing: A Review

Cited by 18 publications

References 227 publications

Paper-Fiber-Activated Triplet Excitons of Carbon Nanodots for Time-Resolved Anti-counterfeiting Signature with Artificial Intelligence Authentication

Paper-Fiber-Activated Triplet Excitons of Carbon Nanodots for Time-Resolved Anti-counterfeiting Signature with Artificial Intelligence Authentication

Study on the Hydrophobicity and Antibacterial Activity of Silica Sol-Chitosan-HDTMS Treated Cotton Fabric Dipped in an Aquas Media

LCM of thermoset-based fiber reinforced composites for large-scale applications: are process kinetics and structural properties antagonistic?

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