Layer-By-Layer Self-Assembled Dip Coating for Antifouling Functionalized Finishing of Cotton Textile

Javaid, Sana; Mahmood, Azhar; Nasir, Habib; Iqbal, Mudassir; Ahmed, Naveed; Ahmad, Naveed

doi:10.3390/polym14132540

Cited by 12 publications

(6 citation statements)

References 54 publications

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“…For drying films, spherical droplets, and cylindrical droplets, this condition can be satisfied and the systems can be modeled with the moving interface method. Examples include a liquid film generated by dip coating [ 73 ], respiratory droplets suspended in air [ 17 ], solution droplets created by a spray drying process [ 74 ], and a polymer fiber during electrospinning [ 75 ]. However, for systems in which the solvent develops flow patterns during drying, the moving interface method cannot be directly employed.…”

Section: Summary and Discussionmentioning

confidence: 99%

Modeling Solution Drying by Moving a Liquid-Vapor Interface: Method and Applications

et al. 2022

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A method of simulating the drying process of a soft matter solution with an implicit solvent model by moving the liquid-vapor interface is applied to various solution films and droplets. For a solution of a polymer and nanoparticles, we observe “polymer-on-top” stratification, similar to that found previously with an explicit solvent model. Furthermore, “polymer-on-top” is found even when the nanoparticle size is smaller than the radius of gyration of the polymer chains. For a suspension droplet of a bidisperse mixture of nanoparticles, we show that core-shell clusters of nanoparticles can be obtained via the “small-on-outside” stratification mechanism at fast evaporation rates. “Large-on-outside” stratification and uniform particle distribution are also observed when the evaporation rate is reduced. Polymeric particles with various morphologies, including Janus spheres, core-shell particles, and patchy particles, are produced from drying droplets of polymer solutions by combining fast evaporation with a controlled interaction between the polymers and the liquid-vapor interface. Our results validate the applicability of the moving interface method to a wide range of drying systems. The limitations of the method are pointed out and cautions are provided to potential practitioners on cases where the method might fail.

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Section: Summary and Discussionmentioning

confidence: 99%

Modeling Solution Drying by Moving a Liquid-Vapor Interface: Method and Applications

et al. 2022

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“…Textile functionalization with antifouling chemicals has enabled several biomedical uses, including bandages, wound treatment, artificial sutures, body implants, and tissue scaffolding. Nano-emulsion enhances textiles by immobilizing polymeric nanoparticles on their surface by encapsulating active substances [34].…”

Section: Polymeric Nano-emulsion In Antimicrobial Textile Finishingmentioning

confidence: 99%

Polymeric Nano-Emulsion in Functional Textile Finishing

Javaid,

Saleem,

Ur Rehman

2024

Nanoemulsions - Design and Applications [Working Title]

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Advancement in nanotechnology brings a revolutionary change in the field of textile finishing. Textile finishing is a chemical or a mechanical process to impart functional properties to the textile to provide comfort for wearer. Today’s textile manufacturers focus on the manufacture of smart and functional textiles that are equipped with antifouling, anti-wrinkle, crease-resistant, water-repellent, flame-retardant, and soil-repellent properties for consumers’ safety and well-being. A wide variety of functional chemical finishes are available in the market to meet the ongoing challenges in the textile sector. Nano-emulsions significantly contribute to a wide variety of functional finishes to provide advanced hi-tech applications for present and future textile consumers. Both natural and synthetic polymers have been utilized for the synthesis of functional finishes by employing polymeric nano-emulsions on cotton, wool polyester fiber as well as textile. Thus, nano-emulsions provide an inherent property to textile and stimulate the economic growth of functional textile market.

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“…LBL films constructed using two phases with differing impedances may trigger significant internal scattering at the internal interfaces. Spin coating [73], spray coating [74], dip coating [75], solution casting [76], and interfacial assembly are common solution processing methods used to build LBL structures [77]. The hydrophilic surfaces of exfoliated MXene sheets allow for the preparation of steady dispersions in aqueous and organic solvents, allowing solution treatment of a variety of nanostructures and polymers [78].…”

Section: Layer-by-layer (Lbl)-structured Mxene Filmmentioning

confidence: 99%

Diverse Structural Design Strategies of MXene-Based Macrostructure for High-Performance Electromagnetic Interference Shielding

Liu,

Wang,

et al. 2023

Nano-Micro Lett.

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There is an urgent demand for flexible, lightweight, mechanically robust, excellent electromagnetic interference (EMI) shielding materials. Two-dimensional (2D) transition metal carbides/nitrides (MXenes) have been potential candidates for the construction of excellent EMI shielding materials due to their great electrical electroconductibility, favorable mechanical nature such as flexibility, large aspect ratios, and simple processability in aqueous media. The applicability of MXenes for EMI shielding has been intensively explored; thus, reviewing the relevant research is beneficial for advancing the design of high-performance MXene-based EMI shields. Herein, recent progress in MXene-based macrostructure development is reviewed, including the associated EMI shielding mechanisms. In particular, various structural design strategies for MXene-based EMI shielding materials are highlighted and explored. In the end, the difficulties and views for the future growth of MXene-based EMI shields are proposed. This review aims to drive the growth of high-performance MXene-based EMI shielding macrostructures on basis of rational structural design and the future high-efficiency utilization of MXene.

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Layer-By-Layer Self-Assembled Dip Coating for Antifouling Functionalized Finishing of Cotton Textile

Cited by 12 publications

References 54 publications

Modeling Solution Drying by Moving a Liquid-Vapor Interface: Method and Applications

Modeling Solution Drying by Moving a Liquid-Vapor Interface: Method and Applications

Polymeric Nano-Emulsion in Functional Textile Finishing

Diverse Structural Design Strategies of MXene-Based Macrostructure for High-Performance Electromagnetic Interference Shielding

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