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The development of materials from industrial wastes has attracted the attention of the research community for years. A material's physico-chemical characteristics have specific impacts its properties and their application in environmental, energetic, and biomedical areas, such as in pollutant removal; CO2 capture; energy storage; catalytic oxidation and reduction processes; the conversion of biomass to biofuels; and drug delivery. Examples of such materials are activated carbons, clays, and zeolites, among others. The aim of this Special Issue is to collect the recent advances and progresses developed in this field considering valorised materials from industrial wastes and their applications in environmental, energetic, and biomedical areas.
Technology: general issues --- History of engineering & technology --- biomass gasification --- agricultural residues --- cogeneration plant --- life cycle assessment --- environmental impact --- greenhouse gas --- kinetics --- polyolefins --- aerobic biodegradation --- waste plastic materials --- biodegradation of plastic --- standard plastic testing --- gas explosion --- equivalent stoichiometric cloud --- Q9 --- explosion risk assessment --- model evaluation --- precoat layer --- precoat filtration --- cellulose fibres --- filter aids --- backwash filtration --- filter regeneration --- filter media resistance --- filter cake resistance --- turbidity --- particle layer --- LNG vapour --- dispersion --- hazard distances --- CFD --- topography --- phase change --- cold venting --- municipal solid waste --- SWDS --- composting process --- DOC --- IPCC guidelines --- GHG emissions --- wastewater treatment --- natural clays --- emerging contaminants --- zeolite --- bentonite --- Daphnia magna --- adsorption --- copper --- ion exchange --- thiourea --- X-ray photoelectron spectroscopy (XPS) --- reductive extraction --- resource recovery --- n/a
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Developments in the science and technology of textiles are not only limited to apparel and fashion. Certainly, there are research efforts aimed at improving the construction and processing of textiles for clothing—such as studies on cleaner production to reduce environmental impact, increasing the utilization of fibers and process chemicals from renewable resources, and on the recycling of materials from post-consumer waste apparel back into the manufacturing of new clothing articles. In addition, technological concepts developed for the creation of clothing over the centuries are now being investigated for use in a diverse array of fields—such as in the manufacture of engineering composites, personal protective equipment, and medicine. Further, developments in other fields—such as electronics, nanotechnology, and information and communication technologies—are being investigated for their incorporation into apparel and clothing to create “smart textiles”. The aim of this Special Issue is to put together a collection of scientific reports on such efforts to highlight the range of scientific and technological issues that are being targeted and the ingenuity of the methodologies employed to find answers. It is hoped that readers of this issue will come away with an appreciation of the research being conducted in this area, and perhaps gain inspiration for their own scientific endeavors.
History of engineering & technology --- Polyimide fiber --- thermal stability --- swelling agent --- dyeability --- carbon textile reinforced mortar --- uniaxial tensile tests --- debonding failure --- steel fibers --- prestress --- multi-cracking pattern --- polyacrylonitrile --- polyaniline --- conductive fibers --- flax fiber-reinforced composite --- strain rate effect --- Johnson–Cook model --- lattice structure --- failure mechanism --- textiles --- composite preforming --- mechanical properties --- shear behavior --- surface analysis --- picture frame test --- kinematic draping simulation --- textile --- PET --- biomaterials --- iPS-cells --- cardiomyocytes --- maturation --- gene expression --- electronic textiles --- AMOLED --- OTFTs --- OLEDs --- textile displays --- organic thin film --- graft polymerization --- surface modification --- hydrogels --- gamma irradiation --- silver nanoparticles --- antibacterial activity --- temperature sensor --- conductivity --- coatings --- deposition --- thermocouple --- material characterization --- smart clothing --- temperature sensing --- wearable technology --- nanomaterials --- environmental impacts --- toxicity --- health and safety --- conductive fibres --- cellulose fibres --- pressure sensor --- smart textiles --- viscose fibres --- carbon black --- biocementation --- MICP --- jute fibres --- unconfined compressive strength --- urea hydrolysis --- sustainable geotechnics --- self-healing --- n/a --- Johnson-Cook model
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Developments in the science and technology of textiles are not only limited to apparel and fashion. Certainly, there are research efforts aimed at improving the construction and processing of textiles for clothing—such as studies on cleaner production to reduce environmental impact, increasing the utilization of fibers and process chemicals from renewable resources, and on the recycling of materials from post-consumer waste apparel back into the manufacturing of new clothing articles. In addition, technological concepts developed for the creation of clothing over the centuries are now being investigated for use in a diverse array of fields—such as in the manufacture of engineering composites, personal protective equipment, and medicine. Further, developments in other fields—such as electronics, nanotechnology, and information and communication technologies—are being investigated for their incorporation into apparel and clothing to create “smart textiles”. The aim of this Special Issue is to put together a collection of scientific reports on such efforts to highlight the range of scientific and technological issues that are being targeted and the ingenuity of the methodologies employed to find answers. It is hoped that readers of this issue will come away with an appreciation of the research being conducted in this area, and perhaps gain inspiration for their own scientific endeavors.
Polyimide fiber --- thermal stability --- swelling agent --- dyeability --- carbon textile reinforced mortar --- uniaxial tensile tests --- debonding failure --- steel fibers --- prestress --- multi-cracking pattern --- polyacrylonitrile --- polyaniline --- conductive fibers --- flax fiber-reinforced composite --- strain rate effect --- Johnson–Cook model --- lattice structure --- failure mechanism --- textiles --- composite preforming --- mechanical properties --- shear behavior --- surface analysis --- picture frame test --- kinematic draping simulation --- textile --- PET --- biomaterials --- iPS-cells --- cardiomyocytes --- maturation --- gene expression --- electronic textiles --- AMOLED --- OTFTs --- OLEDs --- textile displays --- organic thin film --- graft polymerization --- surface modification --- hydrogels --- gamma irradiation --- silver nanoparticles --- antibacterial activity --- temperature sensor --- conductivity --- coatings --- deposition --- thermocouple --- material characterization --- smart clothing --- temperature sensing --- wearable technology --- nanomaterials --- environmental impacts --- toxicity --- health and safety --- conductive fibres --- cellulose fibres --- pressure sensor --- smart textiles --- viscose fibres --- carbon black --- biocementation --- MICP --- jute fibres --- unconfined compressive strength --- urea hydrolysis --- sustainable geotechnics --- self-healing --- n/a --- Johnson-Cook model
Choose an application
Developments in the science and technology of textiles are not only limited to apparel and fashion. Certainly, there are research efforts aimed at improving the construction and processing of textiles for clothing—such as studies on cleaner production to reduce environmental impact, increasing the utilization of fibers and process chemicals from renewable resources, and on the recycling of materials from post-consumer waste apparel back into the manufacturing of new clothing articles. In addition, technological concepts developed for the creation of clothing over the centuries are now being investigated for use in a diverse array of fields—such as in the manufacture of engineering composites, personal protective equipment, and medicine. Further, developments in other fields—such as electronics, nanotechnology, and information and communication technologies—are being investigated for their incorporation into apparel and clothing to create “smart textiles”. The aim of this Special Issue is to put together a collection of scientific reports on such efforts to highlight the range of scientific and technological issues that are being targeted and the ingenuity of the methodologies employed to find answers. It is hoped that readers of this issue will come away with an appreciation of the research being conducted in this area, and perhaps gain inspiration for their own scientific endeavors.
History of engineering & technology --- Polyimide fiber --- thermal stability --- swelling agent --- dyeability --- carbon textile reinforced mortar --- uniaxial tensile tests --- debonding failure --- steel fibers --- prestress --- multi-cracking pattern --- polyacrylonitrile --- polyaniline --- conductive fibers --- flax fiber-reinforced composite --- strain rate effect --- Johnson-Cook model --- lattice structure --- failure mechanism --- textiles --- composite preforming --- mechanical properties --- shear behavior --- surface analysis --- picture frame test --- kinematic draping simulation --- textile --- PET --- biomaterials --- iPS-cells --- cardiomyocytes --- maturation --- gene expression --- electronic textiles --- AMOLED --- OTFTs --- OLEDs --- textile displays --- organic thin film --- graft polymerization --- surface modification --- hydrogels --- gamma irradiation --- silver nanoparticles --- antibacterial activity --- temperature sensor --- conductivity --- coatings --- deposition --- thermocouple --- material characterization --- smart clothing --- temperature sensing --- wearable technology --- nanomaterials --- environmental impacts --- toxicity --- health and safety --- conductive fibres --- cellulose fibres --- pressure sensor --- smart textiles --- viscose fibres --- carbon black --- biocementation --- MICP --- jute fibres --- unconfined compressive strength --- urea hydrolysis --- sustainable geotechnics --- self-healing --- Polyimide fiber --- thermal stability --- swelling agent --- dyeability --- carbon textile reinforced mortar --- uniaxial tensile tests --- debonding failure --- steel fibers --- prestress --- multi-cracking pattern --- polyacrylonitrile --- polyaniline --- conductive fibers --- flax fiber-reinforced composite --- strain rate effect --- Johnson-Cook model --- lattice structure --- failure mechanism --- textiles --- composite preforming --- mechanical properties --- shear behavior --- surface analysis --- picture frame test --- kinematic draping simulation --- textile --- PET --- biomaterials --- iPS-cells --- cardiomyocytes --- maturation --- gene expression --- electronic textiles --- AMOLED --- OTFTs --- OLEDs --- textile displays --- organic thin film --- graft polymerization --- surface modification --- hydrogels --- gamma irradiation --- silver nanoparticles --- antibacterial activity --- temperature sensor --- conductivity --- coatings --- deposition --- thermocouple --- material characterization --- smart clothing --- temperature sensing --- wearable technology --- nanomaterials --- environmental impacts --- toxicity --- health and safety --- conductive fibres --- cellulose fibres --- pressure sensor --- smart textiles --- viscose fibres --- carbon black --- biocementation --- MICP --- jute fibres --- unconfined compressive strength --- urea hydrolysis --- sustainable geotechnics --- self-healing
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