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Over the few coming decades, bio-based and biodegradable plastics produced from sustainable bioresources should essentially substitute the prevalent synthetic plastics produced from exhaustible hydrocarbon fossils. To the greatest extend, this innovative trend has to apply to the packaging manufacturing area and especially to food packaging implementation. To supply the rapid production increment of biodegradable plastics, there must be provided the effective development of scientific-technical potential that promotes the comprehensive exploration of their structural, functional, and dynamic characteristics. In this regard, the transition from passive barrier materials preventing water and oxygen transport as well as bacteria infiltration to active functional packaging that ensures gas diffusion selectivity, antiseptics' and other modifiers' release should be based on the thorough study of biopolymer crystallinity, morphology, diffusivity, controlled biodegradability and life cycle assessment. This Special Issue accumulates the papers of international teams that devoted to scientific and industrial bases providing the biodegradable material development in the barrier and active packaging as well as in agricultural applications. We hope that book will bring great interest to the experts in the area of sustainable biopolymers.

Research & information: general --- bio-HDPE --- GA --- natural additives --- thermal resistance --- UV stability --- food packaging --- antimicrobial properties --- polyethylene --- birch bark extract --- ultrasound --- thermoplastic starch --- biodegradation --- permeability --- diffusion --- sorption --- porous membranes --- hydrophilic and hydrophobic polymers --- PLA bottle --- bio-based and biodegradable polymers --- life cycle assessment --- environmental impact --- ReCiPe2016 method --- packaging material --- bio-based polymer composite --- natural rubber --- water absorption --- mycological test --- biodegradability --- mechanical properties --- poly(3-hydroxybutyrate) (PHB) --- polylactic acid (PLA) --- biomaterials --- gas permeability --- gas diffusion --- segmental dynamics --- electron spin resonance (ESR) --- scanning electron microscopy (SEM) --- differential scanning calorimetry (DSC) --- poly(3-hydroxybutyrate) --- poly(3-hydroxybutyrate-co-3-hydroxyvalerate) --- poly(3-hydroxybutyrate-co-4-methyl-3-hydroxyvalerate) --- hydrolysis --- pancreatic lipase --- mechanical behavior --- chitosan --- polymeric films --- crosslinking --- genipin --- sorption isotherm --- degree of crosslinking --- polylactide --- poly(ethyleneglycol) --- blending under shear deformations --- electrospinning --- oil absorption --- Monte Carlo --- bio-based polymers --- biodegradable packaging --- biopolymer structure --- encapsulation --- life cycle analysis

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Over the few coming decades, bio-based and biodegradable plastics produced from sustainable bioresources should essentially substitute the prevalent synthetic plastics produced from exhaustible hydrocarbon fossils. To the greatest extend, this innovative trend has to apply to the packaging manufacturing area and especially to food packaging implementation. To supply the rapid production increment of biodegradable plastics, there must be provided the effective development of scientific-technical potential that promotes the comprehensive exploration of their structural, functional, and dynamic characteristics. In this regard, the transition from passive barrier materials preventing water and oxygen transport as well as bacteria infiltration to active functional packaging that ensures gas diffusion selectivity, antiseptics' and other modifiers' release should be based on the thorough study of biopolymer crystallinity, morphology, diffusivity, controlled biodegradability and life cycle assessment. This Special Issue accumulates the papers of international teams that devoted to scientific and industrial bases providing the biodegradable material development in the barrier and active packaging as well as in agricultural applications. We hope that book will bring great interest to the experts in the area of sustainable biopolymers.

bio-HDPE --- GA --- natural additives --- thermal resistance --- UV stability --- food packaging --- antimicrobial properties --- polyethylene --- birch bark extract --- ultrasound --- thermoplastic starch --- biodegradation --- permeability --- diffusion --- sorption --- porous membranes --- hydrophilic and hydrophobic polymers --- PLA bottle --- bio-based and biodegradable polymers --- life cycle assessment --- environmental impact --- ReCiPe2016 method --- packaging material --- bio-based polymer composite --- natural rubber --- water absorption --- mycological test --- biodegradability --- mechanical properties --- poly(3-hydroxybutyrate) (PHB) --- polylactic acid (PLA) --- biomaterials --- gas permeability --- gas diffusion --- segmental dynamics --- electron spin resonance (ESR) --- scanning electron microscopy (SEM) --- differential scanning calorimetry (DSC) --- poly(3-hydroxybutyrate) --- poly(3-hydroxybutyrate-co-3-hydroxyvalerate) --- poly(3-hydroxybutyrate-co-4-methyl-3-hydroxyvalerate) --- hydrolysis --- pancreatic lipase --- mechanical behavior --- chitosan --- polymeric films --- crosslinking --- genipin --- sorption isotherm --- degree of crosslinking --- polylactide --- poly(ethyleneglycol) --- blending under shear deformations --- electrospinning --- oil absorption --- Monte Carlo --- bio-based polymers --- biodegradable packaging --- biopolymer structure --- encapsulation --- life cycle analysis

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• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Additive manufacturing technology offers the ability to produce personalized products with lower development costs, shorter lead times, less energy consumed during manufacturing and less material waste. It can be used to manufacture complex parts and enables manufacturers to reduce their inventory, make products on-demand, create smaller and localized manufacturing environments, and even reduce supply chains. Additive manufacturing (AM), also known as fabricating three-dimensional (3D) and four-dimensional (4D) components, refers to processes that allow for the direct fabrication of physical products from computer-aided design (CAD) models through the repetitious deposition of material layers. Compared with traditional manufacturing processes, AM allows the production of customized parts from bio- and synthetic polymers without the need for molds or machining typical for conventional formative and subtractive fabrication.In this Special Issue, we aimed to capture the cutting-edge state-of-the-art research pertaining to advancing the additive manufacturing of polymeric materials. The topic themes include advanced polymeric material development, processing parameter optimization, characterization techniques, structure–property relationships, process modelling, etc., specifically for AM.

Technology: general issues --- History of engineering & technology --- polylactic acid (PLA) --- natural fibres --- biocomposite --- mechanical properties --- thermoplastic starch --- biopolymer --- composite --- food packaging --- pitch --- polyethylene --- carbon fibres --- extrusion --- blend --- antimicrobial --- antibacterial --- 3D printing --- fused filament fabrication --- composite material --- fused-filament fabrication --- mechanical strength --- naked mole-rat algorithm --- optimization --- process parameters --- bio-based polyethylene composite --- X-ray tomography --- CNT --- MWCNT --- non-covalent functionalisation --- polythiophene --- P3HT --- reaction time --- natural fiber composite --- product design --- sustainability design --- design process --- epoxidized jatropha oil --- shape memory polymer --- bio-based polymer --- jatropha oil --- ABS --- fatigue --- thermo-mechanical loads --- building orientation --- nozzle size --- layer thickness --- drug delivery --- biodegradable polymers --- polymeric scaffolds --- natural bioactive polymers --- antimicrobial properties --- anticancer activity --- tissue engineering --- lattice material --- flexible TPU --- internal architecture --- minimum ignition temperature of dispersed dust --- dust explosion --- dust cloud --- polyamide 12 --- additive technologies --- kenaf fibre --- fibre treatment --- thermal properties --- Fused Deposition Modelling (FDM) --- silver nanopowder --- kenaf --- high-density polyethylene --- polylactic acid (PLA) --- natural fibres --- biocomposite --- mechanical properties --- thermoplastic starch --- biopolymer --- composite --- food packaging --- pitch --- polyethylene --- carbon fibres --- extrusion --- blend --- antimicrobial --- antibacterial --- 3D printing --- fused filament fabrication --- composite material --- fused-filament fabrication --- mechanical strength --- naked mole-rat algorithm --- optimization --- process parameters --- bio-based polyethylene composite --- X-ray tomography --- CNT --- MWCNT --- non-covalent functionalisation --- polythiophene --- P3HT --- reaction time --- natural fiber composite --- product design --- sustainability design --- design process --- epoxidized jatropha oil --- shape memory polymer --- bio-based polymer --- jatropha oil --- ABS --- fatigue --- thermo-mechanical loads --- building orientation --- nozzle size --- layer thickness --- drug delivery --- biodegradable polymers --- polymeric scaffolds --- natural bioactive polymers --- antimicrobial properties --- anticancer activity --- tissue engineering --- lattice material --- flexible TPU --- internal architecture --- minimum ignition temperature of dispersed dust --- dust explosion --- dust cloud --- polyamide 12 --- additive technologies --- kenaf fibre --- fibre treatment --- thermal properties --- Fused Deposition Modelling (FDM) --- silver nanopowder --- kenaf --- high-density polyethylene