Choose an application

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

Materials from renewable resources have attracted increasing attention in recent decades as a result of environmental concerns and due to the depletion of petroleum resources. Polymeric materials from renewable sources have a long history. They were used in ancient times and later accompanied the development of man and civilization. Currently, they are widespread in many areas of life and used, for example, in packaging and in the automotive, construction and pharmaceutical industries.The aim of this Special Issue is to highlight the progress in the manufacturing, characterization, and applications of environmentally friendly polymeric blends from renewable resources. The following aspects were investigated: (i) synthesis of composites based on natural llers; (ii) chemical modi cation of polymers or fillers in order to improve interfacial interactions; (iii) potential applications of the biobased materials.

Environmental science, engineering & technology --- lignin --- microspheres --- composites --- polymeric material --- fractionation --- porosity --- radiation grafting --- cotton linter --- phosphate adsorption --- dynamic studies --- bio-polyethylene --- barley straw --- thermomechanical fibers --- interface --- automotive industry --- natural fiber --- polypropylene --- stiffness --- curauá fibers --- microcrystalline cellulose (MCC) --- unsaturated polyester resins --- thermogravimetric analysis (TG) --- mechanical analysis --- dynamic mechanical analysis (DMA) --- LignoBoost® kraft lignin --- potentiometric sensors --- carbon nanotubes --- impedance spectroscopy --- transition metals --- rice nanofibers --- biocomposites --- casting --- mechanical properties --- thermal properties --- rigid polyurethane foams --- lignocellulosic materials --- filler --- chemical treatment --- mechanical characteristics --- pyrolysis process --- Caragana korshinskii biochar --- physicochemical properties --- adsorption characteristics --- nitrate nitrogen --- bio-oil --- polyurethanes --- hemp shives --- bio-filler --- oil impregnation --- sugar beet pulp --- thermal conductivity --- polyurethane composites --- lavender --- kaolinite --- hydroxyapatite --- high-ball milling process --- antibacterial activity --- wood-resin composites --- unsaturated polyester resin --- recycled PET --- wood flour --- renewable resources --- silver nanoparticles --- lignin --- microspheres --- composites --- polymeric material --- fractionation --- porosity --- radiation grafting --- cotton linter --- phosphate adsorption --- dynamic studies --- bio-polyethylene --- barley straw --- thermomechanical fibers --- interface --- automotive industry --- natural fiber --- polypropylene --- stiffness --- curauá fibers --- microcrystalline cellulose (MCC) --- unsaturated polyester resins --- thermogravimetric analysis (TG) --- mechanical analysis --- dynamic mechanical analysis (DMA) --- LignoBoost® kraft lignin --- potentiometric sensors --- carbon nanotubes --- impedance spectroscopy --- transition metals --- rice nanofibers --- biocomposites --- casting --- mechanical properties --- thermal properties --- rigid polyurethane foams --- lignocellulosic materials --- filler --- chemical treatment --- mechanical characteristics --- pyrolysis process --- Caragana korshinskii biochar --- physicochemical properties --- adsorption characteristics --- nitrate nitrogen --- bio-oil --- polyurethanes --- hemp shives --- bio-filler --- oil impregnation --- sugar beet pulp --- thermal conductivity --- polyurethane composites --- lavender --- kaolinite --- hydroxyapatite --- high-ball milling process --- antibacterial activity --- wood-resin composites --- unsaturated polyester resin --- recycled PET --- wood flour --- renewable resources --- silver nanoparticles

Choose an application

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

Materials from renewable resources have attracted increasing attention in recent decades as a result of environmental concerns and due to the depletion of petroleum resources. Polymeric materials from renewable sources have a long history. They were used in ancient times and later accompanied the development of man and civilization. Currently, they are widespread in many areas of life and used, for example, in packaging and in the automotive, construction and pharmaceutical industries.The aim of this Special Issue is to highlight the progress in the manufacturing, characterization, and applications of environmentally friendly polymeric blends from renewable resources. The following aspects were investigated: (i) synthesis of composites based on natural llers; (ii) chemical modi cation of polymers or fillers in order to improve interfacial interactions; (iii) potential applications of the biobased materials.

Environmental science, engineering & technology --- lignin --- microspheres --- composites --- polymeric material --- fractionation --- porosity --- radiation grafting --- cotton linter --- phosphate adsorption --- dynamic studies --- bio-polyethylene --- barley straw --- thermomechanical fibers --- interface --- automotive industry --- natural fiber --- polypropylene --- stiffness --- curauá fibers --- microcrystalline cellulose (MCC) --- unsaturated polyester resins --- thermogravimetric analysis (TG) --- mechanical analysis --- dynamic mechanical analysis (DMA) --- LignoBoost® kraft lignin --- potentiometric sensors --- carbon nanotubes --- impedance spectroscopy --- transition metals --- rice nanofibers --- biocomposites --- casting --- mechanical properties --- thermal properties --- rigid polyurethane foams --- lignocellulosic materials --- filler --- chemical treatment --- mechanical characteristics --- pyrolysis process --- Caragana korshinskii biochar --- physicochemical properties --- adsorption characteristics --- nitrate nitrogen --- bio-oil --- polyurethanes --- hemp shives --- bio-filler --- oil impregnation --- sugar beet pulp --- thermal conductivity --- polyurethane composites --- lavender --- kaolinite --- hydroxyapatite --- high-ball milling process --- antibacterial activity --- wood–resin composites --- unsaturated polyester resin --- recycled PET --- wood flour --- renewable resources --- silver nanoparticles --- n/a --- curauá fibers --- wood-resin composites

Choose an application

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

Graphene-polymer nanocomposites continue to gain interest in diverse scientific and technological fields. Graphene-based nanomaterials present the advantages of other carbon nanofillers, like electrical and thermal conductivity, while having significantly lower production costs when compared to materials such as carbon nanotubes, for instance. In addition, in the oxidized forms of graphene, the large specific area combined with a large quantity of functionalizable chemical groups available for physical or chemical interaction with polymers, allow for good dispersion and tunable binding with the surrounding matrix. Other features are noteworthy in graphene-based nanomaterials, like their generally good biocompatibility and the ability to absorb near-infrared radiation, allowing for the use in biomedical applications, such as drug delivery and photothermal therapy.This Special Issue provides an encompassing view on the state of the art of graphene-polymer composites, showing how current research is dealing with new and exciting challenges. The published papers cover topics ranging from novel production methods and insights on mechanisms of mechanical reinforcement of composites, to applications as diverse as automotive and aeronautics, cancer treatment, anticorrosive coatings, thermally conductive fabrics and foams, and oil-adsorbent aerogels.

graphene oxide --- polymer composite fiber --- interfacial bonding --- polypropylene --- thermal stability --- graphene --- unsaturated polyester resins --- tung oil --- biobased polymer nanocomposites --- in situ melt polycondensation --- graphene polymer matrix composite --- polyamide 66 --- elongational flow --- hydrogen bond --- poly(trimethylene terephthalate) --- electrospinning --- composite fiber --- morphology --- crystallization --- electrical conductivity --- mechanical property --- elastic recovery --- cellulose nanofibers --- polyvinyl alcohol --- directional freeze-drying --- oil absorption --- graphene oxide–platinum nanoparticles nanocomposites --- prostate cancer --- cytotoxicity --- oxidative stress --- mitochondrial membrane potential --- DNA damage --- conducting polymer --- PANI --- LEIS --- corrosion --- fabric --- cellulose nanocrystal --- thermal conductivity --- adhesives --- cohesive zone model --- finite element method --- graphene-polymer nanocomposite --- graphene/polymer interface --- molecular dynamics --- regressive softening law --- polysulfone foams --- tortuosity --- water vapor induced phase separation --- scCO2 --- toughening mechanisms --- graphene nanoplatelets --- recycled rubber --- Halpin–Tsai --- SEM --- light emitting diode --- phototherapy --- polyethylene glycol --- thermal reduction --- n/a --- graphene oxide-platinum nanoparticles nanocomposites --- Halpin-Tsai

Choose an application

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

With daily signals, Nature is communicating us that its unconscious wicked exploitation is no more sustainable. Our socio-economic system focuses on production increasing without considering the consequences. We are intoxicating ourselves on a daily bases just to allow the system to perpetuate itself. The time to switch into more natural solutions is come and the scientific community is ready to offer more natural product with comparable performance then the market products we are used to deal with. This book collects a broad set of scientific examples in which research groups from all over the world, aim to replace fossil fuel-based solutions with biomass derived materials. In here, some of the most innovative developments in the field of bio-materials are reported considering topics which goes from biomass valorization to the synthesis of high preforming bio-based materials.

chitosan --- graphene oxide --- microstructure --- autoxidation --- heavy metals --- polycaprolactone --- precipitation --- thermosetting polymers --- thermal degradation --- humidity sensor --- asphalt rubber --- tung oil --- nanobiocomposites --- ionic liquid --- GC-MS --- hybrid nonisocyanate polyurethane --- physicochemical properties --- alginate sponge --- Bioflex --- dimer acid --- bio-asphalt --- benzoyl cellulose --- Peptone --- transparent wood --- biocomposite --- nanoclays --- storage stability --- solvent- and catalyst-free --- microcellulose fiber --- lignin-containing cellulose nanofibrils --- polylactic acid (PLA) --- bio-inspired interfaces --- polyhydroxyalkanoates --- strain sensor --- enzymatic saccharification --- headspace solid phase microextraction --- PHBV --- electrical resistance --- melt condensation --- cement --- solution casting --- orange waste --- hybrid composites --- biopolymers --- TEMPO oxidation --- pollutant adsorbents --- Escherichia coli --- bio-nanocomposites --- TiO2 anatase --- metal binding --- liquid natural rubber --- hydrotropic treatment --- metal chloride --- feast-famine --- biomass resources --- wood --- electroless deposition --- one-pot synthesis --- thermoplastic starch --- films --- lignin-carbohydrate complex --- cellulose --- corn starch --- microencapsulated phase change material (MPCM) --- differential scanning calorimetry --- compatibility --- natural fibers --- workability --- silkworm cocoons --- lignin content --- polylactic acid --- porous structure --- electrospinning --- nanocellulose fibers --- H2O2 bleaching treatment --- polysaccharides --- mixing sequence --- porosity --- lignocellulosic nanofibrils --- dense structure --- alkali lignin --- polydopamine coating --- nuclear magnetic resonance --- cationic dyes --- poly(lactic acid) and composite films --- endothermic effect --- HSQC-NMR --- Microbial nutrient --- n/a --- toughening --- X-ray diffraction --- water resistance --- waste biomass --- lignin --- UV light --- ultrafiltration --- two-step lyophilization --- mechanical degradation --- bio-based --- methylene blue --- stearoyl cellulose --- ONP fibers --- anionic surfactants --- Hatscheck process --- osteoblast proliferation --- resource recovery --- dissolution --- copper coating --- bacterial cellulose --- hydrogel --- iron chelation --- knotwood --- sensitivity --- mixed microbial cultures --- dimensional stability --- volatiles --- lignocellulose --- Artemisia vulgaris --- surface modification --- PHA --- crosslinked microparticles --- pyrene --- composites --- galactoglucomannan --- polymeric composites --- kaempferol --- tannin-furanic foam --- Solanyl --- wastewater treatments --- adsorption capacity --- heat treatment --- thermal gravimetric analysis --- WAXS --- unsaturated polyester resins --- pulp fibers --- free-radical polymerization --- larixol --- delignification --- antifouling --- chemical composition --- hemicellulose --- tissue engineering --- extrusion-compounding --- membrane --- photodegradation --- structural plastics --- scanning electron microscope --- phenanthrene --- thermal properties --- immobilized TEMPO --- Staphylococcus aureus --- adsorption --- wood modification --- structure–property relationship --- physical property --- film --- mechanical properties --- tannin --- Bio-based foams --- latex state --- paper-based scaffolds --- skincare --- pyrolysis mechanism --- emulsion-solvent evaporation method --- bioplastics --- imidazolium --- fractionation --- cost --- fiber-cement --- lyocell fiber --- recycling --- kenaf fiber --- thermal stability --- transport properties --- SAXS --- silanization --- cellulose nanofibers --- taxifolin --- tannin polymer --- vibrational spectroscopy --- robust fiber network --- nanocelluloses --- poly(lactic acid) --- Anti-bacterial silver nanoparticle --- cellulose nanocrystals --- structure-property relationship