Recycling and Resource Recovery from Polymers II

This compendium illuminates the path to a circular economy, spotlighting innovative research across diverse domains. Key themes include the plastics economy, energy recovery, and emissions reduction. Chapters delve into monomer recovery, hydrogen energy systems, and feedstock recycling, offering a c...

Celý popis

Uloženo v:
Podrobná bibliografie
Médium: Online
Jazyk:angličtina
Vydáno: MDPI - Multidisciplinary Digital Publishing Institute 2024
Témata:
n/a
On-line přístup:ONIX_20240514_9783725804269_310
Tagy: Přidat tag
Žádné tagy, Buďte první, kdo vytvoří štítek k tomuto záznamu!
_version_ 1869516175399976960
collection Directory of Open Access Books
description This compendium illuminates the path to a circular economy, spotlighting innovative research across diverse domains. Key themes include the plastics economy, energy recovery, and emissions reduction. Chapters delve into monomer recovery, hydrogen energy systems, and feedstock recycling, offering a comprehensive view of sustainable material processing. Technological advancements feature prominently, covering thermal and mechanical degradation of recycled materials, upcycling of pine branches, and the thermocatalytic conversion of plastics into liquid fuels. The multidisciplinary exploration extends from fabricating recycled polycarbonate fibers for thermal signature reduction to the valorization of waste subproducts in composite materials. The compendium serves as a valuable resource for researchers, practitioners, and policymakers, providing insights into the intricate landscape of circular economy endeavors.
format Online
id doab-20.500.12854ir-137713
institution Directory of Open Access Books
language eng
publishDate 2024
publishDateRange 2024
publishDateSort 2024
publisher MDPI - Multidisciplinary Digital Publishing Institute
publisherStr MDPI - Multidisciplinary Digital Publishing Institute
record_format ojs
spelling doab-20.500.12854ir-1377132024-05-14T14:13:11Z Recycling and Resource Recovery from Polymers II Devasahayam, Sheila Dyer, Laurence graphene oxide polysilicone functionalization flame retardancy epoxy resin polymers stimulation fluid oilfield produced water chelating agents water sustainability bio-polymer hide waste circular economy n/a spent coffee grounds biopolymer precursors polysaccharides composites chemical recycling plastic waste industrial rejected streams pyrolysis oil pyrolysis secondary raw materials alternative fuels recycling beverage cartons polymer processing cellulose waste tire rubber chicken feathers acoustic properties filter waste fillers pollutants removal wastewater treatment waste polyvinyl chloride (PVC) pulverization heat treatment de-chlorination blast furnace injection multilayer lightweight packaging plastic biopolymers leather waste soil fertilizers industrial crops polycarbonate waste recycled fibre thermal signature camouflage textiles gasification reforming H2 production CO2 emissions plastics fuel catalysts clays clay minerals thermocatalytic conversion additive manufacturing coextrusion polylactide acid filament polypropylene polystyrene polyvinyl chloride high-density polyethylene low-density polyethylene polyurethanes chemical–mechanical recycling wood upcycling particleboard mechanical properties bulk density physical properties carbon storage wood branches poly-lactic acid 3D printing thermal degradation mechanical degradation molecular weight machine learning rubber concrete prediction algorithm chloride permeability coefficient thema EDItEUR::P Mathematics and Science::PN Chemistry::PNK Inorganic chemistry This compendium illuminates the path to a circular economy, spotlighting innovative research across diverse domains. Key themes include the plastics economy, energy recovery, and emissions reduction. Chapters delve into monomer recovery, hydrogen energy systems, and feedstock recycling, offering a comprehensive view of sustainable material processing. Technological advancements feature prominently, covering thermal and mechanical degradation of recycled materials, upcycling of pine branches, and the thermocatalytic conversion of plastics into liquid fuels. The multidisciplinary exploration extends from fabricating recycled polycarbonate fibers for thermal signature reduction to the valorization of waste subproducts in composite materials. The compendium serves as a valuable resource for researchers, practitioners, and policymakers, providing insights into the intricate landscape of circular economy endeavors. 2024-05-14T14:13:07Z 2024-05-14T14:13:07Z 2024 book ONIX_20240514_9783725804269_310 9783725804269 9783725804252 https://directory.doabooks.org/handle/20.500.12854/137713 eng application/octet-stream Attribution-NonCommercial-NoDerivatives 4.0 International https://mdpi.com/books/pdfview/book/8942 https://mdpi.com/books/pdfview/book/8942 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-7258-0425-2 10.3390/books978-3-7258-0425-2 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783725804269 9783725804252 334 open access
spellingShingle graphene oxide
polysilicone
functionalization
flame retardancy
epoxy resin
polymers
stimulation fluid
oilfield produced water
chelating agents
water sustainability
bio-polymer
hide waste
circular economy
n/a
spent coffee grounds
biopolymer precursors
polysaccharides
composites
chemical recycling
plastic waste
industrial rejected streams
pyrolysis oil
pyrolysis
secondary raw materials
alternative fuels
recycling
beverage cartons
polymer processing
cellulose
waste
tire rubber
chicken feathers
acoustic properties
filter
waste fillers
pollutants removal
wastewater treatment
waste polyvinyl chloride (PVC)
pulverization
heat treatment
de-chlorination
blast furnace injection
multilayer
lightweight packaging
plastic
biopolymers
leather waste
soil
fertilizers
industrial crops
polycarbonate waste
recycled fibre
thermal signature
camouflage textiles
gasification
reforming
H2 production
CO2 emissions
plastics
fuel
catalysts
clays
clay minerals
thermocatalytic conversion
additive manufacturing
coextrusion
polylactide acid
filament
polypropylene
polystyrene
polyvinyl chloride
high-density polyethylene
low-density polyethylene
polyurethanes
chemical–mechanical recycling
wood
upcycling
particleboard
mechanical properties
bulk density
physical properties
carbon storage
wood branches
poly-lactic acid
3D printing
thermal degradation
mechanical degradation
molecular weight
machine learning
rubber concrete
prediction
algorithm
chloride permeability coefficient
thema EDItEUR::P Mathematics and Science::PN Chemistry::PNK Inorganic chemistry
Recycling and Resource Recovery from Polymers II
title Recycling and Resource Recovery from Polymers II
title_full Recycling and Resource Recovery from Polymers II
title_fullStr Recycling and Resource Recovery from Polymers II
title_full_unstemmed Recycling and Resource Recovery from Polymers II
title_short Recycling and Resource Recovery from Polymers II
title_sort recycling and resource recovery from polymers ii
topic graphene oxide
polysilicone
functionalization
flame retardancy
epoxy resin
polymers
stimulation fluid
oilfield produced water
chelating agents
water sustainability
bio-polymer
hide waste
circular economy
n/a
spent coffee grounds
biopolymer precursors
polysaccharides
composites
chemical recycling
plastic waste
industrial rejected streams
pyrolysis oil
pyrolysis
secondary raw materials
alternative fuels
recycling
beverage cartons
polymer processing
cellulose
waste
tire rubber
chicken feathers
acoustic properties
filter
waste fillers
pollutants removal
wastewater treatment
waste polyvinyl chloride (PVC)
pulverization
heat treatment
de-chlorination
blast furnace injection
multilayer
lightweight packaging
plastic
biopolymers
leather waste
soil
fertilizers
industrial crops
polycarbonate waste
recycled fibre
thermal signature
camouflage textiles
gasification
reforming
H2 production
CO2 emissions
plastics
fuel
catalysts
clays
clay minerals
thermocatalytic conversion
additive manufacturing
coextrusion
polylactide acid
filament
polypropylene
polystyrene
polyvinyl chloride
high-density polyethylene
low-density polyethylene
polyurethanes
chemical–mechanical recycling
wood
upcycling
particleboard
mechanical properties
bulk density
physical properties
carbon storage
wood branches
poly-lactic acid
3D printing
thermal degradation
mechanical degradation
molecular weight
machine learning
rubber concrete
prediction
algorithm
chloride permeability coefficient
thema EDItEUR::P Mathematics and Science::PN Chemistry::PNK Inorganic chemistry
topic_facet graphene oxide
polysilicone
functionalization
flame retardancy
epoxy resin
polymers
stimulation fluid
oilfield produced water
chelating agents
water sustainability
bio-polymer
hide waste
circular economy
n/a
spent coffee grounds
biopolymer precursors
polysaccharides
composites
chemical recycling
plastic waste
industrial rejected streams
pyrolysis oil
pyrolysis
secondary raw materials
alternative fuels
recycling
beverage cartons
polymer processing
cellulose
waste
tire rubber
chicken feathers
acoustic properties
filter
waste fillers
pollutants removal
wastewater treatment
waste polyvinyl chloride (PVC)
pulverization
heat treatment
de-chlorination
blast furnace injection
multilayer
lightweight packaging
plastic
biopolymers
leather waste
soil
fertilizers
industrial crops
polycarbonate waste
recycled fibre
thermal signature
camouflage textiles
gasification
reforming
H2 production
CO2 emissions
plastics
fuel
catalysts
clays
clay minerals
thermocatalytic conversion
additive manufacturing
coextrusion
polylactide acid
filament
polypropylene
polystyrene
polyvinyl chloride
high-density polyethylene
low-density polyethylene
polyurethanes
chemical–mechanical recycling
wood
upcycling
particleboard
mechanical properties
bulk density
physical properties
carbon storage
wood branches
poly-lactic acid
3D printing
thermal degradation
mechanical degradation
molecular weight
machine learning
rubber concrete
prediction
algorithm
chloride permeability coefficient
thema EDItEUR::P Mathematics and Science::PN Chemistry::PNK Inorganic chemistry
url ONIX_20240514_9783725804269_310