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The triple-R model (reduce, reuse, and recycle) is the essential concept of the circular economy. Due to population growth, the recovery of added-value products from wastes has become a challenge. Wastewaters of different origin (urban, industrial, mining, textile, distillery, and microbial culture, among others) are rich in energy, water, and nutrient sources that can be recovered and reused within a circular economy framework. Recently, wastewater treatment plants have been converted into biofactories, since they can convert waste into new products (water, nutrients, fertilizers, biomethane, electricity, heat, etc.) with a minimal environmental impact. In this context, adsorption and ion-exchange, as well as the integration of both processes, have been proposed as promising technologies for the treatment of wastewaters for resource recovery. Therefore, the aim of this Special Issue, entitled “Wastewater Treatment by Adsorption and/or Ion-Exchange Processes for Resource Recovery”, is to promote these two processes as innovative and environmentally friendly alternatives for the recovery of secondary raw materials from by-products or waste streams. These processes could improve the environmental, economic, and social impacts of the currently used wastewater treatment techniques.
clay --- dye --- adsorption --- isotherm --- kinetics --- hydroxyapatite --- calcium carbonate --- coating --- heavy metal sorption --- groundwater remediation --- adsorption technology --- ultra-sonication --- phosphate removal --- granular ferric hydroxide --- micro-sized adsorbents --- organic acid --- circular economy --- optimization process --- bio-economy --- response surface methodology --- corn stream --- surface-active compounds --- eco-adsorbents --- green membranes --- resource recovery --- hybrid biosorbent --- desorption --- thermodynamic --- nanofiltration --- n/a
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The triple-R model (reduce, reuse, and recycle) is the essential concept of the circular economy. Due to population growth, the recovery of added-value products from wastes has become a challenge. Wastewaters of different origin (urban, industrial, mining, textile, distillery, and microbial culture, among others) are rich in energy, water, and nutrient sources that can be recovered and reused within a circular economy framework. Recently, wastewater treatment plants have been converted into biofactories, since they can convert waste into new products (water, nutrients, fertilizers, biomethane, electricity, heat, etc.) with a minimal environmental impact. In this context, adsorption and ion-exchange, as well as the integration of both processes, have been proposed as promising technologies for the treatment of wastewaters for resource recovery. Therefore, the aim of this Special Issue, entitled “Wastewater Treatment by Adsorption and/or Ion-Exchange Processes for Resource Recovery”, is to promote these two processes as innovative and environmentally friendly alternatives for the recovery of secondary raw materials from by-products or waste streams. These processes could improve the environmental, economic, and social impacts of the currently used wastewater treatment techniques.
Technology: general issues --- History of engineering & technology --- Environmental science, engineering & technology --- clay --- dye --- adsorption --- isotherm --- kinetics --- hydroxyapatite --- calcium carbonate --- coating --- heavy metal sorption --- groundwater remediation --- adsorption technology --- ultra-sonication --- phosphate removal --- granular ferric hydroxide --- micro-sized adsorbents --- organic acid --- circular economy --- optimization process --- bio-economy --- response surface methodology --- corn stream --- surface-active compounds --- eco-adsorbents --- green membranes --- resource recovery --- hybrid biosorbent --- desorption --- thermodynamic --- nanofiltration --- clay --- dye --- adsorption --- isotherm --- kinetics --- hydroxyapatite --- calcium carbonate --- coating --- heavy metal sorption --- groundwater remediation --- adsorption technology --- ultra-sonication --- phosphate removal --- granular ferric hydroxide --- micro-sized adsorbents --- organic acid --- circular economy --- optimization process --- bio-economy --- response surface methodology --- corn stream --- surface-active compounds --- eco-adsorbents --- green membranes --- resource recovery --- hybrid biosorbent --- desorption --- thermodynamic --- nanofiltration
Choose an application
The triple-R model (reduce, reuse, and recycle) is the essential concept of the circular economy. Due to population growth, the recovery of added-value products from wastes has become a challenge. Wastewaters of different origin (urban, industrial, mining, textile, distillery, and microbial culture, among others) are rich in energy, water, and nutrient sources that can be recovered and reused within a circular economy framework. Recently, wastewater treatment plants have been converted into biofactories, since they can convert waste into new products (water, nutrients, fertilizers, biomethane, electricity, heat, etc.) with a minimal environmental impact. In this context, adsorption and ion-exchange, as well as the integration of both processes, have been proposed as promising technologies for the treatment of wastewaters for resource recovery. Therefore, the aim of this Special Issue, entitled “Wastewater Treatment by Adsorption and/or Ion-Exchange Processes for Resource Recovery”, is to promote these two processes as innovative and environmentally friendly alternatives for the recovery of secondary raw materials from by-products or waste streams. These processes could improve the environmental, economic, and social impacts of the currently used wastewater treatment techniques.
Technology: general issues --- History of engineering & technology --- Environmental science, engineering & technology --- clay --- dye --- adsorption --- isotherm --- kinetics --- hydroxyapatite --- calcium carbonate --- coating --- heavy metal sorption --- groundwater remediation --- adsorption technology --- ultra-sonication --- phosphate removal --- granular ferric hydroxide --- micro-sized adsorbents --- organic acid --- circular economy --- optimization process --- bio-economy --- response surface methodology --- corn stream --- surface-active compounds --- eco-adsorbents --- green membranes --- resource recovery --- hybrid biosorbent --- desorption --- thermodynamic --- nanofiltration --- n/a
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The extraction and exploration of cellulose-based polymers is an exciting area of research. For many years, wood (especially from bleached kraft wood pulp) was considered the main source of cellulosic compounds because of its abundance in nature. However, in the past decade, researchers have been devoted to finding alternatives to extract cellulose from byproducts of agricultural crops and/or textile wastes, which are both highly available at a very reduced raw material cost. This book brings together original research that details the recent progresses and new developments in this field, and how this research is contributing to a circular economy.
citrus sinensis --- nano-fibrillated cellulose --- silver nanoparticles --- acid hydrolysis --- heavy metal sorption --- anaerobic digestion --- biofuel --- biomass --- cotton-based waste --- closed-loop --- lignocellulose --- textile waste --- cellulose nanofibre --- green materials --- biopolymers --- environmental --- recycled newspaper --- composite laminates --- water resistance --- high strength --- cotton wastes --- textile --- nanomaterials --- cellulose nanocrystal --- extraction methods --- environmental application --- regenerated cellulose fiber --- Au NP --- controllably assembled --- SERS --- dimetridazole --- cellulose hydrogel --- thermo-responsive --- sustained release --- silver sulfadiazine --- burn wound --- polymer --- carpet fiber --- direct analysis in real time --- time of flight --- mass spectrometry --- function switching --- oleamide --- cellulose nanofibers isolation --- carpet wastes --- supercritical carbon dioxide --- enhanced properties --- recovery of cellulose --- textile fibers --- eco-efficiency --- circular economy --- textile industry --- n/a
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The extraction and exploration of cellulose-based polymers is an exciting area of research. For many years, wood (especially from bleached kraft wood pulp) was considered the main source of cellulosic compounds because of its abundance in nature. However, in the past decade, researchers have been devoted to finding alternatives to extract cellulose from byproducts of agricultural crops and/or textile wastes, which are both highly available at a very reduced raw material cost. This book brings together original research that details the recent progresses and new developments in this field, and how this research is contributing to a circular economy.
Research & information: general --- Physics --- citrus sinensis --- nano-fibrillated cellulose --- silver nanoparticles --- acid hydrolysis --- heavy metal sorption --- anaerobic digestion --- biofuel --- biomass --- cotton-based waste --- closed-loop --- lignocellulose --- textile waste --- cellulose nanofibre --- green materials --- biopolymers --- environmental --- recycled newspaper --- composite laminates --- water resistance --- high strength --- cotton wastes --- textile --- nanomaterials --- cellulose nanocrystal --- extraction methods --- environmental application --- regenerated cellulose fiber --- Au NP --- controllably assembled --- SERS --- dimetridazole --- cellulose hydrogel --- thermo-responsive --- sustained release --- silver sulfadiazine --- burn wound --- polymer --- carpet fiber --- direct analysis in real time --- time of flight --- mass spectrometry --- function switching --- oleamide --- cellulose nanofibers isolation --- carpet wastes --- supercritical carbon dioxide --- enhanced properties --- recovery of cellulose --- textile fibers --- eco-efficiency --- circular economy --- textile industry --- citrus sinensis --- nano-fibrillated cellulose --- silver nanoparticles --- acid hydrolysis --- heavy metal sorption --- anaerobic digestion --- biofuel --- biomass --- cotton-based waste --- closed-loop --- lignocellulose --- textile waste --- cellulose nanofibre --- green materials --- biopolymers --- environmental --- recycled newspaper --- composite laminates --- water resistance --- high strength --- cotton wastes --- textile --- nanomaterials --- cellulose nanocrystal --- extraction methods --- environmental application --- regenerated cellulose fiber --- Au NP --- controllably assembled --- SERS --- dimetridazole --- cellulose hydrogel --- thermo-responsive --- sustained release --- silver sulfadiazine --- burn wound --- polymer --- carpet fiber --- direct analysis in real time --- time of flight --- mass spectrometry --- function switching --- oleamide --- cellulose nanofibers isolation --- carpet wastes --- supercritical carbon dioxide --- enhanced properties --- recovery of cellulose --- textile fibers --- eco-efficiency --- circular economy --- textile industry
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