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The papers selected for publication in the Special Issue “Urban and industrial wastewater disinfection and decontamination by Advanced Oxidation Processes (AOPs): current issues and future trends” and published in this book, include topics related with (waste)water treatment and its reuse, disinfection, and pollutant degradation, advancing the know-how of the topics or assessing their integration into the new age of the circular economy of water. Likewise, aspects such as modeling of degradation processes and new materials synthesis were published, aiming to improve, optimize and predict the efficacy of the existing or the novel treatment processes. Moreover, pilot plant operation and large-scale processes were featured, assessing the feasibility of these new treatment methods in real world applications. Overall, the Special Issue and this book present innovative solutions on the field of water and wastewater treatment, with a view on the future technologies that will form the next advances of the field.
Technology: general issues --- emerging pollutants --- advanced oxidation process --- water pollution --- ultrasound --- flower-like Bi2WO6 --- E.coli inactivation --- reactive oxygen species (ROS) --- photocatalysis --- solar disinfection --- water treatment --- pollution --- circular economy --- wastewater reuse --- zero waste --- zero energy --- substances recovery --- sustainable development goals --- heterogeneous photocatalysis --- titanium dioxide --- tin oxide --- graphene oxide --- chemical oxygen demand --- antibiotics --- wastewater --- removal efficiency --- slurry reactor --- computer-based learning --- solar photocatalysis --- water contaminants --- kinetic modeling --- photoreactor design --- UV-LED --- TiO2 --- hexacyanoferrate --- mining --- hydrothermal method --- elimination routes --- fresh urine --- pharmaceutical degradation --- processes selectivity --- theoretical analysis --- advanced oxidation --- membrane technology --- micropollutants --- biological contaminants --- cytotoxicity --- n/a
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The papers selected for publication in the Special Issue “Urban and industrial wastewater disinfection and decontamination by Advanced Oxidation Processes (AOPs): current issues and future trends” and published in this book, include topics related with (waste)water treatment and its reuse, disinfection, and pollutant degradation, advancing the know-how of the topics or assessing their integration into the new age of the circular economy of water. Likewise, aspects such as modeling of degradation processes and new materials synthesis were published, aiming to improve, optimize and predict the efficacy of the existing or the novel treatment processes. Moreover, pilot plant operation and large-scale processes were featured, assessing the feasibility of these new treatment methods in real world applications. Overall, the Special Issue and this book present innovative solutions on the field of water and wastewater treatment, with a view on the future technologies that will form the next advances of the field.
emerging pollutants --- advanced oxidation process --- water pollution --- ultrasound --- flower-like Bi2WO6 --- E.coli inactivation --- reactive oxygen species (ROS) --- photocatalysis --- solar disinfection --- water treatment --- pollution --- circular economy --- wastewater reuse --- zero waste --- zero energy --- substances recovery --- sustainable development goals --- heterogeneous photocatalysis --- titanium dioxide --- tin oxide --- graphene oxide --- chemical oxygen demand --- antibiotics --- wastewater --- removal efficiency --- slurry reactor --- computer-based learning --- solar photocatalysis --- water contaminants --- kinetic modeling --- photoreactor design --- UV-LED --- TiO2 --- hexacyanoferrate --- mining --- hydrothermal method --- elimination routes --- fresh urine --- pharmaceutical degradation --- processes selectivity --- theoretical analysis --- advanced oxidation --- membrane technology --- micropollutants --- biological contaminants --- cytotoxicity --- n/a
Choose an application
The papers selected for publication in the Special Issue “Urban and industrial wastewater disinfection and decontamination by Advanced Oxidation Processes (AOPs): current issues and future trends” and published in this book, include topics related with (waste)water treatment and its reuse, disinfection, and pollutant degradation, advancing the know-how of the topics or assessing their integration into the new age of the circular economy of water. Likewise, aspects such as modeling of degradation processes and new materials synthesis were published, aiming to improve, optimize and predict the efficacy of the existing or the novel treatment processes. Moreover, pilot plant operation and large-scale processes were featured, assessing the feasibility of these new treatment methods in real world applications. Overall, the Special Issue and this book present innovative solutions on the field of water and wastewater treatment, with a view on the future technologies that will form the next advances of the field.
Technology: general issues --- emerging pollutants --- advanced oxidation process --- water pollution --- ultrasound --- flower-like Bi2WO6 --- E.coli inactivation --- reactive oxygen species (ROS) --- photocatalysis --- solar disinfection --- water treatment --- pollution --- circular economy --- wastewater reuse --- zero waste --- zero energy --- substances recovery --- sustainable development goals --- heterogeneous photocatalysis --- titanium dioxide --- tin oxide --- graphene oxide --- chemical oxygen demand --- antibiotics --- wastewater --- removal efficiency --- slurry reactor --- computer-based learning --- solar photocatalysis --- water contaminants --- kinetic modeling --- photoreactor design --- UV-LED --- TiO2 --- hexacyanoferrate --- mining --- hydrothermal method --- elimination routes --- fresh urine --- pharmaceutical degradation --- processes selectivity --- theoretical analysis --- advanced oxidation --- membrane technology --- micropollutants --- biological contaminants --- cytotoxicity --- emerging pollutants --- advanced oxidation process --- water pollution --- ultrasound --- flower-like Bi2WO6 --- E.coli inactivation --- reactive oxygen species (ROS) --- photocatalysis --- solar disinfection --- water treatment --- pollution --- circular economy --- wastewater reuse --- zero waste --- zero energy --- substances recovery --- sustainable development goals --- heterogeneous photocatalysis --- titanium dioxide --- tin oxide --- graphene oxide --- chemical oxygen demand --- antibiotics --- wastewater --- removal efficiency --- slurry reactor --- computer-based learning --- solar photocatalysis --- water contaminants --- kinetic modeling --- photoreactor design --- UV-LED --- TiO2 --- hexacyanoferrate --- mining --- hydrothermal method --- elimination routes --- fresh urine --- pharmaceutical degradation --- processes selectivity --- theoretical analysis --- advanced oxidation --- membrane technology --- micropollutants --- biological contaminants --- cytotoxicity
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Today, the food and water that we encounter in any part of the world could contain antibiotic residues and/or antibiotic-resistant bacteria. This book presents research evidence for this and also a potential way to mitigate the problem. Although not presented in this book, it is likely that this situation exists for all other types of antimicrobial agents as well, including antivirals, antifungals, and antiprotozoal agents. The presence of antibiotic residues and/or antibiotic-resistant bacteria contributes to the generation and propagation of resistance in disease-causing pathogens in humans and animals. Therefore, the medicines that we use to treat and/or prevent infections will not work as expected in many cases. It is estimated that if we do not contain antimicrobial resistance urgently, by 2050, up to 10 million people will die due to bacterial infectious diseases, such as pneumonia, skin infections, urinary tract infections, etc., which were once easily treatable. However, this book presents a system that can eliminate resistant bacteria and antibiotics from the environment, with the potential to work on other environmental microbes and antimicrobials. This book opens pathways for academics and scientists to do further research on antimicrobials and antimicrobial-resistant bacteria in various environmental areas and also presents evidence for policymakers to take further action and make the general public aware of the current situation in this context.
Research & information: general --- antibiotic resistance --- community --- environment --- India --- coliforms --- commensal --- antibiotic resistance genes --- blaCTX-M --- blaTEM --- qepA --- hospital wastewater --- core-shell --- disinfection --- Escherichia coli --- nanoparticles --- pathogens --- silver --- solar-photocatalysis --- Staphylococcus aureus --- water --- zinc oxide --- S. aureus --- beaches --- multiple-antibiotic resistance --- ramA --- efflux pump --- multilocus sequence typing --- surface water --- antibiotics --- pakchoi --- endophytic bacteria --- antibiotic-resistant genes --- hydroponic cultivation --- Campylobacter --- poultry --- antibiotic susceptibility --- Rep-PCR --- cdt toxin --- Acinetobacter --- JDS3 --- river --- carbapenemases --- antimicrobial resistance --- genotypes --- non-typhoidal Salmonella --- genes --- integrons --- subtyping --- ESBL --- MRSA --- VRE --- sewage sludge --- PER-1 --- pathogenic E. coli --- harvested rainwater --- public health --- Sub-Saharan Africa --- alternative water source --- farmer --- veterinary antibiotics use --- knowledge --- behavior probability model --- China --- antibiotics residue --- food animals --- bacteria --- Nigeria --- E. coli --- antibiotic-resistance gene --- MARI --- MARP --- multidrug resistance --- flooring design --- Turkey --- antibacterial resistance --- enrofloxacin --- commensal E. coli --- ESBL-producing E. coli --- β-lactamase genes --- insertion sequences --- antibiotic residues --- aquatic environment --- ciprofloxacin --- Fe-doped ZnO nanoparticles --- photocatalysis --- sunlight --- ceragenin --- multidrug-resistant bacteria --- biofilm --- antimicrobial peptides --- colistin --- n/a
Choose an application
Today, the food and water that we encounter in any part of the world could contain antibiotic residues and/or antibiotic-resistant bacteria. This book presents research evidence for this and also a potential way to mitigate the problem. Although not presented in this book, it is likely that this situation exists for all other types of antimicrobial agents as well, including antivirals, antifungals, and antiprotozoal agents. The presence of antibiotic residues and/or antibiotic-resistant bacteria contributes to the generation and propagation of resistance in disease-causing pathogens in humans and animals. Therefore, the medicines that we use to treat and/or prevent infections will not work as expected in many cases. It is estimated that if we do not contain antimicrobial resistance urgently, by 2050, up to 10 million people will die due to bacterial infectious diseases, such as pneumonia, skin infections, urinary tract infections, etc., which were once easily treatable. However, this book presents a system that can eliminate resistant bacteria and antibiotics from the environment, with the potential to work on other environmental microbes and antimicrobials. This book opens pathways for academics and scientists to do further research on antimicrobials and antimicrobial-resistant bacteria in various environmental areas and also presents evidence for policymakers to take further action and make the general public aware of the current situation in this context.
antibiotic resistance --- community --- environment --- India --- coliforms --- commensal --- antibiotic resistance genes --- blaCTX-M --- blaTEM --- qepA --- hospital wastewater --- core-shell --- disinfection --- Escherichia coli --- nanoparticles --- pathogens --- silver --- solar-photocatalysis --- Staphylococcus aureus --- water --- zinc oxide --- S. aureus --- beaches --- multiple-antibiotic resistance --- ramA --- efflux pump --- multilocus sequence typing --- surface water --- antibiotics --- pakchoi --- endophytic bacteria --- antibiotic-resistant genes --- hydroponic cultivation --- Campylobacter --- poultry --- antibiotic susceptibility --- Rep-PCR --- cdt toxin --- Acinetobacter --- JDS3 --- river --- carbapenemases --- antimicrobial resistance --- genotypes --- non-typhoidal Salmonella --- genes --- integrons --- subtyping --- ESBL --- MRSA --- VRE --- sewage sludge --- PER-1 --- pathogenic E. coli --- harvested rainwater --- public health --- Sub-Saharan Africa --- alternative water source --- farmer --- veterinary antibiotics use --- knowledge --- behavior probability model --- China --- antibiotics residue --- food animals --- bacteria --- Nigeria --- E. coli --- antibiotic-resistance gene --- MARI --- MARP --- multidrug resistance --- flooring design --- Turkey --- antibacterial resistance --- enrofloxacin --- commensal E. coli --- ESBL-producing E. coli --- β-lactamase genes --- insertion sequences --- antibiotic residues --- aquatic environment --- ciprofloxacin --- Fe-doped ZnO nanoparticles --- photocatalysis --- sunlight --- ceragenin --- multidrug-resistant bacteria --- biofilm --- antimicrobial peptides --- colistin --- n/a
Choose an application
Today, the food and water that we encounter in any part of the world could contain antibiotic residues and/or antibiotic-resistant bacteria. This book presents research evidence for this and also a potential way to mitigate the problem. Although not presented in this book, it is likely that this situation exists for all other types of antimicrobial agents as well, including antivirals, antifungals, and antiprotozoal agents. The presence of antibiotic residues and/or antibiotic-resistant bacteria contributes to the generation and propagation of resistance in disease-causing pathogens in humans and animals. Therefore, the medicines that we use to treat and/or prevent infections will not work as expected in many cases. It is estimated that if we do not contain antimicrobial resistance urgently, by 2050, up to 10 million people will die due to bacterial infectious diseases, such as pneumonia, skin infections, urinary tract infections, etc., which were once easily treatable. However, this book presents a system that can eliminate resistant bacteria and antibiotics from the environment, with the potential to work on other environmental microbes and antimicrobials. This book opens pathways for academics and scientists to do further research on antimicrobials and antimicrobial-resistant bacteria in various environmental areas and also presents evidence for policymakers to take further action and make the general public aware of the current situation in this context.
Research & information: general --- antibiotic resistance --- community --- environment --- India --- coliforms --- commensal --- antibiotic resistance genes --- blaCTX-M --- blaTEM --- qepA --- hospital wastewater --- core-shell --- disinfection --- Escherichia coli --- nanoparticles --- pathogens --- silver --- solar-photocatalysis --- Staphylococcus aureus --- water --- zinc oxide --- S. aureus --- beaches --- multiple-antibiotic resistance --- ramA --- efflux pump --- multilocus sequence typing --- surface water --- antibiotics --- pakchoi --- endophytic bacteria --- antibiotic-resistant genes --- hydroponic cultivation --- Campylobacter --- poultry --- antibiotic susceptibility --- Rep-PCR --- cdt toxin --- Acinetobacter --- JDS3 --- river --- carbapenemases --- antimicrobial resistance --- genotypes --- non-typhoidal Salmonella --- genes --- integrons --- subtyping --- ESBL --- MRSA --- VRE --- sewage sludge --- PER-1 --- pathogenic E. coli --- harvested rainwater --- public health --- Sub-Saharan Africa --- alternative water source --- farmer --- veterinary antibiotics use --- knowledge --- behavior probability model --- China --- antibiotics residue --- food animals --- bacteria --- Nigeria --- E. coli --- antibiotic-resistance gene --- MARI --- MARP --- multidrug resistance --- flooring design --- Turkey --- antibacterial resistance --- enrofloxacin --- commensal E. coli --- ESBL-producing E. coli --- β-lactamase genes --- insertion sequences --- antibiotic residues --- aquatic environment --- ciprofloxacin --- Fe-doped ZnO nanoparticles --- photocatalysis --- sunlight --- ceragenin --- multidrug-resistant bacteria --- biofilm --- antimicrobial peptides --- colistin --- antibiotic resistance --- community --- environment --- India --- coliforms --- commensal --- antibiotic resistance genes --- blaCTX-M --- blaTEM --- qepA --- hospital wastewater --- core-shell --- disinfection --- Escherichia coli --- nanoparticles --- pathogens --- silver --- solar-photocatalysis --- Staphylococcus aureus --- water --- zinc oxide --- S. aureus --- beaches --- multiple-antibiotic resistance --- ramA --- efflux pump --- multilocus sequence typing --- surface water --- antibiotics --- pakchoi --- endophytic bacteria --- antibiotic-resistant genes --- hydroponic cultivation --- Campylobacter --- poultry --- antibiotic susceptibility --- Rep-PCR --- cdt toxin --- Acinetobacter --- JDS3 --- river --- carbapenemases --- antimicrobial resistance --- genotypes --- non-typhoidal Salmonella --- genes --- integrons --- subtyping --- ESBL --- MRSA --- VRE --- sewage sludge --- PER-1 --- pathogenic E. coli --- harvested rainwater --- public health --- Sub-Saharan Africa --- alternative water source --- farmer --- veterinary antibiotics use --- knowledge --- behavior probability model --- China --- antibiotics residue --- food animals --- bacteria --- Nigeria --- E. coli --- antibiotic-resistance gene --- MARI --- MARP --- multidrug resistance --- flooring design --- Turkey --- antibacterial resistance --- enrofloxacin --- commensal E. coli --- ESBL-producing E. coli --- β-lactamase genes --- insertion sequences --- antibiotic residues --- aquatic environment --- ciprofloxacin --- Fe-doped ZnO nanoparticles --- photocatalysis --- sunlight --- ceragenin --- multidrug-resistant bacteria --- biofilm --- antimicrobial peptides --- colistin
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