Chemistry of advanced environmental purification processes of water : fundamentals and applications /

Chemistry of Advanced Environmental Purification Processes of Water covers the fundamentals behind a broad spectrum of advanced purification processes for various types of water, showing numerous applications through worked examples. Purification processes for groundwater, soil water, reusable water...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Sogaard, Erik (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Amsterdam : Elsevier, 2014.
Temas:
Water > Purification.
Environmental chemistry.
Water chemistry.
Water > Pollution.
Eau > �Epuration.
Chimie de l'environnement.
Eau > Chimie.
TECHNOLOGY & ENGINEERING > Environmental > General.
Environmental chemistry
Water chemistry
Water > Pollution
Water > Purification
waterzuivering
water treatment
zuiveren
purification
grondwater
groundwater
bodemwater
soil water
technologie
technology
engineering
Water Management (General)
Waste Water Treatment
Waterbeheer (algemeen)
Afvalwaterbehandeling
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover; Chemistry of Advanced Environmental Purification Processes of Water: Fundamentalsand Applications; Copyright; Dedication; Contents; Contributors; Introduction; Chapter 1
  • Water and Water Cycle; 1.1 ORIGIN OF WATER; 1.2 RAINWATER, GROUNDWATER AND DRINKING WATER; 1.3 WASTEWATER; Reference; Chapter 2
  • In situ Chemical Oxidation: The Mechanisms and Applications of Chemical Oxidants for Remediation Purposes; 2.1 INTRODUCTION; 2.2 FUNDAMENTALS OF ISCO; 2.3 CASE STUDY: K�RGAARD PLANTATION; 2.4 BENCH AND PILOT TESTS; 2.5 METAL MOBILISATION; 2.6 SCAVENGING OF HYDROXYL RADICALS.
  • 2.7 CONCLUSION2.8 PERSPECTIVES AND FUTURE RESEARCH; ABBREVIATIONS; References; Chapter 3
  • Electrochemical Oxidation
  • A Versatile Technique for Aqueous Organic Contaminant Degradation; 3.1 INTRODUCTION; 3.2 THE PRINCIPLE AND MECHANISMS IN EO; 3.3 THE VERSATILITY OF EO DEGRADATION; 3.4 THE CHALLENGE OF MINIMISING THE BY-PRODUCT FORMATION; 3.5 EXAMPLES OF APPLICATION OF EO; 3.6 IMPLEMENTATION OF EO IN LARGE SCALE
  • COMBINED TREATMENT; 3.7 PERSPECTIVES; References; Chapter 4
  • Heterogeneous Photocatalysis; 4.1 INTRODUCTION; 4.2 THE PRINCIPLE AND MECHANISMS IN SEMICONDUCTOR PHOTOCATALYSIS.
  • 4.3 TIO2 PHOTOCATALYSIS4.4 CASE STUDY 1
  • PHOTOCATALYTIC OXIDATION OF DISINFECTION BY-PRODUCTS IN SWIMMING POOL WATER; 4.5 CASE STUDY 2
  • COMPARISON OF THE OXIDATION EFFICIENCY OF UV-ACTIVATED AOP TECHNIQUES; 4.6 SUMMARY; References; Chapter 5
  • Near- and Supercritical Water; 5.1 PROPERTIES OF THE SUPERCRITICAL PHASE; 5.2 PROPERTIES OF SUPERCRITICAL WATER; 5.3 APPLICATIONS OF SUPERCRITICAL WATER; 5.4 SUMMARY; References; Chapter 6
  • Membrane Filtration in Water Treatment
  • Removal of Micropollutants; 6.1 INTRODUCTION; 6.2 TYPES OF MEMBRANES AND MEMBRANE PROCESSES.
  • 6.3 FILTRATION TECHNIQUES AND MEMBRANE MODULE CONFIGURATION6.4 FILTRATION THEORY
  • CONCEPTS AND MODELS; 6.5 ISSUES FOR MEMBRANES FILTRATION
  • FOULING AND SCALING; 6.6 VERSATILITY OF MEMBRANES
  • EXAMPLES OF APPLICATIONS; 6.7 MEMBRANES FOR MICROPOLLUTANT REMOVAL; 6.8 MEMBRANES IN AOPS; References; Chapter 7
  • Advanced Iron Oxidation at Drinking Water Treatment Plants; 7.1 DRINKING WATER TREATMENT IN DENMARK; 7.2 DRINKING WATER STANDARDS IN THE EU AND DENMARK; 7.3 A TYPICAL DRINKING WTP FOR SIMPLE WATER TREATMENT IN DENMARK (VR. GJESING WTP).
  • 7.4 ASTRUP DRINKING WTP USING ADVANCED BIOLOGICAL FILTRATION7.5 BIOTIC CONDITIONS FOR IRON PRECIPITATION; 7.6 FUNCTIONS OF EXOPOLYMERS IN SAND FILTERS; 7.7 CONTENT OF THE FE BACTERIAL STALK; 7.8 CONCLUSION; References; Chapter 8
  • Advanced Arsenic Removal Technologies Review; 8.1 INTRODUCTION; 8.2 REMOVAL TECHNOLOGIES; 8.3 ARSENIC IN STABILE SOLID STATE; 8.4 EXAMPLE OF THE SIMPLE ARSENIC REMOVAL TECHNOLOGY; References; Index.

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