Adsorption Technology in Water Treatment: Fundamentals, Processes, and Modeling
376
Adsorption Technology in Water Treatment: Fundamentals, Processes, and Modeling
376eBook2nd rev. ed. (2nd rev. ed.)
Available on Compatible NOOK devices, the free NOOK App and in My Digital Library.
Related collections and offers
Overview
This book treats the theoretical fundamentals of adsorption technology for water treatment from a practical perspective. It presents all the basics needed for experimental adsorption studies as well as for process modeling and adsorber design. According to the increasing importance of micropollutants in the water cycle, particular attention is paid to their competitive adsorption in the presence of background organic matter.
The current edition considers recent developments in adsorption theory and practice.
Product Details
| ISBN-13: | 9783110715606 |
|---|---|
| Publisher: | De Gruyter |
| Publication date: | 04/19/2021 |
| Sold by: | Barnes & Noble |
| Format: | eBook |
| Pages: | 376 |
| File size: | 8 MB |
| Age Range: | 18 Years |
About the Author
Table of Contents
Preface xi
1 Introduction 1
1.1 Basic concepts and definitions 1
1.1.1 Adsorption as a surface process 1
1.1.2 Some general thermodynamic considerations 2
1.1.3 Adsorption versus absorption 3
1.1.4 Description of adsorption processes: The structure of the adsorption theory 3
1.2 Engineered adsorption processes in water treatment 5
1.2.1 Overview 5
1.2.2 Drinking water treatment 6
1.2.3 Wastewater treatment 6
1.2.4 Hybrid processes in water treatment 7
1.3 Natural sorption processes in water treatment 8
2 Adsorbents and adsorbent characterization 11
2.1 Introduction and adsorbent classification 11
2.2 Engineered adsorbents 12
2.2.1 Activated carbon 12
2.2.2 Polymeric adsorbents 15
2.2.3 Oxidic adsorbents 16
2.2.4 Synthetic zeolites 17
2.3 Natural and low-cost adsorbents 18
2.4 Geosorbents in environmental compartments 19
2.5 Adsorbent characterization 20
2.5.1 Densities 20
2.5.2 Porosities 22
2.5.3 External surface area 23
2.5.4 Internal surface area 25
2.5.5 Pore-size distribution 28
2.5.6 Surface chemistry 34
3 Adsorption equilibrium I: General aspects and single-solute adsorption 41
3.1 Introduction 41
3.2 Experimental determination of equilibrium data 42
3.2.1 Basics 42
3.2.2 Practical aspects of isotherm determination 45
3.3 Isotherm equations for single-solute adsorption 47
3.3.1 Classification of single-solute isotherm equations 47
3.3.2 Irreversible isotherm and one-parameter isotherm 48
3.3.3 Two-parameter isotherms 49
3.3.4 Three-parameter isotherms 55
3.3.5 Isotherm equations with more than three parameters 58
3.4 Prediction of isotherms 59
3.5 Temperature dependence of adsorption 64
3.6 Slurry adsorber design 67
3.6.1 General aspects 67
3.6.2 Single-stage adsorption 69
3.6.3 Two-stage adsorption 72
3.7 Application of isotherm data in kinetic or breakthrough curve models 74
4 Adsorption equilibrium II: Multisolute adsorption 77
4.1 Introduction 77
4.2 Experimental determination of equilibrium data 78
4.3 Overview of existing multisolute adsorption models 80
4.4 Multisolute isotherm equations 81
4.5 The ideal adsorbed solution theory (LAST) 84
4.5.1 Basics of the IAST 84
4.5.2 Solution to the IAST for given equilibrium concentrations 88
4.5.3 Solution to the IAST for given initial concentrations 90
4.6 The pH dependence of adsorption: A special case of competitive adsorption 94
4.7 Adsorption of natural organic matter (NOM) 98
4.7.1 The significance of NOM in activated carbon adsorption 98
4.7.2 Modeling of NOM adsorption: The fictive component approach (adsorption analysis) 100
4.7.3 Competitive adsorption of micropollutants and NOM 104
4.8 Slurry adsorber design for multisolute adsorption 111
4.8.1 Basics 111
4.8.2 NOM adsorption 112
4.8.3 Competitive adsorption of micropollutants and NOM 113
4.8.4 Nonequilibrium adsorption in slurry reactors 118
4.9 Special applications of the Active component approach 120
5 Adsorption kinetics 123
5.1 Introduction 123
5.2 Mass transfer mechanisms 123
5.3 Experimental determination of kinetic curves 124
5.4 Mass transfer models 127
5.4.1 General considerations 127
5.4.2 Film diffusion 129
5.4.3 Surface diffusion 136
5.4.4 Pore diffusion 143
5.4.5 Combined surface and pore diffusion 149
5.4.6 Simplified intraparticle diffusion model (LDF model) 153
5.4.7 Reaction kinetic models 162
5.4.8 Adsorption kinetics in multicomponent systems 164
5.5 Practical aspects: Slurry adsorber design 166
6 Adsorption dynamics in fixed-bed adsorbers 169
6.1 Introduction 169
6.2 Experimental determination of breakthrough curves 175
6.3 Fixed-bed process parameters 176
6.4 Material balances 179
6.4.1 Types of material balances 179
6.4.2 Integral material balance 179
6.4.3 Differential material balance 185
6.5 Practical aspects 189
6.5.1 Introduction 189
6.5.2 Typical operating conditions 190
6.5.3 Fixed-bed versus batch adsorber 191
6.5.4 Multiple adsorber systems 193
7 Fixed-bed adsorber design 197
7.1 Introduction and model classification 197
7.2 Scale-up methods 198
7.2.1 Mass transfer zone (MTZ) model 198
7.2.2 Length of unused bed (LUB) model 202
7.2.3 Rapid small-scale column test (RSSCT) 203
7.3 Equilibrium column model (ECM) 207
7.4 Complete breakthrough curve models 211
7.4.1 Introduction 211
7.4.2 Homogeneous surface diffusion model (HSDM) 213
7.4.3 Constant pattern approach to the HSDM (CPHSDM) 217
7.4.4 Linear driving force (LDF) model 220
7.4.5 Comparison of HSDM and LDF model 224
7.4.6 Simplified breakthrough curve models with analytical solutions 226
7.5 Determination of model parameters 232
7.5.1 General considerations 232
7.5.2 Single-solute adsorption 233
7.5.3 Competitive adsorption in defined multisolute systems 238
7.5.4 Competitive adsorption in complex systems of unknown composition 238
7.6 Special applications of breakthrough curve models 240
7.6.1 Micropollutant adsorption in presence of natural organic matter 240
7.6.2 Biologically active carbon filters 248
8 Desorption and reactivation 253
8.1 Introduction 253
8.2 Physicochemical regeneration processes 254
8.2.1 Desorption into the gas phase 254
8.2.2 Desorption into the liquid phase 256
8.3 Reactivation 261
9 Geosorption processes in water treatment 265
9.1 Introduction 265
9.2 Experimental determination of geosorption data 267
9.3 The advection-dispersion equation (ADE) and the retardation concept 268
9.4 Simplified method for determination of Rd from experimental breakthrough curves 271
9.5 Breakthrough curve modeling 273
9.5.1 Introduction and model classification 273
9.5.2 Local equilibrium model (LEM) 275
9.5.3 Linear driving force (LDF) model 277
9.5.4 Extension of the local equilibrium model 279
9.6 Combined sorption and biodegradation 280
9.6.1 General model approach 280
9.6.2 Special case: Natural organic matter (NOM) sorption and biodegradation 285
9.7 The influence of pH and NOM on geosorption processes 287
9.7.1 pH-dependent sorption 287
9.7.2 Influence of NOM on micropollutant sorption 289
9.8 Practical aspects: Prediction of subsurface solute transport 291
9.8.1 General considerations 291
9.8.2 Prediction of sorption coefficients 293
9.8.3 Prediction of the dispersivity 295
10 Appendix 297
10.1 Conversion of Freundlich coefficients 297
10.2 Evaluation of surface diffusion coefficients from experimental data 298
10.3 Constant pattern solution to the homogeneous surface diffusion model (CPHSDM) 302
Nomenclature 307
References 319
Index 327