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Handbook of Green Analytical Chemistry

M de la Guardia (Autor)

Software / Digital Media
568 Seiten
2012
John Wiley & Sons Inc (Hersteller)
978-1-119-94072-2 (ISBN)
CHF 199,75 inkl. MwSt
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The emerging field of green analytical chemistry is concerned with the development of analytical procedures that minimize consumption of hazardous reagents and solvents, and maximize safety for operators and the environment. In recent years there have been significant developments in methodological and technological tools to prevent and reduce the deleterious effects of analytical activities; key strategies include recycling, replacement, reduction and detoxification of reagents and solvents. The Handbook of Green Analytical Chemistry provides a comprehensive overview of the present state and recent developments in green chemical analysis. A series of detailed chapters, written by international specialists in the field, discuss the fundamental principles of green analytical chemistry and present a catalogue of tools for developing environmentally friendly analytical techniques.

Miguel de la Guardia, Professor of Analytical Chemistry, Valencia University, Spain Professor de la Guardia's research is focused on the automation of analytical methods through multicommutation, sample preparation procedures, chemometrics, development of green analytical methods and development of portable spectrometers. He is a member of the editorial board of Spectroscopy Letters, Ciencia and J. Braz. Chem. Soc., and he was a member of the advisory board of Analytica Chimica Acta from 1995 to 2000. In addition, he is a government consultant for Portugal, Italy, Argentina and China for the evaluation of research proposals and grants. Professor de la Guardia prepared a special issue on Green Spectroscopy in Spectroscopy Letters in 2009, and he is in the process of preparing a special issue on Green Analytical Chemistry for of TrAC which is due to publish in March 2010. Salvador Garrigues, Professor of Analytical Chemistry, Valencia University, Spain Salvador Garrigues works in the research team with Prof. Miguel de la Guardia and has collaborated in more than 150 publications.

List of Contributors xv Preface xix Section I: Concepts 1 1 The Concept of Green Analytical Chemistry 3 Miguel de la Guardia and Salvador Garrigues 1.1 Green Analytical Chemistry in the frame of Green Chemistry 3 1.2 Green Analytical Chemistry versus Analytical Chemistry 7 1.3 The ethical compromise of sustainability 9 1.4 The business opportunities of clean methods 11 1.5 The attitudes of the scientific community 12 References 14 2 Education in Green Analytical Chemistry 17 Miguel de la Guardia and Salvador Garrigues 2.1 The structure of the Analytical Chemistry paradigm 17 2.2 The social perception of Analytical Chemistry 20 2.3 Teaching Analytical Chemistry 21 2.4 Teaching Green Analytical Chemistry 25 2.5 From the bench to the real world 26 2.6 Making sustainable professionals for the future 28 References 29 3 Green Analytical Laboratory Experiments 31 Suparna Dutta and Arabinda K. Das 3.1 Greening the university laboratories 31 3.2 Green laboratory experiments 33 3.2.1 Green methods for sample pretreatment 33 3.2.2 Green separation using liquid-liquid, solid-phase and solventless extractions 37 3.2.3 Green alternatives for chemical reactions 42 3.2.4 Green spectroscopy 45 3.3 The place of Green Analytical Chemistry in the future of our laboratories 52 References 52 4 Publishing in Green Analytical Chemistry 55 Salvador Garrigues and Miguel de la Guardia 4.1 A bibliometric study of the literature in Green Analytical Chemistry 56 4.2 Milestones of the literature on Green Analytical Chemistry 57 4.3 The need for powerful keywords 61 4.4 A new attitude of authors faced with green parameters 62 4.5 A proposal for editors and reviewers 64 4.6 The future starts now 65 References 66 Section II: The Analytical Process 67 5 Greening Sampling Techniques 69 Jose Luis Gomez Ariza and Tamara Garcia Barrera 5.1 Greening analytical chemistry solutions for sampling 70 5.2 New green approaches to reduce problems related to sample losses, sample contamination, transport and storage 70 5.2.1 Methods based on flow-through solid phase spectroscopy 70 5.2.2 Methods based on hollow-fiber GC/HPLC/CE 71 5.2.3 Methods based on the use of nanoparticles 75 5.3 Greening analytical in-line systems 76 5.4 In-field sampling 77 5.5 Environmentally friendly sample stabilization 79 5.6 Sampling for automatization 79 5.7 Future possibilities in green sampling 80 References 80 6 Direct Analysis of Samples 85 Sergio Armenta and Miguel de la Guardia 6.1 Remote environmental sensing 85 6.1.1 Synthetic Aperture Radar (SAR) images (satellite sensors) 86 6.1.2 Open-path spectroscopy 86 6.1.3 Field-portable analyzers 90 6.2 Process monitoring: in-line, on-line and at-line measurements 91 6.2.1 NIR spectroscopy 92 6.2.2 Raman spectroscopy 92 6.2.3 MIR spectroscopy 93 6.2.4 Imaging technology and image analysis 93 6.3 At-line non-destructive or quasi non-destructive measurements 94 6.3.1 Photoacoustic Spectroscopy (PAS) 94 6.3.2 Ambient Mass Spectrometry (MS) 95 6.3.3 Solid sampling plasma sources 95 6.3.4 Nuclear Magnetic Resonance (NMR) 96 6.3.5 X-ray spectroscopy 96 6.3.6 Other surface analysis techniques 97 6.4 New challenges in direct analysis 97 References 98 7 Green Analytical Chemistry Approaches in Sample Preparation 103 Marek Tobiszewski, Agata Mechlinska and Jacek Namiesnik 7.1 About sample preparation 103 7.2 Miniaturized extraction techniques 104 7.2.1 Solid-phase extraction (SPE) 104 7.2.2 Solid-phase microextraction (SPME) 105 7.2.3 Stir-bar sorptive extraction (SBSE) 106 7.2.4 Liquid-liquid microextraction 106 7.2.5 Membrane extraction 108 7.2.6 Gas extraction 109 7.3 Alternative solvents 113 7.3.1 Analytical applications of ionic liquids 113 7.3.2 Supercritical fluid extraction 114 7.3.3 Subcritical water extraction 115 7.3.4 Fluorous phases 116 7.4 Assisted extractions 117 7.4.1 Microwave-assisted extraction 117 7.4.2 Ultrasound-assisted extraction 117 7.4.3 Pressurized liquid extraction 118 7.5 Final remarks 119 References 119 8 Green Sample Preparation with Non-Chromatographic Separation Techniques 125 Maria Dolores Luque de Castro and Miguel Alcaide Molina 8.1 Sample preparation in the frame of the analytical process 125 8.2 Separation techniques involving a gas-liquid interface 127 8.2.1 Gas diffusion 127 8.2.2 Pervaporation 127 8.2.3 Membrane extraction with a sorbent interface 130 8.2.4 Distillation and microdistillation 131 8.2.5 Head-space separation 131 8.2.6 Hydride generation and cold-mercury vapour formation 133 8.3 Techniques involving a liquid-liquid interface 133 8.3.1 Dialysis and microdialysis 133 8.3.2 Liquid-liquid extraction 134 8.3.3 Single-drop microextraction 137 8.4 Techniques involving a liquid-solid interface 139 8.4.1 Solid-phase extraction 139 8.4.2 Solid-phase microextraction 141 8.4.3 Stir-bar sorptive extraction 142 8.4.4 Continuous filtration 143 8.5 A Green future for sample preparation 145 References 145 9 Capillary Electrophoresis 153 Mihkel Kaljurand 9.1 The capillary electrophoresis separation techniques 153 9.2 Capillary electrophoresis among other liquid phase separation methods 155 9.2.1 Basic instrumentation for liquid phase separations 155 9.2.2 CE versus HPLC from the point of view of Green Analytical Chemistry 156 9.2.3 CE as a method of choice for portable instruments 159 9.2.4 World-to-chip interfacing and the quest for a 'killer' application for LOC devices 163 9.2.5 Gradient elution moving boundary electrophoresis and electrophoretic exclusion 165 9.3 Possible ways of surmounting the disadvantages of CE 167 9.4 Sample preparation in CE 168 9.5 Is capillary electrophoresis a green alternative? 169 References 170 10 Green Chromatography 175 Chi-Yu Lu 10.1 Greening liquid chromatography 175 10.2 Green solvents 176 10.2.1 Hydrophilic solvents 176 10.2.2 Ionic liquids 177 10.2.3 Supercritical Fluid Chromatography (SFC) 177 10.3 Green instruments 178 10.3.1 Microbore Liquid Chromatography (microbore LC) 179 10.3.2 Capillary Liquid Chromatography (capillary LC) 180 10.3.3 Nano Liquid Chromatography (nano LC) 181 10.3.4 How to transfer the LC condition from traditional LC to microbore LC, capillary LC or nano LC 182 10.3.5 Homemade micro-scale analytical system 183 10.3.6 Ultra Performance Liquid Chromatography (UPLC) 184 References 185 11 Green Analytical Atomic Spectrometry 199 Martin Resano, Esperanza Garcia-Ruiz and Miguel A. Belarra 11.1 Atomic spectrometry in the context of Green Analytical Chemistry 199 11.2 Improvements in sample pretreatment strategies 202 11.2.1 Specific improvements 202 11.2.2 Slurry methods 204 11.3 Direct solid sampling techniques 205 11.3.1 Basic operating principles of the techniques discussed 205 11.3.2 Sample requirements and pretreatment strategies 207 11.3.3 Analyte monitoring: The arrival of high-resolution continuum source atomic absorption spectrometry 208 11.3.4 Calibration 210 11.3.5 Selected applications 210 11.4 Future for green analytical atomic spectrometry 213 References 215 12 Solid Phase Molecular Spectroscopy 221 Antonio Molina-Diaz, Juan Francisco Garcia-Reyes and Natividad Ramos-Martos 12.1 Solid phase molecular spectroscopy: an approach to Green Analytical Chemistry 221 12.2 Fundamentals of solid phase molecular spectroscopy 222 12.2.1 Solid phase absorption (spectrophotometric) procedures 222 12.2.2 Solid phase emission (fluorescence) procedures 225 12.3 Batch mode procedures 225 12.4 Flow mode procedures 226 12.4.1 Monitoring an intrinsic property 227 12.4.2 Monitoring derivative species 231 12.4.3 Recent flow-SPMS based approaches 232 12.5 Selected examples of application of solid phase molecular spectroscopy 233 12.6 The potential of flow solid phase envisaged from the point of view of Green Analytical Chemistry 235 References 240 13 Derivative Techniques in Molecular Absorption, Fluorimetry and Liquid Chromatography as Tools for Green Analytical Chemistry 245 Jose Manuel Cano Pavon, Amparo Garcia de Torres, Catalina Bosch Ojeda, Fuensanta Sanchez Rojas and Elisa I. Vereda Alonso 13.1 The derivative technique as a tool for Green Analytical Chemistry 245 13.1.1 Theoretical aspects 246 13.2 Derivative absorption spectrometry in the UV-visible region 247 13.2.1 Strategies to greener derivative spectrophotometry 248 13.3 Derivative fluorescence spectrometry 250 13.3.1 Derivative synchronous fluorescence spectrometry 251 13.4 Use of derivative signal techniques in liquid chromatography 254 References 255 14 Greening Electroanalytical Methods 261 Paloma Yanez-Sedeno, Jose M. Pingarron and Lucas Hernandez 14.1 Towards a more environmentally friendly electroanalysis 261 14.2 Electrode materials 262 14.2.1 Alternatives to mercury electrodes 262 14.2.2 Nanomaterial-based electrodes 268 14.3 Solvents 270 14.3.1 Ionic liquids 271 14.3.2 Supercritical fluids 273 14.4 Electrochemical detection in flowing solutions 274 14.4.1 Injection techniques 274 14.4.2 Miniaturized systems 276 14.5 Biosensors 278 14.5.1 Greening biosurface preparation 278 14.5.2 Direct electrochemical transfer of proteins 281 14.6 Future trends in green electroanalysis 282 References 282 Section III: Strategies 289 15 Energy Savings in Analytical Chemistry 291 Mihkel Koel 15.1 Energy consumption in analytical methods 291 15.2 Economy and saving energy in laboratory practice 294 15.2.1 Good housekeeping, control and maintenance 295 15.3 Alternative sources of energy for processes 296 15.3.1 Using microwaves in place of thermal heating 297 15.3.2 Using ultrasound in sample treatment 299 15.3.3 Light as a source of energy 301 15.4 Using alternative solvents for energy savings 302 15.4.1 Advantages of ionic liquids 303 15.4.2 Using subcritical and supercritical fluids 303 15.5 Efficient laboratory equipment 305 15.5.1 Trends in sample treatment 306 15.6 Effects of automation and micronization on energy consumption 307 15.6.1 Miniaturization in sample treatment 308 15.6.2 Using sensors 310 15.7 Assessment of energy efficiency 312 References 316 16 Green Analytical Chemistry and Flow Injection Methodologies 321 Luis Dante Martinez, Soledad Cerutti and Raul Andres Gil 16.1 Progress of automated techniques for Green Analytical Chemistry 321 16.2 Flow injection analysis 322 16.3 Sequential injection analysis 325 16.4 Lab-on-valve 327 16.5 Multicommutation 328 16.6 Conclusions and remarks 334 References 334 17 Miniaturization 339 Alberto Escarpa, Miguel Angel Lopez and Lourdes Ramos 17.1 Current needs and pitfalls in sample preparation 340 17.2 Non-integrated approaches for miniaturized sample preparation 341 17.2.1 Gaseous and liquid samples 341 17.2.2 Solid samples 350 17.3 Integrated approaches for sample preparation on microfluidic platforms 353 17.3.1 Microfluidic platforms in sample preparation process 353 17.3.2 The isolation of analyte from the sample matrix: filtering approaches 356 17.3.3 The isolation of analytes from the sample matrix: extraction approaches 360 17.3.4 Preconcentration approaches using electrokinetics 365 17.3.5 Derivatization schemes on microfluidic platforms 372 17.3.6 Sample preparation in cell analysis 373 17.4 Final remarks 378 References 379 18 Micro- and Nanomaterials Based Detection Systems Applied in Lab-on-a-Chip Technology 389 Mariana Medina-Sanchez and Arben Merkoci 18.1 Micro- and nanotechnology in Green Analytical Chemistry 389 18.2 Nanomaterials-based (bio)sensors 390 18.2.1 Optical nano(bio)sensors 391 18.2.2 Electrochemical nano(bio)sensors 393 18.2.3 Other detection principles 395 18.3 Lab-on-a-chip (LOC) technology 396 18.3.1 Miniaturization and nano-/microfluidics 396 18.3.2 Micro- and nanofabrication techniques 397 18.4 LOC applications 398 18.4.1 LOCs with optical detections 398 18.4.2 LOCs with electrochemical detectors 398 18.4.3 LOCs with other detections 399 18.5 Conclusions and future perspectives 400 References 401 19 Photocatalytic Treatment of Laboratory Wastes Containing Hazardous Organic Compounds 407 Edmondo Pramauro, Alessandra Bianco Prevot and Debora Fabbri 19.1 Photocatalysis 407 19.2 Fundamentals of the photocatalytic process 408 19.3 Limits of the photocatalytic treatment 408 19.4 Usual photocatalytic procedure in laboratory practice 408 19.4.1 Solar detoxification of laboratory waste 409 19.5 Influence of experimental parameters 411 19.5.1 Dissolved oxygen 411 19.5.2 pH 411 19.5.3 Catalyst concentration 412 19.5.4 Degradation kinetics 412 19.6 Additives reducing the e-/h+ recombination 412 19.7 Analytical control of the photocatalytic treatment 413 19.8 Examples of possible applications of photocatalysis to the treatment of laboratory wastes 413 19.8.1 Percolates containing soluble aromatic contaminants 414 19.8.2 Photocatalytic destruction of aromatic amine residues in aqueous wastes 414 19.8.3 Degradation of aqueous wastes containing pesticides residue 415 19.8.4 The peculiar behaviour of triazine herbicides 416 19.8.5 Treatment of aqueous wastes containing organic solvent residues 416 19.8.6 Treatment of surfactant-containing aqueous wastes 416 19.8.7 Degradation of aqueous solutions of azo-dyes 419 19.8.8 Treatment of laboratory waste containing pharmaceuticals 419 19.9 Continuous monitoring of photocatalytic treatment 420 References 420 Section IV: Fields of Application 425 20 Green Bioanalytical Chemistry 427 Tadashi Nishio and Hideko Kanazawa 20.1 The analytical techniques in bioanalysis 427 20.2 Environmental-responsive polymers 428 20.3 Preparation of a polymer-modified surface for the stationary phase of environmental-responsive chromatography 430 20.4 Temperature-responsive chromatography for green analytical methods 432 20.5 Biological analysis by temperature-responsive chromatography 432 20.5.1 Analysis of propofol in plasma using water as a mobile phase 434 20.5.2 Contraceptive drugs analysis using temperature gradient chromatography 435 20.6 Affinity chromatography for green bioseparation 436 20.7 Separation of biologically active molecules by the green chromatographic method 438 20.8 Protein separation by an aqueous chromatographic system 441 20.9 Ice chromatography 442 20.10 High-temperature liquid chromatography 443 20.11 Ionic liquids 443 20.12 The future in green bioanalysis 444 References 444 21 Infrared Spectroscopy in Biodiagnostics: A Green Analytical Approach 449 Mohammadreza Khanmohammadi and Amir Bagheri Garmarudi 21.1 Infrared spectroscopy capabilities 449 21.2 Infrared spectroscopy of bio-active chemicals in a bio-system 451 21.3 Medical analysis of body fluids by infrared spectroscopy 453 21.3.1 Blood and its extracts 455 21.3.2 Urine 457 21.3.3 Other body fluids 457 21.4 Diagnosis in tissue samples via IR spectroscopic analysis 457 21.4.1 Main spectral characteristics 459 21.4.2 The role of data processing 460 21.4.3 Cancer diagnosis by FTIR spectrometry 465 21.5 New trends in infrared spectroscopy assisted biodiagnostics 468 References 470 22 Environmental Analysis 475 Ricardo Erthal Santelli, Marcos Almeida Bezerra, Julio Carlos Afonso, Maria de Fatima Batista de Carvalho, Eliane Padua Oliveira and Aline Soares Freire 22.1 Pollution and its control 475 22.2 Steps of an environmental analysis 476 22.2.1 Sample collection 476 22.2.2 Sample preparation 476 22.2.3 Analysis 479 22.3 Green environmental analysis for water, wastewater and effluent 480 22.3.1 Major mineral constituents 480 22.3.2 Trace metal ions 481 22.3.3 Organic pollutants 483 22.4 Green environmental analysis applied for solid samples 485 22.4.1 Soil 485 22.4.2 Sediments 488 22.4.3 Wastes 492 22.5 Green environmental analysis applied for atmospheric samples 496 22.5.1 Gases 496 22.5.2 Particulates 497 References 497 23 Green Industrial Analysis 505 Sergio Armenta and Miguel de la Guardia 23.1 Greening industrial practices for safety and cost reasons 505 23.2 The quality control of raw materials and end products 506 23.3 Process control 510 23.4 Effluent control 511 23.5 Working atmosphere control 514 23.6 The future starts now 515 References 515 Index 519

Verlagsort New York
Sprache englisch
Maße 189 x 246 mm
Gewicht 666 g
Themenwelt Naturwissenschaften Chemie Analytische Chemie
ISBN-10 1-119-94072-9 / 1119940729
ISBN-13 978-1-119-94072-2 / 9781119940722
Zustand Neuware
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