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  • Instrumental Methods of Analysis

    Instrumental Methods of Analysis by Sivasankar;

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    8 573 Ft

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    A termék adatai:

    • Kiadó OUP India
    • Megjelenés dátuma 2012. május 17.

    • ISBN 9780198073918
    • Kötéstípus Puhakötés
    • Terjedelem600 oldal
    • Méret 241x184x22 mm
    • Súly 776 g
    • Nyelv angol
    • Illusztrációk 200 diagrams
    • 0

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    Rövid leírás:

    Instrumental Methods of Analysis is a textbook designed to introduce various analytical and chemical methods, their underlying principles and applications to the undergraduate engineering students of biotechnology and chemical engineering. This book would also be of interest to students who pursue their B. Sc / M. Sc degree programs in biotechnology and chemistry.

    Több

    Hosszú leírás:

    Instrumental Methods of Analysis is a textbook designed to introduce various analytical and chemical methods, their underlying principles and applications to the undergraduate engineering students of biotechnology and chemical engineering. This book would also be of interest to students who pursue their B. Sc / M. Sc degree programs in biotechnology and chemistry.

    The book starts with a discussion on fundamentals of analytical chemistry, followed by data handling and statistical analysis. Wet chemical methods form the third chapter, where all the conventional titrimetric and gravimetric analysis is dealt with. It then moves onto discuss topics such as the microscopy, optical methods, various spectroscopic methods, X-ray methods, chromatographic methods, electrophoresis, and bulk separation methods. The last few chapters discuss electroanalytical methods,
    thermal, radioanalytical and finally the surface analytical methods.

    Illustrated with block diagrams throughout the text, the book provides review questions, and numerical examples in all relevant chapters.

    Több

    Tartalomjegyzék:

    Introduction to Analytical Chemistry 1
    1.1 Scope and Applications of Analytical Chemistry 1
    1.2 Analytical Process 2
    1.3 Selection of Chemical Reactions for Analysis 2
    1.4 Equilibrium Methods 3
    1.5 Concepts of Chemical Equilibrium 4
    1.6 Types of Equilibria in Aqueous Media 6
    1.6.1 Self-dissociation of Water 6
    1.6.2 Acid-base Equilibria 7
    1.6.3 The pH Scale 8
    1.6.4 Hydrolysis of Salts and the pH of Salt Solutions 9
    1.6.5 Buffer Solutions 10
    1.6.6 Complexation Equilibria 10
    1.6.7 Solubility Equilibria 11
    1.6.8 Redox Equilibria 12
    1.7 Kinetic Methods of Analysis 13
    1.7.1 Experimental Methods for the Determination of Rate of Reaction 15
    1.7.2 Analytical Applications of Kinetic Methods 15
    1.8 Enzyme Catalysed Reactions 16
    1.8.1 Mechanistic and Kinetic Aspects of Enzyme Catalysed Reactions 16
    1.8.2 Applications of Enzymatic Analysis 17
    1.8.3 Substrates as Analytes 18
    1.8.4 Enzymes as Analytes 19
    1.9 Stoichiometric Calculations 20
    1.10 Expression of Concentrations of Solutions 22
    1.11 Reporting of Results 23
    Assessment of Analytical Data 24
    2.1 Introduction 24
    2.2 Definitions of Terms 24
    2.2.1 True Value 24
    2.2.2 Precision 24
    2.2.3 Accuracy 24
    2.2.4 Error 25
    2.2.5 Mean and Median 25
    2.2.6 Spread 25
    2.2.7 Deviation 25
    2.2.8 Population Standard Deviation 25
    2.2.9 Relative Standard Deviation and Coefficient of Variation 26
    2.2.10 Variance 26
    2.2.11 Significant Figures 26
    2.3 Types of Errors 27
    2.3.1 Gross Errors 27
    2.3.2 Systematic Errors or Determinate Errors 27
    2.3.3 Minimizing Systematic Errors 28
    2.3.4 Random Errors or Indeterminate Errors 29
    2.4 Statistical Treatment of Random Errors 29
    2.4.1 Distribution of Random Errors 29
    2.5 Evaluation of Experimental Results 30
    2.5.1 Reliability of Measurements 30
    2.5.2 Analysis of Data 31
    2.6 Comparison of Results 32
    2.6.1 F-test 32
    2.6.2 Student's t-test 33
    2.6.3 Paired t-test 34
    2.7 Standardization of Instrumental Methods of Analysis 35
    2.7.1 Limit of Detection and Limit of Quantitation 35
    2.7.2 Calibration Chart or Curve 35
    2.7.3 Method of Standard Addition 36
    2.7.4 Method of Least Squares 37
    Wet Chemical Methods of Analysis 40
    3.1 Introduction 40
    3.2 Volumetry 40
    3.3 Classification of Volumetric Methods 41
    3.4 Standard Solutions and Standard Substances 41
    3.5 Neutralization Titrations 42
    3.5.1 Theory of Acid-base Indicators 43
    3.5.2 Titration Curves 45
    3.5.3 Titration of a Strong Acid with a Strong Base 45
    3.5.4 Titration of a Weak Acid with a Strong Base 47
    3.5.5 Titration of a Weak Base with a Strong Acid 49
    3.5.6 Titration of a Weak Acid with a Weak Base 49
    3.5.7 Neutralization of Mixtures of Strong and Weak Acids or Strong and Weak Bases 50
    3.5.8 Titration of Polybasic Acids with a Strong Base 50
    3.5.9 Titrations in Non-aqueous Media 51
    3.5.10 Applications of Acid-base Titrations 53
    3.6 Precipitation Titrations 56
    3.6.1 Argentometry 56
    3.6.2 Detection of End Points 58
    3.7 Complexation Titrations 60
    3.7.1 Metal-EDTA Equilibrium 62
    3.7.2 Titration Curves 63
    3.7.3 Metal Ion Indicators 66
    3.7.4 Theory of Metal Ions Indicators 67
    3.7.5 Types of EDTA Titrations 68
    3.7.6 Applications of EDTA Titrations 69
    3.8 Redox Titrations 72
    3.8.1 Redox Indicators 74
    3.8.2 Permanganometry 75
    3.8.3 Dichrometry 76
    3.8.4 Iodometry 76
    3.8.5 Applications of Redox Titrations 77
    3.9 Gravimetry 79
    3.10 Volatilization Methods 80
    3.11 Precipitation Methods 80
    3.11.1 Theoretical Principles of Precipitation Methods 81
    3.11.2 Criteria for an Ideal Gravimetric Estimation 81
    3.11.3 Precipitating Agents 81
    3.11.4 Factors Affecting Solubility of Precipitates 82
    3.11.5 Mechanism of Formation of Precipitates 83
    3.11.6 Colloidal Precipitates 84
    3.11.7 Contamination of Precipitates 84
    3.11.8 Practical Aspects 85
    3.11.9 Homogeneous Precipitation 88
    3.11.10 A Few Examples of Gravimetric Estimations 88
    3.12 A Few Examples of Analysis of Alloys, ORES and Complex Materials by WetChemical Methods 90
    3.12.1 Analysis of an Iron Ore 90
    3.12.2 Analysis of Brass 90
    3.12.3 Analysis of Solder 91
    3.12.4 Analysis of Cement 91
    Optical Methods 96
    4.1 Introduction 96
    4.2 Refraction 96
    4.3 Refractive Index 96
    4.3.1 Measurement of Refractive Index 98
    4.3.2 Abbe Refractometer 98
    4.3.3 Immersion Refractometer 100
    4.3.4 Applications of Refractometry 101
    4.4 Polarimetry 101
    4.4.1 Polarization of Light 101
    4.4.2 Polarizers 103
    4.4.3 Polarimetry Theory 104
    4.4.4 Polarimeter 105
    4.4.5 Applications of Polarimetry 107
    4.5 Optical Rotatory Dispersion and Circular Dichroism Spectra 108
    Microscopy 112
    5.1 Introduction 112
    5.2 Optical Microscope 112
    5.2.1 Compound Light Microscope 112
    5.3 Imaging Techniques 115
    5.3.1 Bright-field Microscopy 115
    5.3.2 Dark-field Microscopy 116
    5.3.3 Phase Contrast Microscopy 118
    5.3.4 Fluorescence Microscope 120
    5.3.5 Confocal Microscopy 120
    5.3.6 Polarizing Microscope 122
    5.3.7 Flow Cytometry 122
    5.4 Electron Microscope 123
    5.4.1 Transmission Electron Microscope 124
    5.4.2 Scanning Electron Microscope 125
    5.4.3 Scanning Transmission Electron Microscope (Stem) 128
    5.5 Scanning Probe Microscopy 128
    5.5.1 Scanning Tunnelling Microscope 128
    5.5.2 Atomic Force Microscope 129
    Spectroscopic Methods of Analysis 132
    6.1 Introduction 132
    6.2 Electromagnetic Radiation 132
    6.2.1 Electromagnetic Spectrum 133
    6.3 Energy Levels in Atoms 134
    6.3.1 Interaction of Electromagnetic Radiation with Atoms 135
    6.4 Energy Levels in Molecules 136
    6.4.1 Interaction of Electromagnetic Radiation with Molecules 137
    6.5 Classification of Spectroscopic Techniques 138
    6.6 Absorption and Emission Spectra 139
    6.6.1 Width of Spectral Lines 139
    6.6.2 Intensity of Spectral Lines 140
    6.7 Analytical Applications of Spectroscopy 142
    6.7.1 Beer-Lambert Law 142
    6.7.2 Applications of Beer-Lambert Law 143
    6.7.2 Limitations to Beer-Lambert's Law 144
    6.8 Visual Colorimetry 145
    6.8.1 Quantitative Analysis 147
    6.8.2 Instruments for Optical Spectrometry and Measurement of Absorbance 148
    6.9 Spectrometers and their Components 149
    6.9.1 Radiation Sources 149
    6.9.2 Dispersing Devices 150
    6.9.3 Sample Holders 158
    6.9.4 Radiation Detectors 158
    6.9.5 Signal Processors and Display Units 163
    6.10 Configurations of Spectrometers 163
    6.11 Fourier Transform Spectrometers 164
    Atomic Spectroscopy 168
    7.1 Introduction 168
    7.2 Classification of Atomic Spectrometric Methods 168
    7.3 Atomization 168
    7.4 Atomization Methods 169
    7.4.1 Flame Atomization 169
    7.4.2 Electrothermal Atomization 171
    7.4.3 Glow Discharge Atomization 172
    7.4.4 Cold-vapour Atomization 172
    7.4.5 Hydride Atomization 172
    7.5 Atomic Absorption Spectrometry 173
    7.5.1 Principle 173
    7.5.2 Atomic Absorption Spectrometer 174
    7.5.3 Working of AAS 177
    7.5.4 Interferences in Atomic Absorption Measurements 179
    7.6 Atomic Emission Spectroscopy 180
    7.6.1 Excitation Methods 180
    7.7 Flame Emission Spectrometry 181
    7.8 Plasma Emission Spectrometry 183
    7.8.1 Inductively Coupled Plasma Atomic Emission Spectroscopy (ICP-AES) 183
    7.8.2 Inductive Coupled Plasma-mass Spectrometry 185
    7.8.3 Direct Current Plasma Atomic Emission Spectroscopy (DCP-AES) 185
    7.8.4 General Features of Plasma Source Spectrometers 186
    7.9 Atomic Fluorescence Spectroscopy 186
    Molecular Spectroscopy 189
    8.1 Introduction 189
    8.2 UV-Visible Spectroscopy 189
    8.2.1 Electronic Spectra of Molecules 189
    8.2.2 Franck-Condon Principle 190
    8.2.3 Electronic Transitions in Organic Molecules 193
    8.2.4 Factors Affecting Absorption Bands 194
    8.2.5 Electronic Transitions in Inorganic Species 196
    8.2.6 UV-visible Spectrophotometer 196
    8.2.7 Analytical Applications of UV-visible Spectroscopy 198
    8.2.8 Simultaneous Determinations 199
    8.2.9 Photometric Titrations 200
    8.2.10 Examples of Spectrophotometric Determinations 201
    8.3 Infrared Spectrophotometry 204
    8.3.1 Infrared Region 204
    8.3.2 Molecular Vibrations 204
    8.3.4 Vibrational Frequencies and IR Absorption Bands 206
    8.3.5 Infrared Spectrum 208
    8.3.6 IR Spectrophotometer 211
    8.3.7 Sample Preparation 213
    8.3.8 Applications 213
    8.3.9 Diffuse Reflectance Infrared Fourier Transform Spectrometry 215
    8.3.10 Attenuated Total Reflectance Spectroscopy 216
    8.3.11 Near Infrared Spectroscopy 216
    8.3.12 Far Infrared Spectroscopy 217
    8.4 Raman Spectroscopy 217
    8.4.1 Comparison of Raman and Infrared Spectra 220
    8.4.2 Raman Spectrometer 220
    8.4.3 Applications of Raman Spectroscopy 221
    8.4.4 Resonance Raman Spectroscopy 222
    8.5 Microwave Spectrometry 223
    8.5.1 Microwave Spectrometer 225
    8.6 Molecular Fluorescence and Phosphorescence 225
    8.6.1 Molecular Fluorescence Spectroscopy 226
    8.6.2 Fluorescent Molecules 227
    8.6.3 Fluorescence and Molecular Structure 227
    8.6.4 Factors Affecting Fluorescence Emission 228
    8.6.5 Analytical Aspects of Fluorescence Emission 229
    8.6.6 Fluorometers 229
    8.6.7 Applications of Fluorescence Measurements 230
    8.6.8 Molecular Phosphorescence Spectroscopy 231
    8.7 Chemiluminescence 231
    8.8 Turbidimetry and Nephelometry 232
    Magnetic Resonance Spectroscopy 236
    9.1 Introduction 236
    9.2 Nuclear Magnetic Resonance Spectroscopy 236
    9.2.1 Theory of Nuclear Magnetic Resonance 236
    9.2.2 Nuclear Energy Levels in an External Magnetic Field 237
    9.2.3 Magnetic Resonance 239
    9.2.4 Classical Model NMR Absorption 239
    9.2.5 Relaxation Processes 241
    9.3 NMR Spectrometers 241
    9.3.1 NMR Spectrum 242
    9.4 Environmental Effects 242
    9.4.1 Chemical Shift 242
    9.4.2 Diamagnetic Anisotropy and Chemical Shift 246
    9.4.3 Spin-spin Coupling 247
    9.4.4 Interpretation of First Order Spectra 248
    9.4.5 Simplification of Complex Spectra 250
    9.5 Nuclear Magnetic Resonance Spectroscopy of Nuclei other than Hydrogen 251
    9.6 Carbon-13 NMR Spectroscopy 251
    9.7 Applications of NMR Spectroscopy 253
    9.8 Fourier Transform NMR Spectroscopy 253
    9.9 Magic Angle Spinning NMR Spectroscopy 254
    9.10 Electron Spin Resonance Spectroscopy 255
    9.10.1 ESR Spectrometer 255
    9.10.2 ESR Spectrum 256
    9.10.3 Hyperfine and Fine Structures in ESR Spectra 257
    9.10.4 Double Resonance 259
    9.10.5 Applications of ESR Spectroscopy 259
    Mass Spectrometry 262
    10.1 Introduction 262
    10.2 Principle 262
    10.3 Mass Spectrometer 263
    10.3.1 Sample Inlet 264
    10.3.2 Ionization Source and Acceleration Chamber 265
    10.3.3 Mass Analyser 265
    10.3.4 Detector 266
    10.3.5 Recording System 266
    10.4 Ionization Methods 266
    10.4.1 Electron Impact Ionization (EI) 267
    10.4.2 Spark Ionization 267
    10.4.3 Chemical Ionization (CI) 267
    10.4.4 Field Ionization (FI) 269
    10.4.5 Field Desorption 269
    10.4.6 Fast Atom/Ion Bombardment (FAB) 269
    10.4.7 Electrospray Ionization (ESI) 270
    10.4.8 Matrix-assisted Laser Desorption/Ionization (MALDI) 271
    10.5 Other types of Mass Spectrometers 271
    10.5.1 Quadrupole Mass Analyser or Spectrometer 271
    10.5.2 Time of Flight Mass Spectrometer 272
    10.5.3 Ion Trap Analyser (Spectrometer) 272
    10.5.4 Fourier Transform Mass Spectrometer 273
    10.6 Tandem Mass Spectrometry 27
    10.7 Interpretation of Mass Spectrum 275
    10.8 Applications 277
    10.8.1 Molecular Weight Determination 278
    10.8.2 Determination of Molecular Formula 280
    10.8.3 Structural Information 284
    10.8.4 Identification of the Sample Compound 285
    10.8.5 Applications in the Study of Proteins and Nucleic Acids 286
    X-ray Methods 288
    11.1 Introduction 288
    11.2 X-ray Spectroscopic Instruments 288
    11.2.1 Production of X-rays by Electron Bombardment 288
    11.2.2 X-rays from Radioactive Sources 292
    11.2.3 Filters 292
    11.2.4 Monochromator, Collimator and Goniometer Assembly 292
    11.2.5 Detectors 293
    11.3 Classification of X-ray Methods 293
    11.4 X-ray Absorption Spectroscopy 294
    11.4.1 Absorption of X-rays 294
    11.4.2 X-ray Absorption Spectrometer 295
    11.4.3 Applications of X-ray Absorption Spectrometry 295
    11.5 X-ray Fluorescence Spectroscopy 296
    11.5.1 Fluorescence Emission of X-rays 296
    11.5.2 X-ray Fluorescence Spectrometer 297
    11.5.3 Applications of X-ray Fluorescence Spectroscopy 299
    11.6 X-ray Emission and Electron Probe Microanalysis 299
    11.7 X-ray Diffraction Methods 300
    Separation Methods 303
    12.1 An Overview of Separation Methods 303
    12.2 Solvent Extraction 304
    12.2.1 Principles of Liquid-liquid Extraction 304
    12.2.2 Selectivity of Extraction 305
    12.2.3 Parameters Affecting the Extraction Process 306
    12.2.4 Extraction Methods 306
    12.2.5 Modes of Extraction 311
    12.3 Aqueous Two-phase Extraction 314
    12.3.1 Aqueous Two-phase Systems 314
    12.3.2 Theoretical Principles of Aqueous Two-phase Extractions 315
    12.3.3 Aqueous Two-phase Extraction Process 316
    12.4 Reversed Micellar Extraction 316
    12.5 Supercritical Fluid Extraction 317
    12.6 Solid Phase Extraction 318
    12.6.1 Solid Phase Micro Extraction 319
    12.7 Ion Exchange Separation 319
    12.7.1 Ion Exchangers 319
    12.7.2 Ion Exchange Equilibrium 320
    12.7.3 Capacity of Ion Exchangers 321
    12.7.4 Regeneration of Ion Exchangers 322
    12.8 Filtration 322
    12.9 Membrane Separation Techniques 323
    12.9.1 Theory of Membrane Separation 324
    12.9.2 Retention Coefficient 324
    12.9.3 Factors Affecting Membrane Separation 325
    12.9.4 Membranes and their Characteristics 326
    12.9.5 Equipment for Membrane Separation 326
    12.9.6 Membrane Separation Methods 327
    12.10 Crystallization 330
    12.11 Precipitation 331
    12.12 Lyophilization 331
    Chromatographic Separations 335
    13.1 Introduction 335
    13.2 Classification of Chromatographic Methods 335
    13.3 Column Chromatography 337
    13.3.1 Principle of Separation in Column Chromatography 337
    13.4 Chromatographic Parameters 339
    13.4.1 Retention Time 339
    13.4.2 Retention Volume 340
    13.4.3 Relative Retention 340
    13.4.4 Column Efficiency 341
    13.4.5 Resolution 342
    13.4.6 Peak Asymmetry 343
    13.4.7 Broadening of Chromatographic Peaks 343
    13.4.8 Optimization of Column Performance 345
    13.4.9 Applications of Chromatography 346
    13.5 Liquid Chromatography 347
    13.5.1 Practice of Liquid Chromatography 347
    13.6 Adsorption Chromatography 349
    13.7 Partition Chromatography 350
    13.7.1 Normal Phase Chromatography 350
    13.7.2 Reversed Phase Chromatography 350
    13.7.3 Hydrophobic Interaction Chromatography 351
    13.8 Ion Exchange Chromatography 352
    13.8.1 Ion Chromatography (IC) 354
    13.9 Size Exclusion Chromatography (SEC) 355
    13.10 Affinity Chromatography 360
    13.11 High Performance Liquid Chromatography 361
    13.11.1 Principle 362
    13.11.2 HPLC Instrument 362
    13.11.3 Practice of HPLC 366
    13.11.4 Applications of HPLC 367
    13.11.5 HPLC-Mass Spectrometry (HPLC-MS) 368
    13.12 Supercritical Fluid Chromatography (SCFC) 369
    13.12.1 Supercritical Fluid Solvents and Their Properties 369
    13.12.2 SCFC Instrument 370
    13.13 Gas Chromatography 371
    13.13.1 Principle 371
    13.13.2 GC Instrument 371
    13.13.3 Hyphenated or Coupled Chromatographic Techniques 376
    13.13.4 Practice of GC 378
    13.13.5 Qualitative Analysis by Gas Chromatography 380
    13.13.6 Quantitative Analysis by Gas Chromatography 381
    13.14 Planar Chromatographic Techniques 381
    13.14.1 Paper Chromatography (PC) 381
    13.14.2 Thin Layer Chromatography (TLC) 383
    13.14.3 Two-dimensional Planar Chromatography 385
    13.14.4 High Performance Thin Layer Chromatography (HPTLC) 386
    13.14.5 Applications of Planar Chromatographic Techniques 386
    13.14.6 Developments in Planar Chromatographic Techniques 387
    Electrophoresis and Related Techniques of Separation 391
    14.1 Introduction 391
    14.2 Electrophoresis 391
    14.2.1 Free Solution Electrophoresis 392
    14.2.2 Zone Electrophoresis 393
    14.2.3 Polyacrylamide Gel Electrophoresis (PAGE) 393
    14.2.4 Native Gel Electrophoresis 394
    14.2.5 Disc Gel Electrophoresis 396
    14.2.6 Sodium Dodecyl Sulphate-polyacrylamide Gel Electrophoresis (SDS-PAGE) 397
    14.2.7 Agarose Gel Electrophoresis 398
    14.2.8 Parameters Affecting Gel Electrophoretic Separations 398
    14.2.9 Detection of Proteins and Nucleic Acids in Electrophoresis Gels 398
    14.2.10 Pulsed Field Gel Electrophoresis (PFGE) 399
    14.2.11 Applications of Electrophoresis Techniques 400
    14.3 Immunoelectrophoresis 400
    14.4 Capillary Electrophoresis 400
    14.4.1 Micellar Electrokinetic Capillary Chromatography 402
    14.4.2 Capillary Gel Electrophoresis 403
    14.4.3 Capillary Electrochromatography 403
    14.5 Isoelectric Focusing 404
    14.6 Two-dimensional Electrophoresis 406
    14.7 Isotachophoresis 406
    Centrifugation 409
    15.1 Introduction 409
    15.2 Centrifugal Force 409
    15.3 Principles of Centrifugal Sedimentation 411
    15.4 Centrifuges 414
    15.4.1 Rotors 415
    15.5 Centrifugation Techniques 418
    15.6 Differential Centrifugation 418
    15.7 Density Gradient Centrifugation 419
    15.7.1 Sample Application and Harvesting Samples from Gradients 421
    15.7.2 Density Gradient Centrifugation Techniques 422
    15.8 Centrifugal Elutriation 423
    15.9 Ultracentrifuge 423
    15.9.1 Analytical Ultracentrifuge 423
    15.9.2 Applications of Analytical Ultracentrifuge 424
    15.9.3 Determination of Molecular Weight of Macromolecules 424
    15.9.3 Determination of Purity of Macromolecules 426
    15.9.4 Study of Conformation Changes in Macromolecules 426
    15.10 Preparative Ultracentrifuge 426
    Electroanalytical Methods 428
    16.1 Introduction 428
    16.2 Classification of Electroanalytical Techniques 428
    16.3 Conductometry 429
    16.3.1 Measurement of Conductance 430
    16.3.2 Applications of Conductance Measurements 431
    16.4 Conductance Titrations 432
    16.4.1 Acid-base Reactions 433
    16.4.2 Displacement Titrations 434
    16.4.3 Precipitation Titrations 435
    16.4.4 Complex-formation Reactions 435
    16.4.5 Titrations in Non-aqueous Media 436
    16.5 Oscillometric or High-frequency Titrations 436
    16.6 Principles of Electrogravimetry and Coulometry 437
    16.7 Electrogravimetry 437
    16.8 Coulometry 438
    16.8.1 Constant Potential Coulometry 438
    16.8.2 Constant Current Coulometry 439
    16.9 Potentiometry 442
    16.9.1 Thermodynamic Significance of Electrode Potentials 443
    16.9.2 Indicator Electrodes 444
    16.9.3 Reference Electrodes 446
    16.9.4 EMF Measurement 447
    16.9.5 Standard Weston Cadmium Cell 448
    16.10 Applications of EMF Measurements 449
    16.10.1 Determination of pH by Glass Electrode 449
    16.10.2 pH Titrations 450
    16.10.3 Potentiometric Titrations 451
    16.11 Ion Selective Electrodes 453
    16.11.1 Different Types of Ion Selective Electrodes 453
    16.12 Polarography 454
    16.12.1 Quantitative Analysis by Polarography 458
    16.12.3 Modern Polarographic Techniques 459
    16.13 Amperometric Titrations 461
    16.13.1 Amperometric Titrations with One Polarizable Indicator Electrode 462
    16.13.2 Biamperometric Titrations 464
    16.13.3 A Few Important Applications of Amperometry 465
    16.13.4 Oxygen Sensor 466
    16.13.5 Biosensors 466
    Thermal Analytical Methods 470
    17.1 Introduction 470
    17.2 Thermogravimetry (TG) 470
    17.2.1 TG Instrument 471
    17.2.2 Thermogram 472
    17.2.3 Applications of Thermogravimetry 473
    17.3 Differential Thermal Analysis (DTA) 476
    17.3.1 DTA Instrument 476
    17.3.2 DTA Thermogram 477
    17.4 Differential Scanning Calorimetry (DSC) 478
    17.4.1 DSC Instrument 478
    17.4.2 Applications of DTA and DSC 479
    17.5 Thermomechanical Analysis (TMA) 483
    17.5.1 TMA Instrument 483
    17.5.2 Applications of TMA 484
    17.6 Dynamic Mechanical Analysis (DMA) 485
    17.6.1 DMA Instrument 485
    17.6.2 DMA Applications 486
    17.7 Evolved Gas Analysis 487
    17.7.1 Pyrolysis Gas Chromatograph Instrument 487
    Radiochemical Methods of Analysis 490
    18.1 Introduction 490
    18.2 Origin of Radioactivity 490
    18.2.1 Decay Modes of Radioactive Isotopes 491
    18.2.2 Kinetics of Radioactive Decay Process 492
    18.2.3 Units of Radioactivity 493
    18.3 Measurement of Radioactivity 493
    18.3.1 Detectors Based on Ionization 494
    18.3.2 Detectors Based on Photo Effect 497
    18.4 Detector Based on Chemical Reaction 498
    18.5 amplifiers and Other Electronic Equipment 498
    18.6 Pulse Height Analyser 498
    18.7 Analytical Applications of Radioisotopes 499
    18.7.1 Isotope Dilution Method 499
    18.7.2 Activation Analysis 500
    18.7.3 Radioimmuno Assay 502
    18.7.4 Autoradiography 504
    Surface Analytical Methods 506
    19.1 Introduction 506
    19.2 Classification of Surface Analytical Methods 506
    19.3 Methods Based on Adsorption-desorption of Probe Molecules 507
    19.3.1 Physisorption 507
    19.3.2 Chemisorption 510
    19.4 Vibrational Spectroscopic Techniques for Surface Studies 510
    19.4.1 IR Spectroscopy 511
    19.4.3 Electron Energy Loss Spectroscopy 512
    19.4.4 Reflection-absorption Infrared Spectroscopy 513
    19.5 Electronic Spectroscopic Methods 513
    19.5.1 Electron Spectroscopy for Chemical Analysis 514
    19.5.2 Auger Electron Spectroscopy 519
    19.5.3 Ion Scattering Spectrometry 521
    19.5.4 Secondary Ion Mass Spectrometry 522
    19.6 X-ray Methods 524
    19.7 Thermal Methods 524
    19.7.1 Temperature Programmed Desorption 524
    19.7.2 Temperature Programmed Reduction 528
    19.7.3 Desorption Studies by TG, DTA and DSC 529

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