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Instrumental Methods of Analysis [Pehme köide]

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  • Formaat: Paperback / softback, 384 pages, kõrgus x laius: 238x156 mm
  • Ilmumisaeg: 30-Jan-2020
  • Kirjastus: CBS Publishers & Distributors
  • ISBN-10: 8123923279
  • ISBN-13: 9788123923277
Teised raamatud teemal:
Instrumental Methods of AnalysisSuurem pilt
  • Formaat: Paperback / softback, 384 pages, kõrgus x laius: 238x156 mm
  • Ilmumisaeg: 30-Jan-2020
  • Kirjastus: CBS Publishers & Distributors
  • ISBN-10: 8123923279
  • ISBN-13: 9788123923277
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9788123923277.html
The book is designed to introduce the recent developments and changes of various analytical techniques their underlying principles instrumentations and applications. It comprehensively covers fundamental information and applications of analytical techniques and provides precise sketches and flow sheets to understand the analytical techniques obviously and discusses different techniques such as microscopy centrifugation spectroscopy chromatography.

This book also explains the functional aspects of all instruments to provide working knowledge of their instrumentation principle and applications. It provides an understanding of analytical techniques for all undergraduate and postgraduate students of biotechnology chemical engineering pharmacy biochemistry microbiology and chemistry teaching and academic research.

The book is designed to introduce the recent developments and changes of various analytical techniques their underlying principles instrumentations and applications.
Foreword iii
Preface v
1 Introduction
1(196)
1.0 Introduction
1.0.1 Methods of detecting analytes
1.0.2 Analytical targets
1.1 Analytical Types
1.1.1 Qualitative analysis
1.1.2 Quantitative analysis
1.2 Volumetric Analysis Or Titration
1.3 Gravimetry
1.3.1 The Universal law of Gravitation
1.4 Precipitation
1.4.1 Conditions for precipitation
1.4.2 Factors Affecting Precipitation
1.5 Traditional Analytical Techniques
1.5.1 Spectroscopy
1.5.2 Mass spectroscopy
1.5.3 Crystallography
1.5.4 Electrochemical analysis
1.5.5 Thermal analysis
1.5.6 Separation techniques
1.5.7 Hyphenated techniques
1.5.8 Microscopy
4.7 Spectroscopy
4.7.1 Introduction
4.7.2 Spectroscopy Types
4.8 Uv-Visible Spectroscopy
4.8.1 Nature of Electronic Transitions
4.8.2 Principle of Absorption Spectroscopy
4.8.3 Instrumentation
4.8.4 UV-Visible absorption spectra
4.8.5 Importance of conjugation
4.9 Spectrofluorimeter
4.9.1 Fluorescence
4.9.2 Phosphorescence
4.9.3 Singlet and Triplet states
4.9.4 Excited state processes in molecules
4.9.5 Principle
4.9.6 Instrumentation
4.9.7 Applications
4.10 Atomic Absorption Spectroscopy
4.10.1 Introduction
4.10.2 Principle
4.10.3 Interferences
4.10.4 Broadening of a spectra line
4.10.5 Instrumentation
4.10.6 Applications
4.11 Atomic Emission Spectroscopy
4.11.1 Principle
4.11.2 Instrumentation
4.11.3 Applications
4.12 Circular Dichroism (Cd)
4.12.1 Dichroism
4.12.2 Circular dichroism
4.12.3 Principle or Operation
4.12.4 Performance
4.12.5 Applications
4.13 Summary
5 Spectroscopy-II
197(37)
5.1 Infrared Spectroscopy
5.1.1 Introduction
5.1.2 Principle
5.1.3 Instrumentation
5.1.4 Applications
5.2 Mass Spectroscopy
5.2.1 History
5.2.2 Principle
5.2.3 Instrumentation
5.2.4 Nature of mass spectra
5.2.5 Applications
5.3 Electron Spin Resonance Spectroscopy
5.3.1 Introduction
5.3.2 Principle
5.3.3 Instrumentation
5.3.4 Applications
5.4 Summary
6 Online Monitoring And Control Devices
234(37)
6.0 Ph
6.0.1 pH Measurement
6.0.2 pH System
6.1 Temperature
6.1.1 Thermometer
6.1.2 Thermistors
6.1.3 Temperature controller
6.2 Dissolved Oxygen
6.2.1 Temperature effect
6.2.2 Environmental impact
6.2.3 Dissolved oxygen affects in water supplies
6.2.4 Oxygen electrode
6.3 Agitation
6.3.1 Mixing features and properties
6.3.2 Mixing equipments
6.4 Sensor
6.5 X-Rays
6.5.1 X-rays source
6.5.2 Diffractometer
6.5.3 Electron density
6.5.4 Crystals
6.5.5 X-ray diffraction
6.5.6 Bragg's law
6.5.7 Fourier theory
6.5.8 Production and detection of X-rays
6.5.9 Limitations
6.5.10 Applications
6.6 Summary
7 Separation Techniques
271(47)
7.0 High Performance Liquid Chromatography (Hplc)
7.0.1 Introduction
7.0.2 Instrumentation
7.0.3 Applications
7.1 Gas Chromatography
7.1.1 Introduction
7.1.2 Principle
7.1.3 Apparatus
7.1.4 Applications
7.2 Ion-Exchange Chromatography
7.2.1 Introduction
7.2.2 Cation exchange resins
7.2.3 Anion exchange resins
7.2.4 Types of ionisable groups
7.2.5 Ion exchange equilibrium
7.2.6 Basis for separations
7.2.7 Principle
7.2.8 Applications
7.3 Gel Filtration Chromatography
7.3.1 Introduction
7.3.2 Principle
7.3.3 Applications
7.4 Affinity Chromatography
7.4.1 Introduction
7.4.2 Matrix
7.4.3 Ligand
7.4.4 Principle
7.4.5 Applications
7.5 Membrane Separation
7.5.1 Ultra filtration (UF)
7.5.2 Reverse osmosis
7.5.3 Diffusion/Dialysis
7.6 Summary
8 Nuclear Magnetic Resonance Spectroscopy
318(26)
8.1 Introduction
8.2 Nuclear Spin And Magnetic Moment
8.2.1 Spinning nuclei-magnetic moments
8.2.2 Magnetic moment and magnetic field
8.3 Types
8.3.1 Low resolution NMR
8.3.2 High resolution NMR
8.3.3 Instrument components
8.4 Principle
8.5 Frequency Lock
8.6 Double Resonance Or Spin Decoupling
8.7 Nuclear Overhauser Effect (Noe)
8.8 Carbon-13 Nmr Spectroscopy
8.9 Fourier Transform (Ft) Nmr
8.9.1 Advantages
8.10 Applications
8.11 Summary
Glossary 344(20)
Index 364