| Description |
1 online resource (207 p.) |
| Series |
Advances in Dye Degradation Series ; v.1 |
|
Advances in Dye Degradation Series
|
| Contents |
Cover -- Title -- Copyright -- End User License Agreement -- Contents -- Foreword -- Preface -- List of Contributors -- Dye Degradation -- Basics and Necessity -- Kiruthiga Kandasamy1, Sheeba Daniel2, Poovan Shanmugavelan3 and Paulpandian Muthu Mareeswaran4,* -- INTRODUCTION -- NATURAL DYES -- ADVANTAGES OF NATURAL DYES -- LIMITATIONS OF NATURAL DYES -- Cost -- Colour -- Availability -- Harmful Effects -- Sustainability -- SYNTHETIC DYES -- CLASSIFICATION OF DYES BASED ON APPLICATION -- Direct Dyes -- Reactive Dyes -- Basic Dyes -- Acid Dyes -- Mordant or Chrome Dyes -- Disperse Dyes |
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Vat Dyes -- Sulphur Dyes -- Azoic Dyes -- ADVANTAGES OF SYNTHETIC DYES -- TOXIC EFFECT OF SYNTHETIC DYES -- DYE DEGRADATION TECHNIQUES -- PHYSICAL PROCESSES -- Adsorption -- Filtration -- Ion Exchange -- CHEMICAL PROCESSES -- Advanced Oxidation -- Photolysis -- Photocatalysis -- Sonolysis -- Electrochemical Dye Degradation Process -- Fenton Process -- Ozonolysis -- BIOLOGICAL PROCESSES -- Biosorption -- Bioaccumulation and Bioremediation -- Mineralization and Alleviation -- CONCLUSION -- REFERENCES -- Toxicity Analysis of Dyes -- Arumugam Girija1,* and Paulpandian Muthu Mareeswaran2 |
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INTRODUCTION -- TOXICITY -- Toxic Effects -- Toxicological Field Studies -- Priorities in the Selection of Toxic Chemicals for Testing -- The Extent of the Toxicity Requirement -- Toxicity Assessment -- DOSE -- Toxicological Dose Descriptors -- LD50 (Lethal Dose 50%) -- LC50 (Lethal Concentration 50%) -- No Observed Adverse Effect Level (NOAEL) -- Lowest Observed Adverse Effect Level (LOAEL) -- T25 and BMD10 -- Median Effective Concentration (EC50) -- No Observed Effect Concentration (NOEC) -- DT50 -- Effect and Response -- Dose Effect and Dose-Response Curves |
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Toxic Effects Due to Combination of Dyes -- Acute, Sub-acute, Sub-chronic and Chronic Toxic Assessment -- Acute toxicity assessment -- Experimental Design -- Selection of Species -- Selection of Doses -- Method of Administration -- Sub-acute Toxicity -- Sub-chronic Toxicity -- Chronic Toxicity Assessment -- Assessment of Non-carcinogenic Toxicity -- Selection of Species and Duration of Studies -- Human Sensitivity and Variability -- Assessment of Carcinogenic Toxicity -- Methodology -- MATHEMATICAL MODELS -- Types of Models -- Threshold Model -- Non-Threshold Model |
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TOXICITY EVALUATION OF EFFLUENTS FROM THE DYE INDUSTRY USING DAPHNIA MAGNA -- CONCLUSION -- REFERENCES -- Utility of Nanotechnology in Dye Degradation -- Seemesh Bhaskar1,2 and Sai Sathish Ramamurthy1,* -- INTRODUCTION -- METHODOLOGY -- Synthesis of f-HEG and Au-LCG -- Characterization -- Catalytic Dye Reduction Test -- RESULTS AND DISCUSSION -- Electron Microscopy, EDAX, XRD, Raman, Zeta Potential Studies and UV-Vis Spectroscopy of f-HEG and Au-LCG -- Analysis of Catalytic Activity of Au-LCG in Dye Reductions -- MSNAs for Dye Degradation Application -- CONCLUDING REMARKS -- ACKNOWLEDGEMENTS |
| Summary |
This series provides information on the nature of dyes, their harmful effects, and dye degrading techniques. The first volume of this series presents a fundamental concept of dye degradation. The information on target-oriented dye mitigation is intended to give readers a better understanding of the dye degradation process to sustain a healthy environment. Chapters present referenced information and highlight novel breakthroughs in the industry. Key topics: Fou |
| Notes |
Description based upon print version of record |
| Bibliography |
REFERENCES |
| Genre/Form |
Electronic books
|
| Form |
Electronic book
|
| Author |
Rajesh, Jegathalaprathaban
|
| ISBN |
9789815179545 |
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9815179543 |
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