| Description |
1 online resource |
| Series |
Advances in chemistry research |
|
Advances in chemistry research
|
| Contents |
Preface; Chapter 1; Commissioning of an Air-Lift Reactor; Abstract; 1. Introduction; 2. Theoretical Background; The Commissioning Process; Safety; Mechanical Completion and Pre-Commissioning; Mechanical Completion; Pre-Commissioning; Pre-Commissioning of Field Instrumentation; Management; Process Commissioning; Final Checks; Performance and Acceptance Tests; Post Commissioning Documentation; Airlift Reactor; Parts of the Airlift Reactor; How ALR Operates; Types of Airlift Reactors; Spargers; Operating flow regimes; Hydrodynamics; Gas-Holdup; Liquid Circulation Velocity |
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Advantages of an Airlift Reactor3. Experimental Setup; 4. Experimental Procedure; Commissioning; Set-Up; 5. Results; Commissioning; Phase A: Construction and Pre-Commissioning; Phase B: Construction and Pre-Commissioning; Phase C: Construction and Pre-Commissioning; Phase D: Construction and Pre-Commissioning/Commissioning; Phase E: Commissioning/Performance Trials; Experimental Results; 6. Discussion; Pre-Commissioning, Construction and Installation; Commissioning/Performance Trials; Conclusion; Appendix A: Raw Data; Appendix B: Sample Calculations |
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Appendix C: Relevant Experimental ProceduresAcknowledgments; References; Chapter 2; Pitfalls in Tandem Mass Spectrometry Analysis and Alternative Confirmatory Methods; Abstract; Introduction; Identification Points System According to; EU Directive 2002/657/EC; False-Positive and False-Negative Results in Tandem Mass Spectrometry; Alternative Confirmation Strategies; High Resolution Mass Spectrometry; Summary and Conclusion; Acknowledgments; References; Chapter 3; Tungsten Carbide: High Temperature Electrochemical Synthesis from Ionic Melts, Technologies of Obtaining and Regeneration |
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Abstract1. High-Temperature Electrochemical Synthesis from Ionic Melts; 1.1. State of the Art in the High-Temperature Electrochemical Synthesis of Tungsten Carbides; 1.2. Thermodynamic Foundations of the Electrosynthesis of Tungsten Carbides; 1.2.1. Calculating the Equilibrium Potentials of Tungsten and Carbon Deposition from Various Electrolytes; 1.2.2. Conditions and Components for the Electrochemical Synthesis of Tungsten Carbides; 1.2.3. The Effect of the Acid-Base Properties of the Melt on the Discharge Potential of Oxygen-Containing Anions |
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1.3. Theoretical Foundations of the High-Temperature Electrochemical Synthesis of Tungsten Carbides1.3.1. Simultaneous Electroreduction of Carbon Dioxide and Various Molybdenum and Tungsten Ionic Species in the KCl-NaCl Melt; 1.3.2. Simultaneous Reduction of Carbon Dioxide and Fluorotungstate Complexes in the NaCl-KCl-NaF Melt; 1.3.3. Simultaneous Electroreduction of Carbon Dioxide and Dimeric Tungsten Species in Tungstate Melts; 1.3.4. Simultaneous Electroreduction of the Carbonate and Tungstate Ions in Chloride-Fluoride and Oxide Melts |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Online resource; title from PDF title page (EBSCO, viewed January 30, 2017) |
| Subject |
Chemistry -- Research.
|
|
SCIENCE -- Chemistry -- General.
|
|
Chemistry -- Research
|
| Form |
Electronic book
|
| Author |
Taylor, James C., editor
|
| ISBN |
9781536100709 |
|
1536100706 |
|
