Florida State University Libraries Electronic Theses, Treatises and Dissertations The Graduate School 2006 Analysis of Chemical Reactions in Pulsed Streamer Discharges: An Experimental Study Mayank Sahni Follow this and additional works at the FSU Digital Library. For more information, please contact [email protected] THE FLORIDA STATE UNIVERSITY COLLEGE OF ENGINEERING ANALYSIS OF CHEMICAL REACTIONS IN PULSED STREAMER DISCHARGES: AN EXPERIMENTAL STUDY BY MAYANK SAHNI A Dissertation submitted to the Department of Chemical Engineering in partial fulfillment of the requirements for the degree of Doctor of Philosophy Degree Awarded: Spring Semester, 2006 Copyright © 2006 Mayank Sahni All Rights Reserved The members of the committee approve the dissertation of Mayank Sahni defended on January 9, 2006. ______________________ Bruce R. Locke Professor Directing Dissertation ______________________ Peter Fajer Outside Committee Member ______________________ Rufina Alamo Committee Member ______________________ Ravindran Chella Committee Member The office of Graduate Studies has verified and approved the above named committee members. ii To my Parents iii ACKNOWLEDGMENTS I thank my thesis advisor Dr Bruce R. Locke, for his motivation, patience and guidance throughout the course of my PhD. His interest in this work and his style of advising has motivated me to put in my best effort. I would also like to thank my committee members Dr Peter Fajer, Dr Ravi Chella and Dr Rufina Alamo for serving on my committee. Thanks also to Dr Igor Alabugin and Dr Louis Kischenbaum for their help at critical junctures of my PhD. Helpful discussions with Dr Petr Lukes and Dr Olga Federova are gratefully acknowledged. I would like to thank Mr Wright Finney for his suggestions both inside and outside the laboratory. I would like to acknowledge the support of the Department of Chemical Engineering, FAMU-FSU College of Engineering, Florida State University Graduate Student Fellowship, U.S. Department of Defense Small Business Innovative Research, and the Florida Department of Environmental Protection. I also thank Dr. Pavel Šunka, Dr. Martin Člupek, and Dr. Vaclav Babicky at the Institute of Plasma Physics, Czech Academy of Sciences for their hospitality during my visit. I would like to thank all my past and present corona group colleagues for several great years both inside and outside the lab. I owe a great deal to ‘my boss’ Dr. Michael Kirkpatrick for all his help throughout the course of my PhD. Friends in Tallahassee have contributed in making my stay here comfortable and exciting. A special thanks is due to Ms. Jyoti Kolhe for her tremendous help in all facets of my PhD work. I would like to thank my family, my grandparents, my parents and my sister for their encouragement and motivation for pursuing my PhD. iv TABLE OF CONTENTS List of Tables…………………………………………………………………... x List of Figures………………………………………………………………….. xii Abstract………………………………………………………………………… xviii I. INTRODUCTION AND LITERATURE REVIEW………………… 1 1.1 What are Plasmas?……………………………………………… 1 1.2 Various types of electrical discharges and their uses …………... 1 1.3 Liquid phase electrical discharges ……………………………... 3 1.4 Gas phase electrical discharges………………………………… 7 1.5 New Reactor configurations……………………………………. 11 1.6 Comparison of pulsed streamer discharges with other AOP……. 13 1.7 Objectives of this research………….…………………………... 16 II. DEGRADATION OF CHEMICAL WARFARE AGENT SIMULANTS USING GAS-LIQUID PULSED STREAMER DISCHARGES……. 18 2.1 Introduction…….……………………………………………….. 18 2.2 Experimental techniques and methods …………………………. 21 2.2.1 Materials ……………………………………..……........ 21 2.2.2 Pulsed generation network……………………………… 21 2.2.3 Reactor Configurations ………………………………… 22 2.2.4 Analytical techniques and procedures …………………. 24 v 2.2.5 Properties of the simulants chosen…..…………………. 26 2.3 Results and Discussion ………………………………………… 28 2.3.1 Effect of reactor configuration on the degradation of H agent simulant (no additives in solution)…..………… 28 2.3.2 Effect of reactor configuration on the degradation of H agent stimulant (ferrous salts in solution (Fenton’s case))….………………………………………………... 32 2.3.3 Comparison of the ion chromatography data on the degradation of H agent stimulant in various reactor configurations…..……………………………………… 36 2.3.4 Energy yields of degradation of the H agent stimulant… 36 2.3.5 Effect of additives in solution (zeolites and platinum coated activated carbon) on the degradation of the H agent simulant …..…………………………………… 41 2.3.6 Degradation of G agent simulant in reference and series configurations (no additives in solution)………………. 46 2.3.7 Degradation of G agent simulant in reference and series configurations (ferrous salts in solution (Fenton’s reactions)) ……………………………………………... 48 2.3.8 Comparison of the ion chromatography and energy efficiency data on the degradation of G agent stimulant in various reactor configurations………………………. 49 2.4 Conclusions……………………………………………........ …. 50 III. DEGRADATION OF AQUEOUS PHASE POLYCHLORINATED BIPHENYLS (PCB) USING PULSED CORONA DISCHARGES … 53 3.1 Introduction ………………………………………………….. 54 3.2 Experimental Techniques…………………………………….. 55 3.2.1 Materials and Methods ……………………………..... 55 vi 3.2.2 Pulse Generating Network ………………………......... 56 3.2.3 Reactor Configuration ………….…………………........ 56 3.3 Results and Discussion ………………………………………… 58 3.3.1 Comparison of experimentally obseved and model simulated degradation of TCB in the reference configuration………….................................................... 59 3.3.2 TCB degradation in the Series configuration ………….. 62 3.3.3 Effect of high voltage electrodes on the degradation of TCB………….................................................................. 68 3.3.4 Effect of additives (zeolytes) on the degradation of TCB... 70 3.3.5 Effect of hydroxyl radical scavenger (methanol) on the degradation of TCB ……………………......................... 72 3.3.6 Effect of salts in solution on the degradation of TCB….. 74 3.3.7 Effect of initial pH of solution on the degradation of TCB.. 75 3.3.8 Comparison of degradation of PCB congeners with different number of chlorine substituents…………….... 76 3.4 Conclusions ……………………………………………............ 79 IV. QUANTIFICATION OF HYDROXYL RADICALS PRODUCED IN PULSED ELECTRICAL DISCHARGE REACTORS………. 80 4.1 Introduction …………………………………………………….. 80 4.2 Experimental Procedures……………………………………….. 83 4.2.1 Chemical and Materials..……………………………….. 83 4.2.2 Formaldehyde quantification using HPLC…................... 84 4.2.3 Quantification of 2-hydroxyterephthalic acid (HTA)…... 84 4.2.4 Quantification of hydrogen peroxide (H O ).................... 84 2 2 vii 4.2.5 Quantification of ozone (O )..………………………….. 84 3 4.2.6 Power Supply and Reactor Configuration….................... 85 4.2.7 Reaction mechanisms and byproducts of probes….......... 88 4.3 Results and Discussion…………………………………………. 90 4.3.1 Effect of input power on the hydroxyl radical production rate………………………………………… 90 4.3.2 Effect of reactor configuration on the hydroxyl radical production rate ..……………………………………….. 101 4.3.3 Effect of gas composition on the hydroxyl radical production rate ..……………………………………….. 110 4.3.4 Effect of initial conductivity of the solution on the hydroxyl radical production rate ……………………… 114 4.3.5 Effect of initial pH of solution on the hydroxyl radical production rate …………….………………………….. 121 4.3.6 Effect of solution temperature on the hydroxyl radical production rate……..…………………………………. 124 4.3.7 Effect of high voltage electrode material on the hydroxyl radical production rate……………………….. 126 4.3.8 Effect of adding reactive species scavengers to the solution on the hydroxyl radical production rate………. 128 4.3.9 Effect of additives such as zeolytes to the solution on the hydroxyl radical production rate…………………… 130 4.4 Conclusions…………………………………………………….. 133 V. QUANTIFICATION OF REDUCTIVE SPECIES PRODUCED BY HIGH VOLTAGE ELECTRICAL DISCHARGES IN WATER…………. 134 5.1 Introduction…………………………………………………….. 134 5.2 Experimental methods…………………………………………… 139 5.3 Results …………………………………………………………... 143 viii a) Reductive Species Quantification using TNM as the reductive species probe 5.3.1 Effect of initial concentration of probe (TNM) on the production of reductive species………………............... 143 5.3.2 Effect of initial power (applied voltage) on the formation and degradation of NF-……………..………. 143 5.3.3 Effect of initial conductivity of solution on the production of reductive species……………………….. 146 5.3.4 Effect of scavengers of solution on the production of reductive species………………………………………. 151 5.3.5 Effect of bubbling different gases into solution on the production of reductive species……………………….. 160 b) Reductive Species Quantification using NBT as the reductive species probe 5.3.6 Effect of input power (applied voltage) on the production of reductive species ……………………….. 161 5.3.7 Comparison of the production rate of reductive and oxidative species……………………………………….. 165 5.3.8 Experiments with NBT as probe with TNM as scavenger in solution…………………………………… 167 5.4 Conclusions……………………………….................................. 169 VI. SUMMARY AND CONCLUSIONS…………………………………. 170 VII. FUTURE WORK………………………………………………………. 178 APPENDIX ….………………………………………………………………….. 181 REFERENCES………………………………………………………………….. 182 BIOGRAPHICAL SKETCH……………………………………………………. 199 ix
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