OOlldd DDoommiinniioonn UUnniivveerrssiittyy OODDUU DDiiggiittaall CCoommmmoonnss Chemistry & Biochemistry Theses & Chemistry & Biochemistry Dissertations Summer 2016 PPoossssiibbllee SSoouurrcceess aanndd IImmppaaccttss ooff BBiioocchhaarr WWaatteerr EExxttrraaccttaabbllee OOrrggaanniicc CCoommppoouunnddss oonn AAqquuaattiicc MMiiccrroooorrggaanniissmmss Cameron Russell Smith Old Dominion University, [email protected] Follow this and additional works at: https://digitalcommons.odu.edu/chemistry_etds Part of the Analytical Chemistry Commons, Environmental Chemistry Commons, and the Environmental Engineering Commons RReeccoommmmeennddeedd CCiittaattiioonn Smith, Cameron R.. "Possible Sources and Impacts of Biochar Water Extractable Organic Compounds on Aquatic Microorganisms" (2016). Doctor of Philosophy (PhD), Dissertation, Chemistry & Biochemistry, Old Dominion University, DOI: 10.25777/61vn-qx48 https://digitalcommons.odu.edu/chemistry_etds/10 This Dissertation is brought to you for free and open access by the Chemistry & Biochemistry at ODU Digital Commons. It has been accepted for inclusion in Chemistry & Biochemistry Theses & Dissertations by an authorized administrator of ODU Digital Commons. For more information, please contact [email protected]. POSSIBLE SOURCES AND IMPACTS OF BIOCHAR WATER EXTRACTABLE ORGANIC COMPOUNDS ON AQUATIC MICROORGANISMS by Cameron Russell Smith B.S. May 2011, Lynchburg College A Dissertation Submitted to the Faculty of Old Dominion University in Partial Fulfillment of the Requirements for the Degree of DOCTOR OF PHILOSOPHY CHEMISTRY OLD DOMINION UNIVERSITY August 2016 Approved by: James W. Lee (Director) Patrick G. Hatcher (Member) Lesley H. Greene (Member) Sandeep Kumar (Member) ABSTRACT POSSIBLE SOURCES AND IMPACTS OF BIOCHAR WATER EXTRACTABLE ORGANIC COMPOUNDS ON AQUATIC MICROORGANISMS Cameron Russell Smith Old Dominion University, 2016 Director: Dr. James W. Lee Smokeless biomass pyrolysis with application of biochar as a soil amendment could be a significant approach for carbon sequestration to possibly control climate change for energy and environmental sustainability. If biochar were to be utilized as a soil amendment and a carbon sequestration agent at Gt C scales, the release of potentially toxic compounds into soils and associated hydrological systems, through soil rainwater runoff and leaching, might have negative consequences, in both agro- ecosystems and aquatic environmental systems. Therefore, the main focus of this dissertation was to study the sources and chemical composition of biochar water extractable (soluble) organic compounds and their effects on aquatic microorganisms. To evaluate the effects of biochar water extractable substances on the growth of aquatic microorganisms, rapid phytotoxicity assays were performed and showed that pinewood derived biochar water extracts inhibited the growth of both cyanobacteria, Synechococcus sp., and eukaryotic green algae, Desmodesmus sp., while peanut shell and chicken litter derived biochar water extracts did not inhibit growth. Because of its ultrahigh resolution, mass precision and effectiveness for analyzing water soluble compounds, electrospray ionization (ESI) coupled to Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS) was utilized to analyze biochar water extracts at a molecular level to enhance our initial understanding of the toxic nature of pinewood-derived biochar water extracts as compared to benign peanut shell-derived biochar water extracts. The molecular composition of pinewood-derived biochar water extracts showed unique carbohydrate ligneous components and sulfur containing condensed ligneous components which were both absent from peanut shell-derived biochar water extracts. Finally, sources of biochar water soluble organic compounds (WSOC) were investigated as a function of biomass materials including cellulose and lignin and pyrolysis temperature from 300°C to 500°C in relation to their potential toxicity to freshwater blue-green algae, Synechococcus. The amount of WSOC extracted from biochar, irrespective of biomass starting material, decreased significantly as a function of pyrolysis temperature. Algal bioassays and advanced 2D GC×GC mass spectrometry analyses revealed that toxic WSOC extracted from pinewood-derived biochar was most likely due to mono-, di- and tri-substituted phenolic compounds derived from lignin, while toxic WSOC extracted from cellulose-derived biochar was acidic and bio-oil like in nature. iv Copyright, 2016, by Cameron Russell Smith, All Rights Reserved. v This dissertation is dedicated to my wonderful family and friends. vi ACKNOWLEDGEMENTS First, I want to thank Old Dominion University for providing me with the opportunity to pursue higher education in the field of chemistry. Secondly, the growth of the chemistry program, the university and the community at ODU would not be what it is today without the liberties the United States provides, and for that I am grateful. I would like to thank my advisor, Dr. Lee, for his continual guidance and patience throughout my post graduate education. His positive attitude and encouragement are qualities that not only made him a great mentor, but also a friend. I would also like to thank Dr. Hatcher for his guidance and collaboration over the course of my research. I am very grateful that he allowed me to work closely with his group and share his laboratory. I would also like to thank Dr. Rachel Sleighter for her support and mentoring throughout my education. She has been one of the most influential teachers in my life, and for that I am grateful. I would also like to thank Dr. Sandeep Kumar and Dr. Lesley Greene for allowing me to use their laboratories for my research, and without both of them my research would not have been possible. I would like to thank my group members, Matt Huff and Hathiem Saeed, for their help and support throughout my studies. I would also like to thank the Hatcher group members, specifically Amanda Willoughby, Derek Waggoner, Wassim Obeid and Blaine Hartman, for their help and support. I would also like to thank Isaiah Ruhl. All of these individuals have made my experience and education at ODU more beneficial and enjoyable. Lastly, and most importantly, I would like to thank God for all that I have, and without him none of this would be possible. vii TABLE OF CONTENTS Page LIST OF TABLES ............................................................................................................. ix LIST OF FIGURES .............................................................................................................x Chapter 1. INTRODUCTION ...................................................................................................1 1.1 OVERVIEW ....................................................................................1 1.2 MOTIVATION ................................................................................1 1.3 GENERAL HYPOTHESES ............................................................3 1.4 ORGANIZATION OF CHAPTERS ...............................................4 2. BACKGROUND .....................................................................................................6 2.1 GENERAL .......................................................................................6 2.2 STRUCTURAL COMPONENTS OF BIOMASS ..........................8 2.3 BIOMASS PYROLYSIS ..............................................................10 2.4 BIOCHAR FORMATION .............................................................12 2.5 BIO-OIL FORMATION ................................................................13 2.6 POTENTIAL ROLE OF BIO-OIL ASSOCIATED WITH BIOCHAR IN THE ENVIRONMENT .........................................14 3. POTENTIAL IMPACT OF BIOCHAR WATER-EXTRACTABLE SUBSTANCES ON ENVIRONMENTAL SUSTAINABILITY ..........................17 3.1 INTRODUCTION .........................................................................18 3.2 MATERIALS AND METHODS ...................................................20 3.3 RESULTS AND DISCUSSIONS ..................................................33 3.4 CONCLUSION ..............................................................................55 4. MOLECULAR CHARACTERIZATION OF INHIBITING BIOCHAR WATER-EXTRACTABLE SUBSTANCES USING ELECTROSPRAY IONIZATION FOURIER TRANSFORM ION CYCLOTRON RESONANCE MASS SPECTROMETRY ...........................................................57 4.1 INTRODUCTION .........................................................................58 4.2 MATERIALS AND METHODS ...................................................60 4.3 RESULTS AND DISCUSSIONS ..................................................65 4.4 CONCLUSION ..............................................................................91 5. AN INVESTIGATION INTO THE SOURCES OF BIOCHAR WATER SOLUBLE ORGANIC COMPOUNDS AND THEIR POTENTIAL TOXICITY ON AQUATIC MICROORGANISMS .............................................93 5.1 INTRODUCTION .........................................................................94 5.2 MATERIALS AND METHODS ...................................................95 viii Chapter Page 5.3 RESULTS AND DISCUSSIONS ................................................102 5.4 CONCLUSION ............................................................................130 6. CONCLUSIONS AND FUTURE WORK ..........................................................132 6.1 IMPORTANCE OF BIOCHAR WATER SOLUBLE (EXTRACTABLE) ORGANIC COMPOUNDS .........................132 6.2 GENERAL CONCLUSIONS ......................................................132 6.3 FUTURE WORK .........................................................................133 REFERENCES ................................................................................................................137 APPENDICES .................................................................................................................153 A. COPYRIGHT PERMISSION ......................................................153 B. ABBREVIATIONS AND ACRONYMS ....................................156 VITA ................................................................................................................................158 ix LIST OF TABLES Table Page 1. Dissolved organic carbon (DOC) in biochar water extracts. ........................................30 2. Electrodialysis separation of pinewood biochar water-extractable substances (BWES) containing about 23.8 mg of dissolved organic carbon (DOC). ........................31 3. Biochar elemental (%, oven-dry wt. basis) and proximate analysis from Galbraith Laboratories, Knoxville, TN. .............................................................................67 4. Comparison of elemental and proximate results with other reported biochar analysis (%, oven-dry wt. basis). .......................................................................................68 5. Biochar yield, elemental analysis (oven-dry wt. % basis) and water soluble organic compounds (WSOC) characteristics. ..................................................................103 6. Raw data biochar yields, elemental analysis (oven-dry wt. % basis) and water soluble organic carbon characteristics. ............................................................................104 7. Compounds corresponding to total ion and extracted ion chromatograms in Figure 33. .........................................................................................................................118 8. Qualitative analysis of volatile fraction via GC×GC MS. ..........................................122