INFLUENCE OF NATURAL ORGANIC MATTER ON THE MOBILITY OF ARSENIC IN AQUATIC SYSTEMS, SOILS AND SEDIMENTS Dissertation zur Erlangung des Grades Doktor der Naturwissenschaften (Dr. rer. nat.) an der Fakultät Biologie/Chemie/Geowissenschaften der Universität Bayreuth vorgelegt von Markus Bauer Geb. am 01.05.1977 in Ingolstadt Bayreuth, 23. April 2008 Vollständiger Abdruck der von der Fakultät für Chemie/Biologie/Geowissenschaften der Universität Bayreuth genehmigten Dissertation zur Erlangung des Grades eines Doktors der Naturwissenschaften (Dr. rer. nat.). Prüfungsausschuss: Prof. Dr. Stefan Peiffer (Vorsitzender) PD Dr. Christian Blodau (1. Gutachter) Prof. Dr. Egbert Matzner (2. Gutachter) Prof. Dr. Hartmut Frank PD Dr. Bruno Glaser Tag der Einreichung: 20.04.08 Tag des wissenschaftlichen Kolloquiums: 29.10.08 TABLE OF CONTENTS TABLE OF CONTENTS INFLUENCE OF NATURAL ORGANIC MATTER ON THE MOBILITY OF ARSENIC IN AQUATIC SYSTEMS, SOILS AND SEDIMENTS ............................................................................... I TABLE OF CONTENTS ..................................................................................................................... I LIST OF FIGURE ............................................................................................................................. III LIST OF TABLES ............................................................................................................................. V SUMMARY ..................................................................................................................................... VII ZUSAMMENFASSUNG .................................................................................................................. IX EXTENDED SUMMARY .................................................................................................................. 1 Introduction ......................................................................................................................................... 1 1. Arsenic health concerns ............................................................................................................... 1 2. Arsenic geochemistry and mobility ............................................................................................. 1 3. Natural organic matter ................................................................................................................. 4 4. As mobility in environments rich in organic matter .................................................................... 7 5. Objectives of the dissertation ...................................................................................................... 8 I. Redox Chemistry of DOM and Electron Transfer Reactions with As ........................................... 11 1. DOM oxidation and reduction by inorganic compounds (study 1 and 2) ................................. 12 2. DOM redox reactivity with As (study 3) ................................................................................... 14 Conclusions ................................................................................................................................... 14 II. Aqueous and Surface Complexation Reactions of As and DOM ................................................. 15 1. Complex and colloid formation in solutions with Fe, DOM and As (study 4 and 5) ................ 16 2. Influence of DOM on As binding to mineral surfaces (study 6) ............................................... 18 3. Aqueous and surface complexation reactions and the redox speciation of As .......................... 18 Conclusions ................................................................................................................................... 19 III. Effect of DOM Load on the As Mobilization (study 7) .............................................................. 19 IV. Arsenic Mobility and Retention in Organic Matter Rich Peat Soils ........................................... 21 1. Arsenic in peat mesocosms subject to drying and rewetting (Study 8) ..................................... 22 2. Arsenic in degraded peatland soil (Study 9) .............................................................................. 23 Conclusions ................................................................................................................................... 24 Conclusions and Outlook .................................................................................................................. 26 References ......................................................................................................................................... 29 Contributions to the Different Studies ............................................................................................... 37 APPENDIX ....................................................................................................................................... 41 - I - - I -I57- TABLE OF CONTENTS Study 1, APPENDIX 45 Electron Transfer Capacities and Reaction Kinetics of Peat Dissolved Organic Matter Study 2, APPENDIX 63 Electron Accepting Capacitiy od Dissolved Organic Matter as determined by Reaction with Metallic Zinc Study 3, APPENDIX 85 Oxidation of As(III) and Reduction of As(V) in Dissolved Organic Matter Solutions Study 4, APPENDIX 97 Experimental colloid formation in aqueous solutions rich in dissolved organic matter, ferric iron, and As Study 5, APPENDIX 119 Evidence for Aquatic Binding of Arsenate by Natural Organic Matter-Suspended Fe(III) Study 6, APPENDIX 129 Mobilization of Arsenic by Dissolved Organic Matter from Iron Oxides,Soils and Sediments Study 7, APPENDIX 143 Mobilization of Iron and Arsenic from Iron Oxide Coated Sand Columns by Percolation with Dissolved Organic Matter Study 8, APPENDIX 159 Arsenic Speciation and Turnover in intact Organic Soil Mesocosms during Experimental Drought and Rewetting Study 9, APPENDIX 179 Groundwater Derived Arsenic in High Carbonate Wetland Soils: Sources, Sinks, and Mobility Redox reactions and Redox potentials, APPENDIX 193 - II - - II -II57- LIST OF FIGURES LIST OF FIGURE Page Figure 1 Extended Summary E -pH diagrams for As 3 h Figure 2 Extended Summary Schematic structure of a DOM molecule 5 Figure 3 Extended Summary Electron transfer reactions of quinones and DOM 5 Figure 4 Extended Summary Aqueous and surface complexes of As and DOM 7 Figure 5 Extended Summary Interactions of As with DOM and Fe 9 Figure 6 Study 1, Fig. 1 Reduction of Fe(III) complexes by DOM 47 Figure 7 Study 1, Fig. 2 Reduction of Fe(III) vs. DOM concentration 48 Figure 8 Study 1, Fig. 3 Reduction of Fe(III) vs. pH 48 Figure 9 Study 1, Fig. 4 Oxidation of H S and Zn0 by DOM 49 2 Figure 10 Study 1, Fig. 5 Oxidation of H S and Zn0 vs. DOM concentration 49 2 Figure 11 Study 1, Fig. 6 Dependency of ETC and reaction rate constant on E 0 50 h Figure 12 Support, Study 1 Aqueous Fe speciation as modelled by Phreeqc 55 Figure 13 Support, Study 1 Aqueous Fe speciation as modelled by Phreeqc 56 Figure 14 Support, Study 1 Variability during modelling 58 Figure 15 Support, Study 1 Formation of Fe(II) in DOM solution 59 Figure 16 Study 2 Zn2+, H and H+ turnover in DOM solution 71 2 Figure 17 Study 2 Dependency of Zn release on pH 72 Figure 18 Study 2 Time series of Zn release with different DOM samples 73 Figure 19 Study 2 Zn0 oxidation vs. DOM concentration 73 Figure 20 Study 2 Electron accepting capacity vs. DOM concentration 75 Figure 21 Study 2 Reversibility of DOM electron uptake 75 Figure 22 Study 2 Relation of DOM SUVA and FTIR properties to EAC 76 Figure 23 Study 2 Relation of DOM fluorescence properties to EAC 77 Figure 24 Study 3 Time series of As(III) oxidation by DOM 90 Figure 25 Study 3 As(III) oxidation capacity 91 Figure 26 Study 3 Time series of As(V) reduction by DOM 93 Figure 27 Study 3 As(V) reduction capacity 94 Figure 28 Study 4 Colloid formation assays: Standard procedure and variations 101 Figure 29 Study 4 Results of standard colloid filtration experiments 103 Figure 30 Study 4 Time series of formation of Fe-As-DOM aggregates 104 Figure 31 Study 4 Correlation of As, Fe and DOC in aggregates with PPHA 105 Figure 32 Study 4 Dependency of aggregate formation on pH 106 Figure 33 Study 4 Dependency of aggregate formation on DOC concentration 107 Figure 34 Study 4 Dependency of aggregate formation on Fe/C ratio 111 Figure 35 Study 4 Filtration results vs. WINHUMIC model calculations 110 - III - - III -III57- LIST OF FIGURES Page Figure 36 Support, Study 4 Formation of Fe-As-DOM aggregates with SRDOM 118 Figure 37 Study 5, Fig. 1 Arsenic dialysis experiments without DOM and with SRHPOA 123 Figure 38 Study 5, Fig. 2 Arsenic dialysis experiments with EGFA and SRWW 124 Figure 39 Study 5, Fig. 3 Arsenic mass balance during dialysis experiments 124 Figure 40 Study 5, Fig. 4 DOC and Fe mass balance in dialysis experiments 125 Figure 41 Study 5, Fig. 5 Arsenic complexation dependency on Fe concentration 126 Figure 42 Study 6, Fig. 1 Aqueous As speciation in DOM solution 134 Figure 43 Study 6, Fig. 2 Arsenic sorption on goethite 134 Figure 44 Study 6, Fig. 3 Arsenic desorption from goethite 135 Figure 45 Study 6, Fig. 4 Arsenic desorption by DOM from soil and sediment 137 Figure 46 Study 6, Fig. 5 Time series of As mobilization and speciation 137 Figure 47 Study 7 Breakthrough of chloride and pH in column experiments 148 Figure 48 Study 7 Column effluent concentrations of Fe, As and S 150 Figure 49 Study 7 Dynamics of Fe, S and As within the column 151 Figure 50 Study 7 Column solid phase Fe, S and As content 152 Figure 51 Study 8 Solid phase As and Fe distribution in peat material 164 Figure 52 Study 8 Gas content in the peat cores during drying and rewetting 166 Figure 53 Study 8 Root activity in the peat cores as determined by d13C of CO 166 2 Figure 54 Study 8 Aqueous depth profiles of Fe, S, DOC, and pH 167 Figure 55 Study 8 Temporal dynamics of dissolved As in the peat cores 168 Figure 56 Study 8 Arsenic speciation at the beginning of the drying period 169 Figure 57 Study 8 Temporal dynamics of the As(III) to As(V) ratio 169 Figure 58 Study 8 Temporal dynamics of DMA concentration 170 Figure 59 Study 8 Redox potential values calculated from As, Fe and S couples 170 Figure 60 Study 8 Turnover rates calculated for As and Fe 171 Figure 61 Support, Study 8 Time series of water levels during drying and rewetting 177 Figure 62 Study 9 Aqueous concentration profiles of As, Fe and DOC 183 Figure 63 Study 9 Soil horizon XRD spectra 184 Figure 64 Study 9 Soil content of As, Fe and C in different pools 186 Figure 65 Study 9 Arsenic mobilization by soil organic carbon dispersion 187 Figure 66 Support, Study 9 Setup of the Stella transport model 192 Figure 67 Support, Study 9 Measured and modelled depth profile of As and Cl- 192 - IV - - IV -IV57- LIST OF TABLES LIST OF TABLES Page Table 1 Study 1, Tab. 1 DOM oxidation and reduction experiments 46 Table 2 Support, Study 1 Properties of DOM samples 52 Table 3 Support, Study 1 List of critical stability constants 54 Table 4 Support, Study 1 Thermodynamic calculations 57 Table 5 Support, Study 1 Literature review of EAC and EDC values 60 Table 6 Study 2 Properties of DOM samples 66 Table 7 Study 3 Experiments of As oxidation and reduction by DOM 88 Table 8 Study 3 Thermodynamic calculations 89 Table 9 Study 4 Complexation and colloid formation experiments 101 Table 10 Study 4 Properties of DOM samples 103 Table 11 Study 4 Fe, DOC and As concentrations in different size fractions 108 Table 12 Study 5, Tab. 1 Properties of DOM samples 121 Table 13 Study 5, Tab. 2 Inorganic constituents of DOM solution 121 Table 14 Study 5, Tab. 3 Results of sequential filtration experiments 126 Table 15 Study 6, Tab. 1 Arsenic sorption and desorption experiments from iron oxide 136 Table 16 Study 6, Tab. 2 Characteristics of soil and sediment samples 138 Table 17 Study 6, Tab. 3 Arsenic content in soil and sediment pools 138 Table 18 Study 7 Column hydraulic characteristics 149 Table 19 Study 7 Mass balances for Fe, S, As and C in column experiments 152 Table 20 Study 8 Solid phase Fe, Al and TRIS content 165 Table 21 Study 8 Correlation of As content with major soil constituents 165 Table 22 Support, Study 8 Solid phase elemental content 178 Table 23 Study 9 Applied extraction procedures 182 Table 24 Study 9 Physical and chemical properties of soil horizons 185 Table 25 Study 9 Solid phase Ca, Fe and As content in soil mineral pools 185 Table 26 Appendix 10 Summary of thermodynamic calculations 194/195 - V - - V -V57- LIST OF TABLES - VI - - VI -VI57-
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