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Published byRoland Berry Modified over 9 years ago
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Salty Dust: Increasing the accessibility and mobility of toxic metals
Dr. James King
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Acknowledgements Richard Reynolds, Harland Goldstein,
Jim Yount, George Breit, Suzette Morman George Nikolich, Jack Gillies, Vic Etyemezian
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Why salty dust? Evaporite-mineral dust contain elevated As, Cr, Cu, Ni, Pb, Th, U, Se No current limits on inhalation of toxins Bioaccessibility of toxic metals Spatial variability of metal content in dust vs. groundwater chemistry Influences from climatic variability Aral Sea dust storm April Dust from Owens (dry) Lake NASA MODIS Photo by W. Cox, GBUAPCD
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Types of Playas WET Ground water is at or near the surface (< 4 m)
Ground water is far below the surface (> 4 m) or cannot interact with surface DRY (Stone, 1956; Neal, 1965; Rosen, 1994)
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Dust Emission Mechanics
Direct entrainment Highly dependent on surface conditions Generates relatively smaller amounts of dust Sensitive to wind regime F = Au*3 5 Saltation Bombardment Dependent on sand supply conditions Fetch effects are important q = Bu*3 Surface Roughness Vegetation, rocks, and crusts can modify the efficiency of dust emission mechanics
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Playa Surface Characteristics
Hard, compact surfaces Dry playa Wet playa Variable & Dynamic Soft – in areas of fluffy & puffy sediment Hard – in areas of crust Relatively stable with time Typically very hard
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Playa Sediment Types Wet Playa
Fluffy sediment – very soft; abundant evaporite minerals produced continuously; high volume of pore space Puffy sediment – soft, hummocky surface; fewer evaporite minerals. Crusts – salts and carbonate Dry Playa Typically compact clastic sediment (commonly mud cracked) Evaporite minerals deposited originally in lake beds
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Dust Emission from Playas
Hard, compact surfaces Dry playa Wet playa Low levels of dust emission when sediment supply is limited and surface is undisturbed Conditions may promote dust emission. Efflorescent salts in near-surface sediments produce mineral fluff & soft surfaces Wet playa Franklin Playa April 2005 Dry playa
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Field study & Monitoring site Franklin Lake Playa, USA
Amargosa River Ash Meadows Mojave Desert Carson Slough Franklin Lake
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Quickbird satellite images
0.7 1.5 16 90 Specific Conductivity (mS cm-1) Spring Discharge: a60,000 m3 day-1 Evaporation: b22,800 m3 day-1 Precipitation: 100mm yr -1 Pan Evap mm yr -1 Ash Meadows: Ash Meadows Carson Slough Quickbird satellite images 0.6-m resolution April 2006 aDudley & Larson, 1976; bCzarnecki & Stannard, 1997) Czarnecki, J.B., USGS Water Supply Paper, 2377.
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Groundwater Ion Content Trends
Ash Meadows Carson Slough Franklin Playa
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Groundwater Metal Trends
85 As (ppm) 83 190 180 93 As (ppm) predicted in anhydrous salts (Cl) by mass balance from evaporation
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Trace Metal and Ion Content with Depth
As U Cl SO4 Franklin Playa Auger Sediments Evaporation Front:
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Thick evaporation zone
Thin evaporation zone Evaporation Evaporation Sulfates precipitated, few metals Sulfates, chlorides precipitated with metals Surface Evap. front Water vapor rises with few metals Metals move with water Water table Groundwater Evaporation front vapor generated evaporation zone Metals accumulate in residual water Chloride concentrated Metals move with water Water table Groundwater
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Surface and Dust sediment collection
Wind-tunnel Tests Simulated winds to ~ 20 m/s to measure PM10 dust flux Dust Assess the potential vulnerability of surfaces to wind erosion Bulk dust collection
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Salt Crust Arsenic Spatial Trends
SO4 : Cl As Ratio in ground water
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Fractionation increases sulfate in crust and dust
Mobility of Sulfates ground water crust dust ground water crust dust ground water SO4 & Cl increase in groundwater crust dust ground water crust dust Fractionation increases sulfate in crust and dust Sulfates are mobile
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Bioaccessibility of Toxic Metals
Extraction pH Temp (C) Time Mixing control method Gastric I hr Shaker in Enviro Chamber Intestinal I hr Shaker in Enviro Chamber Lung hr Incubator Physiologically based extractions in simulated biofluids to assess bioaccessibility of As, Cd, Cr, Pb, Mo, Sb, W Se, U, etc.
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Extractions from dust in simulated biofluids
North Arsenic Uranium South Lung Gastric Intestinal
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Extractions from dust in simulated biofluids
85 As (ppm) 83 190 180 93 Lung Gastric As (ppm) predicted from Cl Intestinal
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Summary on accessibility of toxic metals
Extractions from dust in simulated biofluids demonstrate that for both Ar and U, the potential for concentrations exceeding current ingestion limits could be reached For these results there is no bias of the accessibility of Ar or U based on dust chemistry – this simplifies any prediction of other potential sources of toxic dust Differences in the accessibility of Ar and U exists between the three tested biofluids, with the intestinal biofluid having the lowest ability to access the metals
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Summary of mobility Sulfate salts are the most mobile; easily precipitating from the groundwater and concentrating further when eroded Toxic metals, in this case mainly As and U, are precipitated with the salts but mainly rely on the movement of chlorides to accumulate at the surface The conceptual model proves that any history of a thin evaporation zone could lead to concentration of toxic metals near the surface if present in the groundwater and therefore groundwater chemistry alone is not a good predictor of the potential mobility and accessibility Further work is currently under way to model wind erosion emissions based on local climate and surface conditions
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PI-SWERL Portable In-Situ Wind ERosion Laboratory
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