Acid Mine Drainage Field-Lab Experience Round I Greg Druschel Department of Geology University of Vermont
Ely Mine Field Experience Fall 2004 – first try - Round I…Fall 2004 – first try - Round I… Goals: -recognize and describe chemical changes associated with mineral oxidation and precipitation -be able to reconstruct those changes in a thermodynamic framework (speciation modeling, use of Eh-pH diagrams) -identify significant changes in redox state and how that impacts metal transport, microbial ecology -importance of keeping a detailed field book and appreciation for proper field sampling techniques (in situ measurements, filtration, etc.)
Ely Mine One of 3 massive sulfide mines in central- eastern Vermont Besshi-type massive sulfide primarily mined for Cu (at Ely) Historically and archeologically rich – site of Ely’s War and several technological advances in ore processing Site is essentially untouched since closure, timbers and foundations of mine buildings still visible in places
Ely Mine Tour Start at 5A, parking on an old waste site Hike up to the main shaft and discuss the mine site, ore deposits Get an overview of the system – mineral transformation, hydrologic cycle
Materials at Ely Wealth of detailed information here from the efforts of Bob Seal, Jane Hammerstrom, and Nadine Piatek at the USGS on the primary ore minerals, and secondary materials resulting from ore roasting, smelting, weatheringWealth of detailed information here from the efforts of Bob Seal, Jane Hammerstrom, and Nadine Piatek at the USGS on the primary ore minerals, and secondary materials resulting from ore roasting, smelting, weathering Massive sulfide is primarily pyrrhotite, chalcopyrite, sphalerite, and minor pyriteMassive sulfide is primarily pyrrhotite, chalcopyrite, sphalerite, and minor pyrite Roast materials are primarily hematite and magnetite (product of over-roasting)Roast materials are primarily hematite and magnetite (product of over-roasting) Sulfosalt minerals often coat tailings and can be dug out in some of the tailingsSulfosalt minerals often coat tailings and can be dug out in some of the tailings
Ely Brook Field Assessment From mine shaft, hike down and survey Ely Brook, starting at the headwater pool and ending at the confluence with schoolhouse Brook With students, have them pick out sites which undergo demonstrable change
Choices: 1.Headwaters – pond (really an old beaver dam), but relatively unimpacted 2.Sediment color change – white, vegetation more sparse 3.Sediment color change – red, vegetation absent 4.Anoxic spring feeding into Ely Brook – Black precipitate turning to red 5.Confluence – White and red strips flowing into Schoolhouse Brook
DETAILED Look at each Site Split students into several working groups to take field measurements and do analyses: Group 1 Water sample collection, filtration, and acidification; sediment/rock samples collection; alkalinity kit (Hach titration) Group 2: pH, temperature, conductivity meter Group 3: Spectrophotometer (Hach portable) Al, Fe 2+, Fe T Used voltammetric probes at one site
Site 1 Unimpacted headwater Discussed where a representative sample might come from, how to get it… Used pH, T, Cond meter to survey – checked if edges vs. middle were different pH 6.54 at edge, 7.01 nearer the middle (shallow, ~1 meter deep) Site Alkalinity measureable here 20.6 mg/l as CaCO 3, no measurable Al 3+, but Fe 3+ close to 0.2 mg/l
Site 2 Appearance of fluffy white precipitate pH 5.97, Alkalinity now 2 mg/l as CaCO 3 (10-fold decrease)
Students asked what the white stuff was, so we did a little field experiment and acidified a sample with some of it in suspension, measured it for Al and Fe and analyzed it with the spectrophotometer… Collected several samples for later analysis in lab
Site 3 One site evolved…
Invisible inputs… Students had identified a spatial problem with respect to a contaminant source… Let them poke around for a while to figure it out, followed by a good discussion of groundwater flow
After constructing a crude well, we sampled it and analyzed the water pH 2.86, Al 3+ =0.9 mg/l, Fe T =1.5 g/l After lab analysis of sulfate, this turned into a good example on Fe hydrolysis!
Application of microelectrodes to look at presence of sulfide and formation of FeS minerals at anoxic site Discussion of oxidation and closed systems
Confluence – mixing and FeOOH, AlOOH precipitation
Lab/ Computational Samples brought back to the lab were run on IC for anions Provided cation data from Seal et al., for modeling PHREEQCI modeling lab to determine saturation indices for AlOOH and FeOOH, used activity diagrams for both systems they constructed as a homework to supplement reports on this
Student Impact Every one of the students commented on this in course evaluation Brought together acid/base. Redox, hydrolysis reactions as well as mineral/water reactions, microbial interactions, and gas exchange (O 2 availability, SO 2 /H 2 S loss). Provided a concrete example of thermodynamic calculations they had been doing in class and a basis for more detailed analyses using PHREEQCI 3 of them wrote a final paper on an individual aspect from the trip (SO 2 degassing, Cu speciation and sorption, microbial pyrite oxidation)
Logistics/ Portability to other sites This mine, like many around the U.S. and the world, is privately owned – negotiated access with the owner Many AMD sites have characteristics similar to Ely, and are great examples of redox and acid/base geochemistry that students can actually ‘see’ and get their hands on Most measurements are fast, cheap, and easy – turns out students are pretty good at working with field data and working out process control…
Next Year Expanding this to 2 days Bringing piezometers Test a study on filtration and sampling for Al 3+ concentrations Collect samples and do a separate lab on sorption OTHER THOUGHTS???