Publication Type:Journal Article
Source:Canadian Mineralogist, Mineralogical Association of Canada, Volume 52, Number 3, p.453-471 (2014)
Keywords:aerosols, Aluminum coatings, Aluminum compounds, dissolution, Hematite, laser ablation, Mass spectrometry, Metal drawing, metalloids, metals, Nickel oxide, Oxide minerals, Precipitation (chemical), rare earths, silicates, Slags, smelting, Soil pollution, soils, Spheres, Sulfate minerals, Trace elements, weathering
Over 10,000 tons of particulate matter (PM) has been emitted over the last 100 years as a result of mining activities in Sudbury, Ontario, Canada. Much of the PM has been deposited in the local soils, causing elevated concentrations of Cu, Ni, Zn, Se, As, and Pb. The goal of this study is to determine the distribution of metals and metalloids in PM in order to draw conclusions about their formation, their weathering, and the mobility of these elements in the local soils. The PM and associated secondary phases have been studied using optical microscopy, SEM, micro-Raman spectroscopy, and laser ablation inductively coupled plasma mass spectrometry. Spherical PM forms during the rapid cooling of hot gasses and is predominantly composed of Cu- and Ni-bearing spinel, silicate, and sulfide mineral inclusions. The collision of precursors of spherical PM with aerosols of residual matte and slag results in the formation of metal- and metalloid-rich outer rims on each sphere. These rims, as well as Fe-silicate and spinel minerals in the silicate-oxide matrix, weather to hematite during a dissolution-precipitation process. Metals and metalloids are released during this process in non-stoichiometric proportions relative to their initial concentration in the spinel, as they have different affinities to sorb on surface sites during their diffusion through the hematite precipitate. Metal-bearing sulfide inclusions alter to sulfate and occasionally into oxide minerals, which are enriched in Ni, Co, and Cu. Particulate matter composed of angular sulfide minerals and NiO particulates is often coated with Fe-Al-hydroxide and aluminosilicate minerals. The coatings contain higher trace-metal and metalloid concentrations than the underlying PM and are thus sinks for metals and metalloids released by other types of PM. The mobility of metals and metalloids in the soils decreases in the sequence Zn Cu Ni Pb and is the result of differences in element adsorption affinities and dissolution rates of phases in the PM.
Compilation and indexing terms, Copyright 2018 Elsevier Inc.<br/>20145200355429<br/>Aluminosilicate minerals<br/>Dissolution-precipitation process<br/>Elevated concentrations<br/>Initial concentration<br/>Laser ablation inductively-coupled plasma mass spectrometries<br/>Micro Raman Spectroscopy<br/>Particulate Matter<br/>Smelter