[107] ODA (2002). Administrative rule developed to declare limits of certain metals in fer‐
tilizer, agricultural amendments, agricultural mineral and lime products distributed
in Oregon.
Oregon Department of Agriculture; ODA White Paper 08/2002.
[108] Porvari, P, Verta, M., Munthe, J. & Haapanen, M. (2003). Forestry practices increase
mercury and methyl mercury output from boreal forest catchments.
Environmental
Science and Technology, 37, 2389-2393.
[109] Protano, G., Riccobono, F. & Sabatini, G. (2000). Does salt water intrusion constitute a
mercury contamination risk for coastal fresh water aquifers?
Environmental Pollution,
110, 451-458.
[110] Ravichandran, M. (2004). Interactions between mercury and dissolved organic matter
—a review.
Chemosphere, 55, 319-331.
[111] Ravichandran, M., Aiken, G.R., Ryan, J.N. & Reddy, M.M., (1999). Inhibition of pre‐
cipitation and aggregation of metacinnabar (mercuric sulfide) by dissolved organic
matter isolated from the Florida Everglades.
Environmental Science and Technology, 33,
1418-1423.
[112] Reddy, M.M. & Aiken, G.R. (2001). Fulvic acid-sulfide ion competition for mercury
ion binding in the Florida Everglades.
Water, Air, and Soil Pollution,
132, 89-104.
[113] Reilly, P.A., Barringer, J.L. & Szabo, Z. (2012). Mobility of mercury from sandy soils
into acidic groundwater, New Jersey Coastal Plain: Geological
Society of America
Abstracts, v. 44, no. 2, p. 118, Abstract 53-2.
[114] Reimann, C., Siewers, U., Skarphagen, H. & Banks, D. (1999). Influence of filtration
on concentrations of 62 elements analyzed on crystalline bedrock groundwater sam‐
ples by ICP-MS.
Science of the Total Environment, 234, 155-173.
[115] Reimers, R.S. & Krenkel, P.A. (1974). Kinetics of mercury adsorption and desorption
in sediments.
Journal of the Water Pollution Control Federation, 46, 3520365.
[116] Repert, D.A, Barber, L.B., Hess, K.M., Keefe, S.H., Kent, D.B., LeBlanc, D.R. & Smith,
R.L. (2006). Long-term natural attenuation of carbon and nitrogen within a ground‐
water plume after removal of the treated wastewater source.
Environmental Science
and Technology, 40, 1154-1162.
[117] Rudd, J.W.M. (1995). Sources of methyl mercury to freshwater ecosystems—a re‐
view.
Water, Air, and Soil Pollution, 80, 697-713.
[118] Ryan, J.N. & Gschwend, P.M. (1990). Colloid mobilization
in two Atlantic Coastal
Plain aquifers: field studies.
Water Resources Research, 26, 307-322.
[119] Ryan, J.N. & Gschwend, P.M. (1994). Effect of solution chemistry on clay colloid re‐
lease from an iron oxide-coated aquifer sand.
Environmental Science and Technology,
28, 1717-1726.
Occurrence and Mobility
of Mercury in Groundwater
http://dx.doi.org/10.5772/55487
145
[120] Rytuba, J.J. (2000). Mercury mine drainage and processes that control its environ‐
mental impact.
Science of the Total Environment 260, 57-71.
[121] Rytuba, J.J., Ashley, R., Slowey, A.,J. Brown, G.E. & Foster, A. (2005). Mercury specia‐
tion and transport from historic
placer gold and mercury mines, California. (Ab‐
stract).
Geological Society of America, Abstracts with Programs, 37, 104.
[122] Saether, O.M., Storroe, G., Segar, D. & Krog, R. (1997). Contamination of soil and
groundwater at a former industrial site, Trondheim, Norway.
Applied Geochemistry,
12, 327-332.
[123] Savoie, J.G., LeBlanc, D.R., Fairchild, G.M., Smith, R.L., Kent, D.B., Barber, L.B., Re‐
pert, D.A., Hart, C.P., Keefe, S.H. & Parsons, L.A. (2012). Groundwater-quality data
for a treated-wastewater plume near the Massachusetts Military Reservation, Ashu‐
met Valley, Cape Cod, Massachusetts, 2006-08.
U.S. Geological Survey Data Series 648,
11 p.
[124] Schuster, P.F., Krabbenhoft, D.P., Naftz, D.L., Cecil, L.D., Olson, M.L., DeWild, J.F.,
Susong, D.D., Green, J.R. & Abott, M.L. (2002). Atmospheric mercury deposition dur‐
ing the last 270 years: a glacial ice core record of natural and anthropogenic sources.
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