[19] Barringer, J.L., Szabo, Z. & Reilly, P.A. (2012). Mercury in waters, soils and sediments
of the New Jersey Coastal Plain: A comparison of regional distribution and mobility
to the mercury contamination at the William J.
Hughes Technical Center, Atlantic
County, New Jersey.
U.S. Geological Survey Scientific Investigations Report 2012-5115
[20] Behra, P. (1986). Evidences for the existence of a retention phenomenon during the
migration of a mercurial solution through a saturated porous medium.
Geoderma, 38,
209-222.
[21] Benoit, J.M., Gilmour, C.C., Mason, R.P. & Heyes, A. (1999). Sulfide controls on mer‐
cury speciation and bioavailability to methylating bacteria in sediment pore waters.
Environmental Science and Technology, 33, 951-957.
[22] Benoit, J.M., Mason, R.P., Gilmour, C.C. & Aiken, G.R. (2001). Constants for mercury
binding by dissolved organic matter isolated from the Florida Everglades.
Geochimica
et Cosmochimica Acta, 65, 4445-4451.
[23] Bhavsar, S.P., Gewurtz, S.B., McGoldrick, D.J., Keir, M.J. & Backus, S.M., (2010).
Changes in mercury levels in Great Lakes fish between 1970s and 2007.
Environmental
Science and Technology, 44, 3273-3279.
[24] Biester, H., Schihmacher, P. & Müller, G. (2000). Effectiveness of mossy tin filters to
remove mercury from aqueous solution by Hg(II) reduction and Hg(0) amalgama‐
tion.
Water Research, 34, 2031-2036.
[25] Black, F.J., Paytan, A., Knee, K.L., de Sieyes, N.R., Ganguli, P.M., Gray, E. & Flegal, R.
(2009). Submarine groundwater discharge of total mercury and monomethylmercury
to Central California coastal waters.
Environmental Science and Technology, 43,
5652-5659.
[26] Bollen, A., Wenke, A. & Biester, H. (2008). Mercury speciation analyses in HgCl
2
-con‐
taminated soils and groundwater—implications for risk assessment and remediation
strategies.
Water Research, 42, 91-100.
[27] Bone, S.E., Charette, M.A., Lamborg, C.H. & Gonneea, M.E. (2007). Has submarine
groundwater discharge been overlooked as a source of mercury to coastal waters?
Environmental Science and Technology, 41, 3090-3095.
[28] Bouffard & Amyot (2009). Importance of elemental mercury in lake sediments.
Che‐
mosphere, 74, 1098-1103.
[29] Bower, J., Savage, K.S., Weinman, B., Barnett, W.P. & Harper, W.F. (2008). Immobili‐
zation of mercury by pyrite (FeS
2
),
Environmental Pollution, 156, 504-514.
[30] Bradley, P., Burns, D., Murray, K., Brigham, M., Button, D., Chasar, L., Marvin-Di‐
Pasquale, M., Lowery, M. & Journey, C.A. (2011). Spatial and seasonal variability of
dissolved methylmercury in two stream basins in the eastern United States.
Environ‐
mental Science and Technology, 45, 2048-2055.
Current Perspectives in Contaminant Hydrology and Water
Resources Sustainability
138
[31] Bradley, P. & Journey, C. (2012). Hydrology and methylmercury availability in
Coastal Plain streams. Chapter 8, 169-190. In: Water Resources Management and
Modeling: Nayak, P., (ed.). InTech Open Access Publishing. Available at http://
www.intechopen.com/books/ water-resources-management-and-modeling.
[32] Bradley, P.M., Journey, C.A., Lowery, M.A., Brigham, M.E., Burns, D.A., Button,
D.T., Chapelle, F.H., Luz, M.A., Marvin-DiPasquale, M.C. & Riva-Murray, K. (2012).
Shallow groundwater mercury supply in a Coastal Plain stream.
Environmental Sci‐
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