|
Background
 Atmospheric
deposition [figure 1] is generally accepted as the principal
mechanism of mercury introduction into aquatic ecosystems. New England
is thought to have one of the highest deposition rates anywhere
in the United States. Major sources of mercury deposition in New
England are emissions from municipal waste incinerators, coal and
oil boilers, and medical waste incinerators. Through environmental
processes, mercury (Hg) in its inorganic form can be transformed
into methyl mercury (MeHg) and accumulate in aquatic organisms.
Urbanization is postulated to affect the production and accumulation
rates of MeHg. The major route of human exposure to mercury is through
the diet, more specifically from consumption of fish. MeHg is the
most toxic and bioaccumulative form of mercury in the environment,
and comprises greater than 95 percent of the mercury in fish. Elevated
mercury concentrations in fish have resulted in the issuance of
fish consumption advisories [figure
2] in all states of New England and throughout the Northeastern
United States.
Figure credits:
Figure 1. Modeled/predicted mercury deposition rates for the contiguous
48 states (from Russ Bullock, NOAA/EPA)
Figure 2. Fish consumption
advisories for mercury (Krabbenhoft
and Rickert, 1995)
Purpose and study design
Results of a
national assessment of mercury contamination of aquatic systems
found that the New England Coastal Basins area had among the highest
mercury concentrations and rates of mercury methylation in the nation
(Krabbenhoft and others, 1999; Brumbaugh and others, 2001). Because
of these findings, the New England Coastal Basins study team, in
collaboration with the USGS Toxic Substances Hydrology Program,
conducted a regional study of how total mercury (HgT) and MeHg in
water and streambed sediments and HgT in fish varied in relation
to the amount of urbanization in a watershed. The
purposes of this study were to (1) determine whether gradients in
HgT and MeHg contamination are evident along urban gradients; and
(2) to evaluate whether Hg loading rates or ecosystem factors were
more influential in generating regional Hg gradients in fish in
New England streams.
Water and bed
sediment were sampled during 1998 - 2000 from 55 stream sites, and
fish tissue from a subset of 27 sites. Sites were selected to span
a range from a major metropolitan area (Boston), where mercury loading
is presumably greater, to comparatively remote regions of southern
Maine, where known mercury emissions are far fewer and more distant.
Most of the sites were chosen to be located in one ecoregion - the
Northeastern Coastal Zone - to minimize the effect of natural features
on study results. Sediment, water, and fish tissue samples were
collected over a one week period during summer low flow conditions
to show patterns of HgT and MeHg accumulation and partitioning relative
to watershed conditions.
See Table
1
for site names and characterization.
| Study
Location Maps
|
click
for full view
Sediment and water
sampling locations |
click
for full view
Fish tissue
sampling locations |
General
results
Concentrations
of HgT ranged from 0.7 to 13.7 nanograms per liter (ng/L) in water
and from 7.2 to 3,100 nanograms per gram (ng/g) dry weight in streambed
sediment. HgT concentrations followed an urban gradient with highest
concentrations in urban areas and lowest concentrations in rural
areas in Maine and New Hampshire. Concentrations of MeHg ranged
from 0.04 to 1.8 ng/L in water and from 0.3 to 15.6 ng/g dry weight
in sediment. Concentrations of MeHg in water and sediment did not
follow an urban gradient, but were positively correlated with concentrations
of organic carbon. HgT concentrations in fish tissue ranged from
40 to 398 ng/g wet weight and were positively correlated with concentrations
of MeHg in water and bed sediment. A positive relation was not observed
between HgT concentrations in fish tissue and HgT concentrations
in water and bed sediment. Methylation efficiency, as estimated
by MeHg/HgT, ranged from 0.003 to 0.282 for sediment and water samples,
with a median value of 0.071. Methylation efficiency was highest
at sampling sites with low urbanization and high organic carbon
concentrations. (Chalmers and Krabbenhoft, 2001)
|
Mercury Data Tables |
| |
|
|
Streambed
sediment
|
|
|
|
Water
|
|
|
|
Fish
Tissue
|
|
|
|
Protocols
used for the NECB Mercury study
Fitzgerald,
W.F., and Watras, C.J., 1989, Mercury in surficial waters of rural
Wisconsin lakes: Science of the Total Environment, v. 87/88,
277-291.
Olson, M.L.,
and DeWild, J.F., 1999, Low-level techniques for the collection
and species-specific analysis of low levels of mercury in water,
sediment, and biota, in Morganwalp, D.W., and Buxton, H.T.,
eds., U.S. Geological Survey Toxic Substances Hydrology Program--Proceedings
of the Technical Meeting, Charleston, South Carolina, March 8-12,
1999--Volume 2--Contamination of Hydrologic Systems and Related
Ecosystems: U.S. Geological Survey Water-Resources Investigations
Report 99-4018B, p. 191-200.
Shelton, L.R.
and Capel, P.D., 1994, Guidelines for collecting and processing
samples of stream bed sediment for analysis of trace elements and
organic contaminants for the National Water-Quality Assessment program,
U.S. Geological Survey Open-File Report 94-458, 20 p.
References
Brumbaugh, W.G.,
Krabbenhoft, D.P., Helsel, D.R., Weiner, J.G., and Echols K.R.,
2001, A
national pilot study of mercury contamination of aquatic ecosystems
along multiple gradients: Bioaccumulation in fish [PDF format,
1.8 MB]: U.S. Geological Survey Biological Science Report, BSR-2001-0009,
25 p.
Chalmers, A.T.,
and Krabbenhoft, D.P., 2001, Total
and methyl mercury distribution in water, sediment, and fish tissue
in New England streams, American Geophysical Union (AGU) Spring
Meeting, May 29-June 2, 2001, Boston, Mass.
Krabbenhoft,
D.P., Wiener, J.G., Brumbaugh, W.G., Olson, M.L., DeWild, J.F.,
and Sabin, T.J., 1999, A
national pilot study of mercury contamination of aquatic ecosystems
along multiple gradients, in Morganwalp, D.W., and Buxton,
H.T., eds., U.S. Geological Survey Toxics Substances Hydrology Program
- Proceedings of the Technical Meeting, Charleston, South Carolina,
March 8-12, 1999 - Volume 2 - Contaminants of Hydrologic Systems
and Related Ecosystems: U.S. Geological Survey Water-Resources Investigations
Report 99-4018B, 13 p.
Krabbenhoft,
D.P. and Rickert, D.A., 1995, Mercury
Contamination of Aquatic Ecosystems: U.S. Geological Survey
Fact Sheet 216-95, 4 p.
Related information
USGS
Mercury Studies Team
Mercury
in the Environment
(USGS Fact Sheet, October 2000)
Fish
consumption advisories (Mineral
Resources Program, USGS)
New
England Coastal Basins Mercury Deposition Network
|
