Chapter
3
RIA
References
for
E­
Document
References
Cited
 
Not
Available
Electronically
Ambrose,
R.
B.,
1987.
Modeling
Volatile
Organics
in
the
Delaware
Estuary.
Journal
of
Environmental
Engineering,
113(
4):
703­
721.
Ambrose,
R.
B.
and
Wool,
T.
A.,
2001.
Modeling
Tools
Used
for
Mercury
TMDLs
in
Georgia
Rivers.
In:
K.
Hatcher
(
Editor),
Proceedings
of
the
2001
Georgia
Water
Resources
Conference,
March
26­
27,
2001.
University
of
Georgia:
Athens,
Georgia,
Athens,
GA,
pp.
532­
535.
Ambrose,
R.
B.
e.
a.,
1988.
WASP4,
A
Hydrodynamic
and
Water
Quality
Model­­
Model
Theory,
User's
Manual,
and
Programmer's
Guide.,
U.
S.
Environmental
Protection
Agency,
Athens,
GA.
EPA/
600/
3­
87­
039.
Barber,
M.,
2003.
A
review
and
comparison
of
models
for
predicting
dynamic
chemical
bioconcentration
in
fish.
Environmental
Toxicology
and
Chemistry,
22(
9):
1963­
1992.
Barber,
M.
C.,
Suárez,
L.
A.
and
Lassiter,
R.
R.,
1987.
FGETS
(
Food
and
Gill
Exchange
of
Toxic
Substances):
A
simulation
model
for
predicting
the
bioaccumulation
of
nonpolar
organic
pollutants
by
fish,
U.
S.
Environmental
Protection
Agency,
Office
of
Research
and
Development,
EPA/
600/
3­
87/
038,
Athens,
GA.
Barber,
M.
C.,
Suárez,
L.
A.
and
Lassiter,
R.
R.,
1988.
Modeling
bioconcentration
of
nonpolar
organic
pollutants
by
fish.
Environmental
Toxicology
and
Chemistry,
7:
545­
558.
Barber,
M.
C.,
Suárez,
L.
A.
and
Lassiter,
R.
R.,
1991.
Modelling
bioaccumulation
of
organic
pollutants
in
fish
with
an
application
to
PCBs
in
Lake
Ontario
salmonids.
Canadian
Journal
of
Fisheries
and
Aquatic
Sciences,
48:
318­
337.
Benoit,
J.
M.,
Gilmour,
C.
C.,
Heyes,
A.,
Mason,
R.
P.
and
Miller,
C.,
2003.
Geochemical
and
Biological
Controls
over
Methylmercury
Production
and
Degradation
in
Aquatic
Systems,
Biogeochemistry
of
Environmentally
Important
Trace
Metals.
ACS
Symposium
Series
835.
Benoit,
J.
M.,
Mason,
R.
P.
and
Gilmour,
C.
C.,
1999.
Estimation
of
mercury­
sulfide
speciation
in
sediment
pore
waters
using
octanol­
water
partitioning
and
implications
for
availability
to
methylating
bacteria.
Environmental
Toxicology
and
Chemistry,
18(
10):
2138­
2141.
Bigham,
G.
N.
and
Vandal,
G.
M.,
1994.
A
drainage
basin
perspective
of
mercury
transport
and
bioaccumulation:
Onondaga
Lake,
New
York,
Twelfth
International
Neurotoxicology
Conference,
Hot
Springs,
Arkansas
USA.
Branfireun,
B.
and
Roulet,
N.,
2002.
Controls
on
the
fate
and
transport
of
methylmercury
in
a
boreal
headwater
catchment,
northwestern
Ontario,
Canada.
Hydrology
and
Earth
System
Sciences,
6(
4):
785­
794.
Compeau,
G.
C.
and
Bartha,
R.,
1987.
Effect
of
salinity
on
mercury­
methylating
activity
of
sufate
reducing
bacteria
in
estuarine
sediments.
Applied
and
Environmental
Microbiology,
53:
261­
265.
Connolly,
J.
and
Thomann,
R.
V.,
1985.
WASTOX,
A
Framework
for
Modeling
the
Fate
of
Toxic
Chemicals
in
Aquatic
Environments.
Part
2:
Food
Chain.,
U.
S.
Environmental
Protection
Agency,
Gulf
Breeze,
FL
and
Duluth,
MN.
Craig,
P.
J.
and
Bartlett,
P.
D.,
1978.
The
role
of
hydrogen
sulphide
in
environmental
transport
of
mercury.
Nature,
275:
635­
637.
Craig,
P.
J.
and
Moreton,
P.
A.,
1986.
Total
mercury,
methyl
mercury
and
sulphide
levels
in
British
estuarine
sediments­
III.
Water
Research,
20(
9):
1111­
1118.
Di
Toro,
D.
M.,
Fitzpatrick,
J.
J.
and
Thomann,
R.
V.,
1983.
Water
Quality
Analysis
Simulation
Program
(
WASP)
and
Model
Verification
Program
(
MVP)
­
Documentation.,
Hydroscience,
Inc.,
Westwood,
NY,
for
U.
S.
EPA,
Duluth,
MN,
Contract
No.
68­
01­
3872.
Driscoll,
C.
T.
et
al.,
1995.
The
role
of
dissolved
organic
carbon
in
the
chemistry
and
bioavailability
of
mercury
in
remote
Adirondack
lakes.
Water,
Air,
Soil
Pollution,
80:
499­
508.
EPRI,
2003.
Factors
Affecting
Predicted
Responses
of
Fish
Mercury
Concentrations
to
Changes
in
Mercury
Loading.,
Electric
Power
Research
Institute
Report
1005521,
Palo
Alto,
CA.
Fitzgerald,
W.
F.,
Mason,
R.
P.,
Vandal,
G.
M.
and
Dulac,
F.,
1994.
Air­
water
cycling
of
mercury
in
lakes.
In:
C.
J.
Watras
and
J.
W.
Huckabee
(
Editors),
Mercury
Pollution:
Integration
and
Synthesis.
Lewis
Publishers,
Chelsea,
MI,
pp.
203­
220.
Gilmour,
C.
C.
and
Henry,
E.
A.,
1991.
Mercury
methylation
in
aquatic
systems
affected
by
acid
deposition.
Environmental
Pollution,
71:
131­
169.
Greenfield,
J.,
Dai,
T.
and
Manguerra,
H.,
2002.
Watershed
Modeling
Extensions
of
the
Watershed
Characterization
System.,
Ft.
Lauderdale,
Florida,
USA,
February
2002.
Harris,
R.
and
Hutchison,
D.,
2003.
Factors
Affecting
the
Predicted
Response
of
Fish
Mercury
Concentrations
to
Changes
in
Mercury
Loading.
1005521,
Electric
Power
Research
Institute,
Palo
Alto,
CA.
Harris,
R.
C.
et
al.,
2004.
The
METAALICUS
Project:
Overview
of
Study
and
Results
To­
Date,
7th
Internation
Conference
on
Mercury
as
a
Global
Pollutant,
Slovenia.
Hintelmann,
H.,
Keppel­
Jones,
K.
and
Evans,
R.
D.,
2000.
Constants
of
mercury
methylation
and
demethylation
rates
in
sediments
and
comparison
of
tracer
and
ambient
mercury
availability.
Environmental
Toxicology
and
Chemistry,
19(
9):
2204­
2211.
Jackson,
T.
A.,
1998.
Mercury
in
aquatic
ecosystems.
In:
W.
J.
Langston
and
M.
J.
Bebianno
(
Editors),
Metal
Metabolism
in
Aquatic
Environments.
Chapman
&
Hall,
London,
pp.
77­
158.
Kidd,
K.,
Hesslein,
R.,
Fudge,
R.
and
Hallard,
K.,
1995.
The
influence
of
trophic
level
as
measured
by
delta­
N­
15
on
mercury
concentrations
in
fresh­
water
organisms.
Water,
Air,
and
Soil
Pollution,
80(
1­
4):
1011­
1015.
Landis,
M.
S.,
Lynam,
M.
and
Stevens,
R.
K.,
2004.
The
Monitoring
and
Modeling
of
Mercury
Species
in
Support
of
Local
Regional
and
Global
Modeling.
In:
N.
Pirrone
and
K.
R.
Mahaffey
(
Editors),
Dynamics
of
Mercury
Pollution
on
Regional
and
Global
Scales.
Kluwer
Academic
Publishers,
New
York,
NY.
Lee,
Y.
H.,
Bishop,
K.,
Pettersson,
C.,
Iverfeldt,
I.
and
Allard,
B.,
1995.
Subcatchment
Output
of
Mercury
and
Methylmercury
at
Svartberget
in
Northern
Sweden.
Water,
Air,
and
Soil
Pollution,
80:
455­
465.
Mierle,
G.
and
Ingram,
R.,
1991.
The
role
of
humic
substance
in
the
mobilization
of
mercury
from
watersheds.
Water,
Air,
and
Soil
Polution,
56:
349­
357.
Morel,
F.,
Kraepiel,
A.
M.
L.
and
Amyot,
M.,
1998.
The
chemical
cycle
and
bioaccumulation
of
mercury.
Annual
Reviews
of
Ecological
Systems,
29:
543­
566.
Neitsch,
S.
L.,
Arnold,
J.
G.,
Kiniry,
J.
R.,
Williams,
J.
R.
and
King,
K.
W.,
2002.
Soil
and
Water
Assessment
Tool
theoretical
documentation
­
version
2000.
TWRI
Report
TR­
191.,
Texas
Water
Resources
Institute,
College
Station,
Texas.
Pollman,
C.
et
al.,
1991.
Preliminary
analysis
of
the
hydrologic
and
geochemical
controls
on
acid­
neutralizing
capcity
in
two
acidic
seepage
lakes
in
Florida.
Water
Resources
Research,
27(
9):
2321­
2355.
Schroeder,
W.
H.,
Munthe,
J.
and
Lindqvist,
O.,
1989.
Cycling
of
mercury
between
water
air
and
soil
compartments
of
the
environment.
Water,
Air,
and
Soil
Pollution,
48:
337­
347.
Tsiros,
I.,
2002.
Modeling
assessment
of
air
emission
flux
of
mercury
from
soils
in
terrestrial
landscape
components:
Model
tests
and
sensitivities.
Journal
of
Air
and
Waste
Management
Association,
52(
3):
339­
348.
Tsiros,
I.
X.,
1999.
A
Modeling
Analysis
of
Factors
Influencing
Mass
Balance
Components
of
Airborne
Deposited
Mercury
in
Terrestrial
Landscapes.
J.
Environ.
Sci.
Health
A,
34(
10):
1079­
2005.
Wren,
C.
D.
and
MacCrimmon,
H.
R.,
1986.
Comparative
bioaccumulation
of
mercury
in
two
adjacent
freshwater
ecosystems.
Water
Research,
6:
763­
769.
