905R84115
UNITED STATES PHOSPHORUS LOADS
TO LAKES ERIE AND ONTARIO
AND SAGINAW BAY FOR 1982
Prepared by: Paul J. Horvatin
Anne Baughman
U.S. Environmental Protection Agency
Great Lakes National Program Office
July 1984
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Introduction
Annex 3 of the 1978 Great Lakes Water Quality Agreement and its Supplement
requires that both the United States and Canada confirm future phosphorus
loads and establish load allocations and compliance schedules for meeting
those loads. The Annex 3 Supplement establishes phosphorus target loads and
load reductions for the Lower Lakes, Lakes Erie and Ontario, and Saginaw Bay.
In order to provide the Great Lakes States with a basis for state and
river basin load planning, it is necessary to have an estimate of the loading
from each tributary and the amount of potential load reduction. For this
report it was agreed that the 1982 water year would be used as a base year
for Lakes Erie and Ontario and the 1980 water year for Saginaw Bay.
This report summarizes total phosphorus loads for water year 1982 by major
river basins and includes municipal and industrial point sources as well as
nonpoint sources. The intent of this report is to partition the known phosphorus
load to the Lower Lakes into its tributary origins and point/nonpoint compon-
ents. The report and any conclusions derived from it are totally dependent
on the reliability and accuracy of the phosphorus load data bases. Some of
the tributary load values are estimated since neither flow nor concentration
data is routinely collected on a regular basis. Unmonitored tributaries are
listed for Lakes Erie and Ontario. Point source data is reported by each
discharger as required by the NPDES permit system for both monitored and
unrnonitored tributaries. Overall there does appear to be satisfactory corre-
lations between lake phosphorus concentrations and reported loadings.
Figures 1, 2, and 3 summarize phosphorus loads for Lake Erie, Lake Ontario and
Saginaw Bay, respectively. Total hydrologic drainage area loads and basin
loads including all components are provided. Excess municipal loads, which are
those loads above or below a 1.0 mg/1 effluent phosphorus concentration, are
given. A negative excess load means that a single or group of municipal
facilities are collectively discharging effluent with a phosphorus concentration
below 1.0 mg/1. A positive excess load means that the facilities are
discharging an effluent with a phosphorus concentration above 1.0 mg/1. This
positive excess load is that amount of phosphorus which is expected to be
reduced when the facilities comes into compliance with the 1.0 mg/1 effluent
phosphorus requirement.
Methodology
The study period for this report is water year 1982 (October 1981 - September
1982). This year was chosen because it is the most recent year for which
complete and accurate tributary phosphorus data and point source data is
available. Based on U.S. Geological Survey (USGS) Great Lakes tributary flow
data, (water resources data-Michigan, Ohio, Indiana, New York, Pennsylvania,
1982) water year 1982 in general appears to be representative of average or
near normal stream flow conditions in the lower lakes Basin. Exceptional
rainfall events in any specific tributary may have occurred during the water
year. Reported phosphorus loads from tributaries with exceptionally high or
low flow events should be carefully evaluated by the reviewer.
Lakes Erie and Ontario and Saginaw Bay drainage basins were subdivided into
hydrologic areas (complexes and river basins) following the procedures used in
the U.S. Task D reports on Great Lakes Pollution From Land Use Activities by
the international Joint Commission. River Basin group maps and a brief
narrative description of each hydrologic area is included as Appendix 1
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-2-
Municipal and industrial point sources were divided into direct and indirect
discharges for each major drainage basin to avoid double counting of phosphorus
loads. Direct discharges are defined as a point source of phosphorus below
the tributary monitoring station or having an outfall discharging into the
lake proper. Indirect discharges are defined as a point source above the
tributary monitoring station so that the tributary load calculated at the
monitoring station includes those point sources. All known point sources of
phosphorus for each drainage basin are listed in Appendix 2.
The 1982 phosphorus load for each hydrologic area was calculated by adding
the tributary component and direct municipal and industrial point sources.
The nonpoint component of each hydrologic area phosphorus load was calculated
by subtracting the indirect municipal and industrial point source loads from
the tributary load. (See figures 1, 2 and 3 for examples) The assumption for
these calculations is that the tributary load accounts for all sources of
phosphorus within the drainage basin including indirect point sources, non
point, and natural background.
Sources of Data
Tributary phosphorus load data was obtained from Dr. John Clark, International
Joint Commission (IJC) Windsor, Ontario Regional Office. Dr. Clark prepares
annual phosphorus tributary loading summaries for each of the Great Lakes as
secretariat to the IJC Water Quality Board's Surveillance Workgroup.
Tributary flow data from USGS gaged streams and phosphorus concentration
data from USGS, USEPA and State monitoring stations is used to calculate
tributary loads. When tributary sampling is conducted on varying frequencies
(i.e. monthly grab, 24 composite etc.) during the water year, a stratum or
grouping of data is established for each distinctive sampling frequency. Daily
grab samples for example are not averaged with 24 hour flow weighted samples.
Each sample frequency is treated as a distinct data set. The reference for
the methodology used is discussed in Sampling Techniques by William Cochran,
3rd Edition John Wiley & Son.
Phosphorus loads are estimated for unmonitored tributaries by using a unit
area ratio of an adjoining monitored tributary less its point sources.
Appendix 3 lists for Lakes Erie and Ontario those tributaries which are
monitored and unmonitored in addition to phosphorus loads in metric tons/year.
1980 tributary load data was used for Saginaw Bay since it was the only year
for which complete monitoring data is available for all rivers in the basin.
Point source load data for phosphorus is reported by each of the Great Lakes
States for all major and significant municipal and industrial dischargers.
The State Pollution Control Agencies receive their data from each of the
NPDES permitted dischargers on a monthly basis. The data is then collected and
summarized by USEPA annually for transmittal to the International Joint Commission,
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-3-
Summary
Figure 4 summarizes the total phosphorus load to Lake Erie, Lake Ontario and
Saginaw Bay. Each of the components of the total load, tributary, point and
non-point, are quantified. Based on the assumption that water year 1982 was
generally representative of stream flow conditions in the Lower Lakes and
Saginaw Bay, these loads should provide a perspective of the tributary origins
and source magnitude of phosphorus. The total load and its components are
quantities of total phosphorus actually delivered to the Lakes in 1982. The
delivered load has not been adjusted nor corrected to reflect long term
conditions or averages.
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APPENDIX 1
LAKE BASIN MAPS
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APPENDIX 1
LAKE ERIE
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z
0
436
SCALE IN MILES
0 10 20 30 40 SO
-------�
Figure 19
RIVER BASIN GROUP 4.1
/ ''
VENAWE; /^MICHIGAN
SCALE IN MILES
0 5 10
15
-------�
Hydrologic Area_4.1.1 _)
Black Creek (St. Clair)'
The Black River encompasses an area of 180,000 hectares (446,000 acres). In the
central portion of Michigan's Lower Peninsula the Black River has a mean annual
Hlrharee of 7.8 m3's (275 cfs). An important tributary to the Black River is
Mill Creek The area is generally flat and has a significant amount of wetlands.
.Approximately 20 percent of area exists as scattered forested areas about 60
percent is (utilized in agriculture, and 10 percent is urbanized. The bedrock
consists primarily of sandstone. The material covering the bedrock is composed
of silt and clay near the shore and glacial till throughout the rest of the b.asin.
Important gas fields and salt formations exist in the area Approximately three
najor municipalities and four major industries use the surface waters of this area
Tor waste assimilation. The cities of Port Huron (pop.: 35,794), and Marysville
(pop.: 5,610) are the major population centers in the area.
Station Key
Station
Location
Black River
a
b
c
d
e
f
g
h
DAM River
and
Station Numbers
41101
4110101
4110102
4110103
4110104
4110105
4110106
4110107
4110108
441
-------�
Hydrologic Area 4.1.1
Black River
Vicinity Map-RBG 4 1
<7\
SAN I LAC
ST. CLAIR
SCALE IN MILES
0 5
440
10
15
-------�
Hydrologic Area 4.1.2
St. Clair Complex
Vicinity Map-RBG 4.1
SCALE IN MILES
10
15
AA2
-------�
Hydrologic Area 4.1.2
St. Clair Complex
The St. Clair Complex includes 155,000 hectares (383,000 acres) in the
southeast portion of Michigan's Lower Peninsula. The major rivers draining
the area are the Pine River (ungaged), and the Belle River, which has a mean
annual discharge of 2.3 m 's (81 cfs). Both of these rivers drain into the
*St. Clair R4.ver. There are a number of other small streams that also provide drainag<
for this complex. This area is generally flat with few wetlands. Approximately
15 percent of the area is forested, 60 percent devoted to agriculture, and 15
percent urbanized. The bedrock is composed principly of sandstone. The overlying
material is composed of silt, clay and glacial till. Several municipalities and
industries use the area's rivers for waste assimulation. The cities of
St. Clair (pop.: 4,770), Marine City (pop.: 4,567), New Baltimore (pop.: 4,142),
and Richmond (pop.: 3,234) are the areas of greatest human pressure on the Complex.
Station Key
Station
Location
Pine River
a
b
c
d
e
Belle River
f
g
h
i
j
Marsh Drain
k
Beaubien Creek
1
Swan Creek
— m -
n
Marsac Creek
o
Salt River
P
DAM River
and
Station Numbers
41201
4120101
4120102
4120103
4120104
4120105
41202
4120201
4120202
4120203
4120204
4120205
41203
4120301
41204
420401
41205
4120501
4120502
41206
4120601
41207
4120701
443
-------�
Hydrologic Area 4.1.3
Clinton River
ST. CLAIR
WACOM B
SCALE IN MILES
10
15
Vicinity Map-RBG 4.1
444
-------�
Hydrologic Area 4.1.3
Clinton River
The Clinton River drains an area of 155,000 hectares (383,000 acres). The
area is located in the southeast portion of Lake Michigan's Lower Peninsula. The
Clinton River has a mean annual discharge of 14.3 m^'s (505 cfs) and drains
*into Lake S^. Clair. Major tributaries to the Clinton River are the North
Branch, Paint Creek, and Red Run. There are several additional small streams that
also provide drainage for the area. The topography varies from flat to rolling
with few wetlands. About 15 percent of the area is forested, 50 percent
agriculturalized, and 20 percent found in highly developed metropolitan areas.
The bedrock is composed primarily of sandstone. The surface material consists
of silt, clay and glacial till. Heavy industrial development, to a large extent
associated with the automotive industry, is a major influence on the water
quality of this area. A considerable amount of the area's municiple waste
is treated by Detroit Water Services and discharged to the Rouge River in
Hydrologic Area 4.1.4. However, there still is significant municiple and
industrial discharge into the surface waters. The Clinton River is characteris-
tically sluggish (as many of the streams draining into the western portion of
Lake Erie) and carries a high silt load. Cities of Pontiac (pop.: 85,279),
Mt. Clements (pop.: 20,476), and Rochester (pop.: 7,054) are the major
concentrated population centers in the area.
Station Key
DAM River
Station and
Location Station Numbers
Clinton River 41301
a 4130101
b 4130102
c 4130103
d 4130104
e 4130105
445
-------�
Hydrologic Area 4.1.4
Rouge Complex
Northville • WAYNE
Vicinity Map-RBG 4.1
•
^-x\. v\v**
^- \ -=>*. o-
' ' ^ ~ ^ - >• v
/. - •—• ^>--*»c- "x ^ '
/ i-y ^T ^^.^ t >
^\ 21 * *
V—^^-~\ A' ^
• !..•« Mtt ma*n «*,.o. ^. i /
SCALE IN MILES
A46
10
15
-------�
Hydrologic Area 4.1.4
Rouge Complex
The Rouge Complex encompasses an area of 189,000 hectares (468,00 acres).
The Complex is located in the southeast portion of Michigan's Lower Peninsula.
The major tributary in the area is the Rouge River, which has a mean annual
discharge of approximately 6.4 m s (226 cfs). Major tributaries to the Rouge
^ River are the Upper, Middle, and Lower Rouge Rivers. The area is generally
flat with few wetlands. Approximately 15 percent of the area is forested,
another 20 percent devoted to agriculture, and over 50 percent consists of the
highly developed Detroit Metropolitan Area. Bedrock is composed of sandstone
and shale. The overlying material consists of silt and clay with some
glacial till. Heavy industry, to a large extent associated with the automobile
industry, effects the water quality of this Complex. There is some peat,
clay, salt, and sand and gravel extracted from the area. A large number of
major industries and numerous combined sewer overflows discharge wastewater
into the surface waters of this Complex. The Rouge River drains much of metro-
poliaton Detroit (approximate population 3,000,000), subjecting the river
to severe human pressure.
Station Key
Station
DAM River
and
Location Station Numbers
Rouge River
a
b
c
d
e
f
g
h
i
j
k
1
m
n
Ecorse River
o
P
q
Frank and Poet Drain
r
s
Brownstown/Marsh Creek
t
u
41401
4140101
4140102
4140103
4140104
4140105
4140106
4140107
4140108
4140109
4140110
4140111
4140112
4140113
4140114
41402
4140201
4140202
4140203
41403
4140301
4140302
41404
4140401
4140402
447
-------�
Hydrologic Area 4.1.5
Huron River
LIVINGSTON
O
SCALE IN MILES
Vicinity Map-RBG 4.1
10
15
-------�
Hydrologic Area 4.1.5
Huron River
The Huron River drains an area of 220,000 hectares (543,000 acres). The
area is located in the southeast portion of Michigan's Lower Peninsula. The Huron
River has a mean annual discharge of 12.6 m^/s (445 cfs). Major tributaries to
the Huron River are Mill Creek, and the Portage River. Topography varies from
flat to rolling with relatively few wetlands. Approximately 20 percent of the
area is forested, 60 percent devoted to agriculture and 15 percent urbanized.
Bedrock is composed mostly of sandstone with some shale in the eastern portion.
The overlying material is composed principally of silt and clay in the east
with glacial till in the west. Several municipalities and industries discharge
significant amounts of treated wastewaters into the surface waters of this area.
The cities of Ann Arbor (pop.: 99,797), Ypsilanti (pop.: 29,538), and Flat
Rock (pop.: 5,643) are the major developed and industrialized regions within
this area.
Station Key
DAM Rivers
Station and
Location Station Numbers
Huron River 41501
a 4150101
b 4150102
c 4150103
d 4150104
e 4150105
f 4150106
g 4150107
h 4150108
449
-------�
CO x
H —
« t
co o
0) o
< J*
o g
go
0
450
-------�
Hydrologic Area A.1.6
Swan Creek Complex
The Swan Creek Complex encompasses an area of 74,000 hectares (182,000 acres)
in the southeast portion of Michigan's Lower Peninsula. Important streams draining
the area are; Swan Creek, Stoney Creek, and Sandy Creek, all of which are ungaged.
The topography is very flat with relatively few wetlands. Approximately 15 percent
of the area ,is forested, about 60 percent devoted to agriculture and about 10
percent urbanized. The bedrock is compossed mostly of shale. The bedrock is
covered by a combination of silt and clay. Swan Creek and Stoney Creek each have
a municipal wastewater discharge flowing into them. The cities of Woodland
Beach (pop.: 2,249) and Detroit Beach (pop.: 2,053) are the only urbanized areas
in this region.
Station Key
DAM Rivers
Station and
Location Station Numbers
Swan Creek 41601
a 4160101
b 4160102
Stoney Creek 41602
c 4160201
Sandy Creek 41603
d 4160301
451
-------�
Hydrologic Area 4.1.7
Raison River
Vicinity Map-RBG 4.1
4.1
'ri
v^
^ **"•->
is-
^- — " \\
•^ ^-
^ — ^
"?:— ~ t."
r.
I
%
^x /
tw^l \i
-, ^
:•/•'*' .''T •--" — iV- • , r 1 f'
•, "" «— . \»^_-. 1 ,.o-~ t-y ''u
u«STO>u«
0
SCALE IN MILES
10
15
452
-------�
Hydrologic Area A.1.7
Raisin River
The Raisin River covers an area of 326,000 hectares (805,000 acres). Ninety-
eight percent of this area is located in the southeast corner of Michigan's Lower
Peninsula with remaining 2 percent in the State of Ohio. The Raisin River has a
mean annual discharge of 19.5 nr's (689 cfs). Major tributaries to the Raisin River
are the Saline River, the Macon River, the South Branch of the Raisin River, and
Black Creek. The topography is generally flat with relatively few wetlands.
Approximately 20 percent of the area is forested, about 60 percent devoted to
agriculture, and about 15 percent urbanized. The principle bedrock composition
is dolomite in the east, shale in the central regions, and sandstone in the west.
The overlying material principly consists of silt and clay, with glacial till in
some areas. A number of municipalities and industries use the areas surface
waters for waste assimilation. The cities of Monroe (pop.: 23,894), Adrian
(pop.: 20,382), and Tecumseh (pop.: 7,120) represent the major population centers
within the area.
Station Key
Station
Location
River Raisin
a
b
c
d
e
f
g
h
i
Otter Creek
j
k
Yetter Drain/Bay
1
Little Lake Creek
m
Halfway Creek
n
o
DAM Rivers
and
Station Numbers
41701
4170101
4170102
4170103
4170104
4170105
4170106
4170107
4170108
4170109
41703
4170301
4170302
Creek 41705
4170501
41706
4170601
41707
4170701
4170702
453
-------�
Figure 20
RIVER BASIN GROUP 4.2
LAKE ERIE
VICINITY MAP
SCALE 'N Mlj.es
100
487
SCALE IN MILES
0 5 10 15 JO
-------�
cs
Q) -
re
O5 ro
5 S
S o
CO
UJ
Z
UJ
_j
<
O
CO
488
-------�
Hydrologic Area 4.2.1
Ottawa River (Ten Mile Creek)
The Ottawa River drains an area of 44,000 hectares (109,000 acres). Seventy
percent of the area is located in north central Ohio with the remaining 30 percent
in Michigan. The Ottawa River is ungaged. The major tributary to the Ottawa River
is Ten Mile Creek. Topography is flat with few wetlands. Approximately 5 percent
of the area is forested, 10 percent urbanized, and 70 percent devoted to agriculture.
The bedrock is composed mostly of dolomite. The overlying material is predominantly
silt and clay. Economy is based on manufacturing and agriculture. The Ottawa River
flows through highly developed industrialized sections of Toledo (pop.: 383,818) and
Sylvania (pop.: 12,031).
Station Key
DAM Rivers
Station and
location Station Numbers
Ottawa River 42101
a 4210101
b 4210102
c 4210103
d 4210104
e 4210105
f 4210106
489
-------�
Hydrologic Area 4.2.2
Maumee River
DEFIANCE J Napoleon
0 5
490
VICINITY MAP-RBG4.2
-------�
Hydrologic Area 4.2.2
Maumee River
The Maumee River, the largest tributary to the Great Lakes, drains an area
of approximately 1,711,000 hectares (A, 229,000 acres). Seventy-three and six
tenths percent of the area is located in northwest Ohio, with 19.4 percent in adjoining
Indiana and the remaining 7 percent in Michigan. The Maumee River has a mean annual
discharge of 134.7 m s (4,756 cfs). The lower reaches of the Maumee are subject
to esturine effects. The major tributaries to the Maumee are the St. Joseph River,
the Auglaize River, the St. Mary's River, and the Tiffin River. Much of the land is
nearly level or gently sloping. The fine textured glacial tills and lakelaid
clays have poor natural drainage. The soils have slow permeability, and are
subject to intensive row cropping. A glacial depression, formerly known as the
Great Black Swamp, covers a large portion of the basin. Because the region is
poorly drained, drainage ditches and subsurface tile drains have been constructed
to remove water from much of the agricultural land. Approximately 85 percent
of the area within the hydrologic boundaries is used for agricultural purposes.
Eleven percent of the area is found in urbanized areas with nearly 70 percent of the
population located in the three major areas of Fort Wayne, Indiana, Lima, Ohio,
and Toledo, Ohio. Another 8 percent of the area can be classified as forest and
woodland. The bedrock consists mostly of sandstone in the northwest section of the
area and dolomite in the southeast. Bands of shale are interspersed throughout the
area. The economy is based on manufacturing and agriculture with some extraction
of natural resources such as sand, gravel, limestone, dolomite and clay.
The heavy sediment load and its associated contaminants of the Maumee River is
a major source of pollution to Maumee Bay and Lake Erie in general. The surface
waters of the area receive a heavy point source load of wastewater. More than
150 municipalities, industries, and private wastewater sources use these surface
waters for waste assimiliation. Important municipal and industrial centers in the
area are the cities of Fort Wayne, Indiana (pop.: 177,671), Toledo, Ohio (pop.:
383,818), Lima, Ohio (pop.: 53,734), Findlay, Ohio (pop.: 35,800), Van Wert,
Ohio (pop.: 29,194), Defiance, Ohio (pop.: 16,281), and Maumee, Ohio (pop.: 15,937).
Station Key
DAM Rivers °AM Rivers
Station and Station and
Location Station Numbers Location Station Number
Swan Creek 42201 * 4220207
a 4220101 n 4220208
b 4220102 o 4220209
c 4220103 P 4220210
d 4220104 q 4220211
e 4220105 r 4220212
f 4220106 s 4220213
Maumee River 42202 t 4220214
g 4220201 u 4220215
h 4220202 v 4220216
i 4220203 w 4220217
j 4220204 x 4220218
k 4220205
1 4220206
491
-------�
Hydrologic Area 4.2.3
Toussaint-Portage Complex
£j Kellys Island
Sandusky Bay
Bowling Gree
Toledo
OTTAWA?
SANDUSKY
SENECA
Vicinity Map-RBG 4.2
SCALE IN MILES
492
5 10 15 20 25
-------�
Hydrologic Area 4.2.3
Toussaint-Portage Complex
The Toussaint-Portage Complex covers 266,000 hectares (656,000 acres). The area
is located in northwestern Ohio. The major rivers in the area are the Portage River,
which has a mean annual discharge of 8.6 m^/s (304 cfs) and Toussaint Creek (ungaged).
A number of other small streams drain the remaining area. The Complex is flat with fe
wetlands although the area is highly underdrained and ditched. Less than 10
percent of the area is forested, approximately 80 percent is devoted to agriculture,
and about 10 percent is urbanized. The bedrock is composed primarily of dolomite.
The overlying material is predominantly a mixture of silt and clay near the shore and
glacial till throughout the remainder of the complex. Streams in this area are
usually high in dissolved solids. The cities of Bowling Green (pop.: 21,760),
Fostoria (pop.: 16,037), and Port Clinton (pop.: 7,202) are the largest population
centers in the area and all contribute waste to the surface waters.
Station Key
Station
Location
DAM River
and
Station Numbers
Toussaint Creek
a
Portage River
b
c
d
e
f
g
h
i
Muddy Creek
j
42305
4230501
42307
4230701
4230702
4230703
4230704
4230705
4230706
4230707
4230708
42309
4230901
493
-------�
Hydrologic Area 4.2 4
Sandusky River
SENECA
CRAWFORD
SCALE IN MILES
5 10 15 20 25
Vicinity Map-RBG 4 2 494
-------�
Hydrologic Area 4.2.4
Sandusky River
The Sandusky River drains an area of 397,000 hectares (980,000 acres). The
area is located in north central Ohio. The Sandusky River has a mean annual dis-
charge of 8.6 m^/s (304 cfs). Major tributaries to the Sandusy River are Tymochtee
Creek and Honey Creek. The area is generally very flat and poorly drained. An
extensive network of surface ditches and underdrains exists in the area. Approximately
80 percent of the area is used in agriculture, about 10 percent urbanized, and about
5 percent forested. The bedrock is principly composed of shale, dolomite and some sand-
stone. The overlying material consists of silt and clay in the northern portion and
glacial till in the south. The Sandusky River tends to be high in dissolved solids
which leach from the caleureous bedrock. The cities of Tiffin (pop.: 21,596),
Freement (pop.: 18,490), and Bucyrus (pop.: 13,111) are the major population and
industrial centers in the Basin.
Station Key
DAM River
Station and
Location Station Numbers
Sandusky River 42401
a 4240101
b 4240102
c 4240103
d 4240104
e 4240105
f 4240106
g 4240107
Green Creek 42402
h 4240201
i 4240202
495
-------�
Hydrologic Area 4.2.5
Huron-Vermilion Complex
LAKE ERIE
SanausK/ Bay
\
Sandusky
O WiJIard
HURON
SCALE IN MILES
Vicinity Map-RBG 4.2
5 10 15 20 25
A96
-------�
Hydrologic Area 4.2.5
Huron-Vermilion Complex
The Huron-Vermilion Complex compasses and area of 267,000 hectares (661,000
acres) in north central Ohio. The major rivers in the complex and their mean annual
discharges are the Huron River, 8.2 m3/s (290 cfs), and the Vermilion River 6.6 m^'s
(233 cfs). A number of other small streams also drain this complex. This area had a ro]
ing topography with relatively few wetlands. Approximately 80 to 90 percent of this
area is devoted to agriculture, about 5 percent urbanized, and about 5 percent
forested. Bedrock is composed predominantly of sandstone and shale. Overlying
material consists of glacial till with silt and clay near the shore. Some sand,
gravel, and stone are extracted from the area. Large population centers, such
as Sandusky (pop.: 32,674), Norwalk (pop.: 13,386), and Bellevue (pop.: 8,604)
utilize the Huron River for wastewater assimilation. The Vermilion River receives
much less human pressure since its drainage area is relatively sparsely populated,
the largest city being New London (pop.: 2,336).
Station Key
Station
Location
Huron River
a
b
c
d
e
f
g
Vermilion River
h
i
j
k
DAM River
and
S t a t io n Numb e r s
42508
4250801
4250802
4250803
4250804
4250805
4250806
4250807
42511
4251101
4251102
4251103
4251104
497
-------�
Figure 21
RIVER BASIN GROUP 4.3
537
SCALE IN MILES
10 15
-------�
Hydrologic Area 4.3.1
Black-Rocky Complex
CUYAHOGA
SCALE IN MILES
10
Vicinity Map-RBG 4.3
538
-------�
Hydrologic Area 4.3.1
Black-Rocky Complex
The Black-Rocky Complex encompasses an area of 230,000 hectares (568,000
acres). This area is located in north central Ohio. The major tributaries and
their mean annual discharges are the Black River 8.8 m^'s (311 cfs) and the Rocky
River 7.3 m^/s (258 cfs). A number of other small streams drain the remaining
portions of this area. The topography is rolling with relatively few wetlands.
Approximately 40 percent of the area is devoted to agriculture, about 15 percent
urbanized, and 15 percent forested. The bedrock is composed predominantly of
shale near the lake shore and sandstone throughout the remaining area. The
bedrock is covered mostly by a silt and clay mixture near the shoreline and
glacial till throughout the remaining portions. The economy is heavily based
on manufacturing with some agriculture and mineral extraction. Industrial waste,
treated municipal waste, and combined sewer overflows heavily influence water
quality, throughout the area. The cities of Lorain (pop.: 78,185), and
Elyria (pop.: 53,427) are the largest population centers on the Black River.
The city of Medina (pop.: 10,913) and part of Cleveland (pop.: 750,903)
utilize the Ricky River for wastewater assimilation.
Station Key
Station
Location
Beaver Creek
a
b
c
d
Black River
e
f
g
h
i
j
k
1
m
n
o
P
q
r
s
t
u
V
w
X
y
z
DAM River
and
Station Number j
43102
4310201
4310202
4310203
4310204
43104
4310401
4310402
4310403
4310404
4310405
4310406
4310407
4310408
4310409
4310410
4310411
4310412
4310413
4310414
4310415
4310416
4310417
4310418
4310419
4310420
4310421
4310422
Station
Station
Location
aa
bb
cc
dd
ee
ff
gg
hh
ii
jj
kk
11
mm
nn
00
PP
qq
rr
ss
tt
uu
w
Rocky River
ww
XX
yy
zz
Key
DAM River
and
Station Numbers
4310423
4310424
4310425
4310426
4310427
4310428
4310429
4310430
4310431
4310432
4310433
4310434
4310435
4310436
4310437
4310438
4310439
4310440
4310441
4310442
4310443
4310444
43108
4310801
4310802
4310803
4310804
539
-------�
Hydrologic Area 4.3.2
Cuyahoga River
Vicinity Map-RBG 4.3
540
SCALE IN MILES
10
15
-------�
Hydrologic Area 4.3.2
Cuyahoga River
The Cuyahoga River drains an area of 234,000 hectares (578,000 acres) in
northeastern Ohio. The Cuyahoga River has a mean annual discharge of 21.6 m^/s
(763 cfs). The topography varies from rolling to steep hills with relatively few
wetlands. Approximately 40 percent of the area is devoted to agriculture, 20
percent forested, and 20 percent urbanized. The bedrock is composed predominantly
of shale near the shoreline and sandstone throughout the rest of the area. The
overlying material is composed of silt and clay near the shore with an area of sand and
gravel in the southern portion, and glacial till throughout the remaining regions
The economy is based mainly on manufacturing. Large amounts of municipal and
industrial wastewater enter the surface waters from metropolitan Cleveland (pop.:
750,903) and Akron (pop.: 275,425), as well as the cities of Cuyahoga Falls
(pop.: 49,678), and Kent (pop.: 28,103). Steel and chemical industries are
prevelent along the Cuyahoga River.
Station Key
DAM River
Station and
Location Station Numbers
Cuyahoga River 43201
a 4320101
b 4320102
c 4320103
d 4320104
e 4320105
f 4320106
g 4320107
h 4320108
i 4320109
j 4320110
k 4320111
1 4320112
m 4320113
n 4320114
o 4320115
p 4320116
q 4320117
r 4320118
s 4320119
t 4320120
u 4320121
v 4320122
w 4320123
x 4320124
y 4320125
z 4320126
541
-------�
Hydrologic Area 4.3.3
Chagrin River
542
SCALE IN MILES
10
15
Vicinity Map-RBG 4.3
-------�
Hydrologic Area 4.3.3
Chagrin Complex
The Chagrin Complex covers 77,000 hectares (189,000 acres) in northwestern
Ohio. The major tributary draining the area is the Chagrin River, which has a mean
annual discharge of 9.0 nr's (318 cfs). Approximately 5 other small streams drain
the remaining areas of this complex. The area has a steep rolling topography
with relatively few wetlands. Approximately 40 percent of the area is agriculturalized,
about 25 percent forested, and about 20 percent urbanized. The bedrock in the northern
portion of the area is predominantly composed of shale and to a lesser extent, sand-
stone. The overlying material consists of mostly silt and clay near the shore .with
glacial till throughout the rest of the region. The economy is based upon manufacturing
with some agriculture and mineral extraction. The area is subject to heavy human
pressure from the cities of East Cleveland (pop.: 39,600), Willoughby (pop.: 18,634),
Chagrin Falls (pop.: 4,848) and portions of Cleveland (pop.: 750,903). Sheet
erosion also causes a serious water quality problem.
Station Key
Station
Location
Doan Brook
a
Euclid Creek
b
Chagrin River
c
d
e
f
g
h
DAM River
and
Station Numbers
43302
4330201
43305
4330501
43306
4330601
4330602
4330603
4330604
4330605
4330606
543
-------�
Hydrologic Area 4.3.4
Grand River
Fairport Harbo
Vicinity Map-RBG 4.3
544
SCALE IN MILES
10
15
-------�
Hydrologic Area 4.3.4
Grand River
The Grand River drains an area of 212,000 hectares (525,000 acres) in north-
eastern Ohio. The Grand River has a mean annual discharge of 18.7 m^'s (660 cfs).
The major tributary to the Grand River is Mill Creek. The topography of the area
is rolling with relatively few wetlands. Approximately 40 percent of the area is
agriculturalized, about 30 percent is forested, and about 20 percent is urbanized.
Bedrock is composed mostly of shale with some sandstone in the southern portion.
The bedrock is covered by silt and clay near the shore and glacial till over the rest
of the area. The economy is based heavily on manufacturing. The city of
Painesville (pop.: 16,536) discharges a heavy industrial and minicipal wastewater
load to the Grand River.
Station Key
Station
Location
Grand River
a
b
c
d
e
f
g
h
i
3
DAM River
and
Station Numbers
43402
4340201
4340202
4340203
4340204
4340205
4340206
4340207
4340208
4340209
4340210
545
-------�
Hydrologic Area 4.3.5
Ashtabula-Conneaut Complex
SCALE IN MILES
10
15
•$
£K*'~ Lr
*<.-
^-s -t , , «
"C^?" ' '
«^x y. , ^
\ •'•r*1'' ^
t;
--"
5A6
Vicinity Map-RBG 4.3
-------�
Hydrologic Area A.3.5
Ashtabula-Conneaut Complex
The Ashtabula-Conneaut Complex encompasses an area of 90,000 hectares (220,000
acres). Fifty-four percent of the area is located in northeastern Ohio with the
remaining A6 percent in bordering Pennsylvania. The major tributaries in the area
and their mean annual discharges are the Ashtabula River A.I m^'s (1A5 cfs) and
the Conneaut Creek 7.2 m^/s (25A cfs). The topography varies from flat to rolling
vith few wetlands. The Ashtabula basin is characterized by high runoff.
Approximately 30 percent of the area is forested, about AO percent is devoted to
agriculture, and about 15 percent urbanized. The bedrock is composed mostly of dolomite.
The bedrock is covered by a combination of silt and clay near the shore areas, and glacial
till throughout the remaining area. The economy is based heavily upon manufacturing.
The lower reaches of the Ashtabula River are affected by municipal and industrial
wastewater discharges from the city of Ashtabula (pop.: 2A.313). The Ashtabula
has a relatively small drainage basin and a relatively low flow, resulting in a low
dillution potential. During periods of low natural flow, efflent from the
Ashtabula industrial complex dominates the rivers discharge.
Station Key
Station
Location
Cowles Creek
a
Red Brook
b
c
Ashtebula River
d
e
f
g
h
i
j
k
1
m
n
o
Conneaut Creek
P
q
r
s
t
u
DAM River
and
Station Numbers
A3503
A350301
A3505
A350501
A350502
A3506
A350601
A350602
A350603
A35060A
A350605
A350606
A350607
A350608
A350609
A350610
A350611
4350612
A3508
A350801
A350802
A350803
A350804
A350805
A350806
5A7
-------�
Figure 22
RIVER BASIN GROUP 4.4
\
UKE ONTARIO
NEW YORK CATTARAUGUS
586
SCALE IN MILES
0 5 10 15 20
-------�
CD
a
E
CD
cn'~
0 £
JZ
U
£ I
LJJ
CD
QC
a
CD
c
o
588
-------�
Hydrologic Area 4.A.I
Erie-Chautauqua Complex
The Erie-Chautauqua Complex covers 169,000 hectares (418,000 acres). Fifty-three
percent of the area is located in northern Pennsylvania, with the remaining 47
percent in New York. There are a number of small streams draining the area but no
major rivers. The area has a rolling relief with relatively few wetlands.
Approximately 45 percent of the complex is forested, about 35 percent is agriculturalizec
and about 10 percent is urbanized. The bedrock is composed mostly of shale.
Overlying material consists of glacial till with some areas of silt and clay. The
economy is based heavily upon manufacturing. Despite the small size of the
tributaries in this area, they contribute a significant amount of wastewater to
Lake Erie. The cities of Erie, Pennsylvania (pop.: 129,231), Fredonia, New York
(pop.: 10,326), and Dunkirk, New York (pop.: 16,855), are the major population
centers in this area.
Station Key
Station
Location
Turkey Creek
a
Elk Creek
b
c
d
Trout Run
e
Walnut Creek
f
Cascade Creek
g
Sixmile Creek
h
Sixteen Mile Creek
i
Twentymile Creek
j
Freelings Creek
k
DAM River
and
S t ation Number s
44101
4410101
44104
4410401
4410402
4410403
44105
4410509
44106
4410608
44107
4M0706
44111
4411101
44115
4411506
44116
4411601
44119
4411901
Station
Station
Location
Chautauqua Creek
1
m
n
o
P
Corell Creek
q
r
Key
DAM River
and
Station Numbers
44120
4412001
4412002
4412003
4412004
4412005
44126
4412601
4412602
Little Canadaway Creek 44128
s
t
u
Canadaway Creek
V
w
X
Crooked Brook
V
J
Z
Beaver Creek
aa
bb
Walnut-Silver Creek
cc
4412801
4412802
4412803
44130
4413001
4413002
4413003
44131
4413101
4413102
44134
4413401
4413402
44136
4413601
589
-------�
Hydrologic Area 4.4.2
Cattaraugus River
Springville.
ERIE
Vicinity Map-RBG 4.4
590
SCALE IN MILES
0 5 10 15 20
-------�
Hydrologic Area A.4.2
Cattaraugus Creek
The Cattaraugus Creek drains an area of 144,000 hectares (355,000 acres) in the
southwest portion of New York. Cattaraugus Creek has a mean annual discharge of
20.2 m s (713 cfs). The topography of the area is quite hilly with relatively few
wetlands. Approximately 50 percent of the area is forested, about 35 percent if
devoted to agriculture, and about 10 percent is urbanized. Bedrock consists mostly of
shale. The overlying material is predominantly silt and clay near the shore,
glacial till in the more southern portions, and sand and gravel in the east. The only
important wastewater point sources are discharged near the village of Gowanda
(pop.: 3,110), and the village of Arcade (pop.: 3,048). Along with the city of
Springville (pop.: 4,350), these villages are the most highly populated zones within
this area.
Station Key
DAM River
Station and
Location Station Numbers
Cattaraugus Creek 44201
a 4420101
b 4420102
c 4420103
d 4420104
e 4420105
f 4420106
591
-------�
APPtNDIX 1
LAKE ONTARIO
-------�
LAKE ONTARIO BASIN, 5
River Basin Groups 5.1 through 5.3
628
SCALE IN MILES
0 10 20 30 «0 50
-------�
Hydrologic Area 4.4.3
Tonawanda Complex
SCALE IN MILES
Vicinity Map-RBG 4.4
10 15 20
-------�
Hydrologic Area 4.4.3
Tonawanda Complex
The Tonawanda Complex covers 371,000 hectares (917,000 acres) in the western
region of New York State. The major tributaries and their mean annual discharges are
Eighteen Mile Creek (ungaged), the Buffalo River 11.6 m-*'s (408 cfs), and Tonawanda
Creek 7.5 m^/s (265 cfs). Major tributaries to the Buffalo River are the Cazenovia
Creek and the Buffalo Creek. The topography of the area is rolling with relatively
few wetlands. Approximately 30 percent of the area is forested, about 30 percent is
devoted to agriculture, and roughly 20 percent is urbanized, including the
metropolitan Buffalo area. The bedrock is composed mostly of shale. The overlying
material consists principly of glacial till in the eastern portions and silt and
clay in the west. The economy is based almost entirely upon manufacturing. Eighteen
Mile Creek receives wastewater discharges from the Hamburg (pop.: 10,215) area. The
Buffalo River is subject to heavy industrial and municipal wastewater loadings from
the cities of Buffalo (pop.: 462,768), Lockport (pop.: 25,399), Depew (pop.: 22,158), an<
Lancaster (pop.: 13,365). Tonawanda Creek receives industrial and municipal wastewater
streams from the cities of North Tonawanda (pop.: 36,012) and Tonawanda (pop.: 21,898).
Station
Station
Location
Muddy Creek
a
Key
DAM River
and
Station Numbers
44301
4430101
Delaware Creek 44302
b
Big Sister
Creek
c
Eighteen Mile
Creek
d
Smoke Creek
e
f
Buffalo River
g
h
i
j
k
1
m
n
4430201
44303
4430301
44305
4430501
44306
4430601
4430602
44307
4430701
4430702
4430703
4430704
4430705
4430706
4430707
4430708
Station Key
Station
Location
o
P
q
r
s
t
u
V
w
X
y
z
aa
bb
cc
dd
ee
Tonawanda
ff
gg
hh
DAM River
and
Station Numbers
4430709
4430710
4430711
4430712
4430713
4430714
4430715
4430716
4430717
4430718
4430719
4430720
4430721
4430722
4430723
4430724
4430725
Creek 44308
4430801
4430802
4430803
593
-------�
Figure 24
RIVER BASIN GROUP 5.1
LAKE
ONTARIO
\
NEWYOpK
PENNSYLVANIA
631
-------�
X
«- jj?
T- a
m E
o
rp O
£ LO
< c
re
632
-------�
Hydrologic Area 5.1.1
Niagara-Orleans Complex
The Niagara-Orleans Complex covers 269,000 hectares (664,000 acres) in north-
western New York. Major tributaries drainaing this area are Johnson Creek and
Oak Orchard Creek, both of which are ungauged. Many additional small streams drain
the remaining portions of this area. The New York State barge canal also flows
through this complex. The topography is relatively flat. Approximately 50 percent
of this area is used for agricultural purposes, about 35 percent is forested, and
roughly 10 percent urbanized. The bedrock is composed mostly of shale and
dolomite. The overlying material is mainly a mixture of silt and clay with some
glacial till. The economy is based heavily upon manufacturing, with some
agriculture. The cities of Medena (pop.: 6,415), Albion (pop.: 5,112), Brock-
port (pop.: 7,878), Niagara Falls (pop.: 85,615), and Rochester (only a portion
of the city falls in the watershed pop.: 296,233) exert the greatest human
pressure on the area. The cities of Niagara Falls and Rochester are heavily
industrialized and utilize the surface waters for large amounts of waste
assimilation. Station Key
Station
Location and
Cuyuga Creek
a
b
Eighteen Mile Creek
c
d
e
f
Golden Hill Creek
g
h
Johnson Creek
i
j
k
Oak Orchard Creek
1
m
n
DAM River
Station Numbers
51101
5110101
5110102
51107
5110701
5110702
5110703
5110704
51110
5111001
5111002
51113
5111301
5111302
5111303
51114
5111401
5111402
5111403
Station
Location and
Sandy Creek
o
P
West Creek
q
r
Salmon Creek
s
t
Black Creek
u
V
w
Round Pond Creek
X
Slater Creek
y
z
DAM River
Station Numbers
51116
5111601
5111602
51119
5111901
5111902
51120
5112001
5112002
51122
5112201
5112202
5112203
51124
5112401
51125
5112501
5112502
633
-------�
Hydrologic Area 5.1.2
Genesee River
LAKE
ONTARIO^
Vicinity Map-RBG 5.1
-------�
Hydrologlc Area 5.1.2
Genesee River Complex
The Genesee River drains an area of 642,000 hectares (1,586,000 acres).
Ninety-six percent of the area is located in western New York with the remaining
four percent in Pennsylvania. The Genesee River has a mean annual discharge
of 76.8 m3/s (2,712 cfs). Major tributaries to the Genesee River are the
Canaseraga Creek, the Otatka Creek, the Black Creek, and the Honeoye Creek.
A barge canal crosses the Genesee River south of Rochester. Guard Locks, located
on either side of the river crossing, permit regulation of canal water diverted
from Lake Erie. The River has a low slope and many meanders in the lower reaches
which results in generally sluggish flow and estuarine effects during low
flow conditions. The southern region is characterized by steep rugged terrain,
changing to a gently rolling look in the north. There are few wetlands.
Approximately 30 to 40 percent of the area is forested, roughly 50 percent is
devoted to agriculture, and about 10 percent is urbanized. Bedrock is composed
mostly of dolomite and shale. The overlying material is mostly glacial till
with some silt and clay. Severe soil erosion occurs in the upper reaches of
the watershed. The economy is based upon manufacturing and agriculture in the
northern areas with agriculture and forestry being the dominate influence in
the south. Approximately four municipalities and three industries induce the
greatest pressure upon the river. Discharge from the barge canal also seriously
degrades water quality in the river. The city of Rochester (pop.: 296,233) at
the mouth of the Genesee River is the most highly industrialized region within
this hydrologic area.
Station Key
Station
Location
Genesee River
a
b
c
d
e
f
g
h
i
j
k
1
m
n
DAM River
and Station Numbers
51201
5120101
5120102
5120103
5120104
5120105
5120106
5120107
5120108
5120109
5120110
5120111
5120112
5120113
5120114
Station
Location and
Genesee River
o
P
q
r
s
Irondequoit Creek
t
u
V
w
Mill Creek
X
DAM River
Station Numbers
5120115
5120116
5120117
5120118
5120119
51202
5120201
5120202
5120203
5120204
51203
5120301
635
-------�
watkins Gien . ,
VsCHUYLES/ ,
Figure 25
RIVER BASIN GROUP 5.2
>4 iW ' "" \V_ K
'•"/7/r -_ j-O",'^- ^
-^'("PT^ J—^
i -( ^. V /\
1-0"^ ^ _^< T^
~ -.'=-
/
't*»
66A
SCALE IN MILES
I, • "
0 5 10 15 20
-------�
Hydrologic Area 52 1
Wayne-Cayuga Complex
SCALE IN MILES
10 15 20
Vicinity Map-RBG 5.2
666
-------�
Hydrologic Area 5.2.1
Wayne-Cayuga Complex
The Wayne-Cayuga Complex encompasses an area of 177,000 hectares
(437,000 acres) in north central New York. The major tributary in the area is
Sterling Creek, which has a mean annual discharge of 1.7 m/s (60 cfs). There
are a number of smaller streams that drain the remainder of the complex.
The area has a rolling topography with relatively few wetlands. Approximately
45 percent of the complex is forested, another 45 percent approximately is agricul-
turized and about 5 percent is urbanized. The bedrock is composed pre-
dominately of dolomite. The overlying material is largely silt and clay.
The cities of Sterling (pop.: 2,589) and Sodus (pop.: 1,813) are the largest
population centers in the area.
Station Key
Station
Location
Bear Creek
a
b
c
d
Salmon Creek I
e
f
Salmon Creek II
g
Red Creek
h
i
j
Sterling
k
1
m
n
Nine Mile Creek
o
P
DAM River
and S t at ion Numbe r s
52103
5210301
5210302
5210303
5210304
52104
5210401
5210402
52107
5210701
52113
5211301
5211302
5211303
52115
5211501
5211502
5211503
5211504
52116
5211601
5211602
667
-------�
668
-------�
Hydrologic Area 5.2.2
Oswego River
The Oswego River drains an area of 1,316,000 hectares (3,252,000 acres) in
north ,central New York. The Oswego River has a mean annual discharge of
183 m /s (6,462 cfs). This area drains the bulk of New York's Finger Lakes
Region. A significant feature of this complex is the New York State Barge
Canal which completely transects this complex in an east-west direction. The
topography varies from rolling in the northern portions to mountainous in the
south. There are some wetlands in the eastern region of this area.
Approximately 30 percent of the area is forested, about 40 percent is
agriculturized, about 5 percent is urbanized, and nearly 5 percent of the complex's
area is covered by lakes. The large number of lakes has a modifying effect on
runoff. The bedrock is composed largely of dolomite in the northern sections and
sahle in the south. The cover material is composed mostly of glacial till with
some areas of sand and gravel. The economy is based heavily upon manufacturing
with some agriculture and mineral extraction (limestone and dolomite, salt,
clay, and sahle). The Oswego River receives heavy organic loadings from three
municipalities and six major industries scattered throughout the area. Additional
treated wastewater loads are introduced by the New York State Barge Canal, and
over 60 industries scattered throughout the metropolitan Syracuse area. The
cities of Syracuse (pop.: 197,208), Oswego (pop.: 23,844), Auburn (pop.: 34,599),
Ithaca (pop.: 26,226), and Fulton (pop.: 23,844)., are the most populated and
industrilized centers in this area.
Station DAM River
Location and Station Numbers
Oswego River 52201
a 5220101
b 5220102
c 5220103
d 5220104
e 5220105
669
-------�
Hydrologic Area 5.2.3
Salmon Complex
SCALE IN MILES
0 5 10 15 20
Vicinity Map-RBG 5.2 670
-------�
Hydrologic Area 5.2.3
Salmon Complex
The Salmon Complex encompasses an area of 273,000 hectares (674,000 acres) in
north central New York on the eastern shore of Lake Onatrio. The major.,tributaries
in the area are Sandy Creek, which has a mean annual discharge of 6.9m /s (244
cfs), the Salmon River (ungaged), and the Little Salmon River (ungaged). Many
additional small streams drain portions of this area. The topography varies from
rolling to flat. Wetlands are significant. Approximately 50 percent of the
area is forested, about 40 percent is agriculturized, and roughly 5 percent is
urbanized. Bedrock is composed mostly of shale. The overlying material consists
of silt and clay near the lake shore and glacial till throughout the remaining
area. The major population center in the area is the city of Pulaski
(pop.: 2,480). There are no important wastewater discharges in the area.
Station
Location
Station Key
DAM River
and Station Numbers
Catfish Creek
a
b
Butterfly Creek
c
Little Salmon River
d
e
f
o
1,
i
Grindstone Creek
j
52304
5230401
5230402
52305
5230501
52306
5230601
5230602
5230603
5230604
5230605
5230606
52309
5230901
Station
Location and
Salmon River
k
1
m
n
Little Sandy Creek
o
P
q
r
South Sandy Creek
s
Sandy Creek
t
u
V
Stony Creek
w
DAM River
Station Numbers
52310
5231001
5231002
5231003
5231004
52312
5231201
5231202
5231203
5231204
52314
5231401
52316
5231601
5231602
5231603
52319
5231901
671
-------�
Figure 26
RIVER BASIN GROUP 5.3
LAKE
ONTARIO
VICINITY tup
692
SCALE IN MILES
0 5 10 15 20
5.3
-------�
CO
If)
cu
0>
QJ -Z.
II
0)
UJ
J
i
z
UJ
<
O
(/)
O
CM
in
IT)
LJ O
694
-------�
Hydrologic Area 5.3.1
Black River
The Black River drains an area of 521,000 hectares (1,289,000 acres) in
northcentral New York. The Black River has a mean annual discharge of 110.0 m /s
(3,884 cfs). Major tributaries to the Black River are the Moose River, the Beaver
River, and the Deer River. The Black River and its tributaries have many natural
falls, which are used extensively for power generation. The topography varies
from rolling near the lake shore to mountainous in the eastern states. Annual
runoff in the Basin is high. Some of the 30 hydroelectric developments in the
Basin cause alteration in the flow of the river system. Approximately 60 to 70
percent of the area is forested, 20 to 30 percent is agriculturized, and about
5 percent is urbanized. The bedrock consists predominately of igneous and meta-
morphic rock, although significant shale is found in the western portions. The
overlying material predominantly consists of a silt and clay mixture near the lake
shore areas and glacial till throughout the remainder of the region. Numerous
paper and pulp mills use the Black River for waste assimilation. The cities of
Watertown (pop.: 30,787), and Carthage (pop.: 3,889) are the most populated and
industrialized centers within the area.
Station Key
Station DAM River
Location and Station Numbers
Black River 53101
a 5310101
b 5310102
c 5310103
d 5310104
e 5310105
f 5110106
g 5310107
h 5310108
i 5310109
j 5310110
695
-------�
UJ
-I
I
Z
UJ
tn
696
-------�
Hydrologic Area 5.3.2
Perch Complex
The Perch Complex covers 126,000 hectares (311,000 acres) in north-central
New York. The major tributaries draining this area are the Perch River, Chaumout
River, and Chippawa Creek, all of which are ungauged. The area is generally flat
with few wetlands. Approximately 60% of the land is forested, 40% is devoted to
agriculture, with only a small fraction of the area urbanized. The sandstone and
carbonate bedrock is overlain with silts and clays of a former lake bed. The local
economy is based largely on agriculture, forestry, and food-processing activities.
Wastewater is discharged by several dairy plants, paper mills and small munici-
palities. The largest population centers in this sparsely populated area are the
villages of Clayton (Pop: 1,970) and Dexter (Pop: 1,061).
Station Key
Station DAM River
Location and Station Numbers
Chippewa Creek 53210
a 5321001
b 5321002
c 5321003
697
-------�
Hydrologic Area 5.3.3
Oswegatchie River
JEFFERSON
SCALE IN MILES
0 5 10 15 20
Vicinity Map-RBG 5.3
697a
-------�
Hydrologic Area 5.3.3
Oswegatchie River
The Oswegatchie River drains 430,000 hectares (1,063,000 acres) in north-
central New York. The mean annual discharge into the St. Lawrence River is
81.4 m /s (2874 cfs). Major tributaries to the Oswegatchie are the Indian River
and the West Branch. Many natural lakes exist in the headwaters area and the river
itself has been extensively dammed for hydroelectric generation. The topography
varies from flat and rolling near the mouth to mountainous in the upper reaches.
Runoff is high but streamflow is greatly regulated by the many impoundments along
the river. Roughly 80% of the area is forested, 15% is agriculturized, and 5% is
in urban uses. Bedrock consists of igneous and metamorphic rocks in the upper
mountainous reaches with carbonates and sandstones underlying the area near the
mouth. Surface deposits in the lower reaches are mostly silt and clay lake bed
sediments, while the upper drainage area is mainly exposed bedrock with some
glacial till. The local economy is based on forestry, dairying and mining (iron,
talc, zinc, and silver). Paper mills and dairy plants contribute significantly
to tributary wastewater loads. The major population centers, Ogdensburg
(Pop.: 14,554) and Gouverneur (Pop.: 4,574) also contribute wastewater from muni-
cipal and industrial sources.
Station Key
Station DAM River
Location And Station Numbers
Oswegatchie River 53301
a 5330101
b 5330102
c 5330103
d 5330104
e 5330105
697b
-------�
Hydrologic Area 5.3.4
Grass-Raquetle-St. Regis Complex
SCALE IN MILES
0 5 10 15 20
Vicinity Map-RBG 5.3
-------�
Hydrologic Area 5.3.4
Grass-Raquette-St. Regis Complex
The Grass-Raquette-St. Regis complex covers an area of 823,000 hectares
(2,033,600 acres) in northcentral New York. The major tributaries and their mean
annual discharges are the Grass River (32.6 m /s, 1150 cfs), the Raquette River
(61.7 m /s, 2180 cfs) and the St. Regis River (39.4 m /s, 1391 cfs). The flow
of the Grass River is increased by diversion of a part of the St. Lawrence via
the Massena Power Canal at Massena. Major tributaries to the Grass River are
Harrison Creek and the Little River; to the Raquette are the Bog River and Jordan
River; and to the St. Regis are the Deer River and the East and West Branches of
the St. Regis. All three major rivers have their headwaters in the mountainous
Adirondack region and flow northerly onto the flat to rolling plain along the
St. Lawrence River. There are many natural lakes and man made impoundments in
the upper reaches; the Raquette River is especially heavily utilized for hydro-
electric generation. Many wetlands are present in the mountainous areas. Approxi-
mately 75% of the region is forested, 20% is devoted to agriculture and 5% is in
urban usage. Bedrock is composed for the largest part of crystalline rocks with
a smaller area along the St. Lawrence River underlain by sandstone and carbonates.
Surficial deposits consist of silt and clay in the lower reaches and areas of
both exposed bedrock and glacial outwash in the southern portion. The economy
is based on mining, metals production, dairying, and forestry. Aluminum production
utilizes much of the electric power generated within the region. The Grass River
receives municipal effluent from Conton (Pop.: 6,398) and Massena (Pop.: 14,042)
and industrial wastes from aluminum plants, dairy processing plants, and ore re-
fineries. The Raquette River is subject to industrial and municipal wastewater
loadings from the Potsdam (Pop.: 9,985), Norwood (Pop.: 2,098), and Tupper Lake
(Pop.: 4,854) areas. The St. Regis River receives only small amounts of municipal
effluent but receives significant discharges from paper mills and food processing
plants.
Station Key
Station DAM River
Location and Station Numbers
Grass River 53405
a 5340501
b 5340502
c 5340503
d 5340504
e 5340505
f 5340506
g 5340507
Raquette River 53406
h 5340601
i 5340602
j 5340603
k 5340604
St. Regis River 53407
1 53407G1
m 5340702
n 5340703
o 5340704
p 5340705
697d
-------�
APPENDIX 1
SAGINAW BAY
-------�
Figure 17
RIVER BASIN GROUP 3.2
LAKE HURON
Harbor Boch
*Owosso«s,>.artJ creek M^j
402
SCALE IN MILES
5 10 15 20
-------�
Hydrologic Are? 3.1.6
Rifle-Au Gres Complex
Tawas
Map-RBG 3.1
SCALE IN MILES
10 15 20
370
-------�
Hydrologic Area 3.1.6
Rifle-Au Gres Complex
The Rifle-Au Gres Complex encompasses an area of 287,000 hectares (709,000
acres). This complex is located in the northeastern portion of Michigan's Lower
Peninsula. The important rivers in the area and their mean annual discharges are
the Au Gres (2.8 m-*/s, 99 cfs), and the Rifle (8.7 m3/s, 307 cfs). The Complex is
generally flat and wetlands are relatively common. Approximately 70 to 80 percent
of the area is forested (including portions of the Huron National Forest), about
15 percent devoted to agriculture, and only a few percent is urbanized. The bed-
rock is composed mostly of limestone. The bedrock is covered by silt and clay
along the lakeshore and glacial till throughout the rest of the area. Material
such as sand and gravel, oil, gypsum, limestone, and dolomite are extracted from
the area. The cities of East Tawas (Pop.: 2,372) and Tawas (Pop.: 1,666) represent
the two largest urbanized areas in this complex.
Station Key
Station
Location
DAM River and
Station Numbers
Tawas River
a
b
c
Whitney Drain
d
Au Gres River
e
f
g
h
i
Rifle River
j
k
1
m
Pine River
n
o
31601
3160101
3160102
3160103
31602
3160201
31603
3160301
3160302
3160303
3160304
3160305
31605
3160501
3160502
3160503
3160504
31606
3160601
3160602
371
-------�
Hydrologic Area 3.2.1
Kawkawlin Complex
i \*--. - ^
Vicinity Map-RBG 3 2
SCALE IN MILES
10 15 20
404
-------�
Hydrologic Area 3.2.1
Kawkawlin Complex
The Kawkawlin Complex encompasses an area of 100,000 hectares (248,000
acres) in the Saginaw Bay area of Michigan's Lower Peninsula. Important rivers
in the area are the Kawkawlin River, which has a mean annual discharge of 1.6 m^/s
(57 cfs), and the Pine River (ungauged). The area is generally flat with some
wetlands. Only about 10 percent of the area is forested, roughly 50 percent is
devoted to agriculture, and about 15 percent urbanized. The bedrock is composed
of sandstone. Overlying material consists of silt and clay near the shoreline
and glacial till over the remaining area. The economy is based on manufacturing
and agriculture with some oil extraction. Generally the waters are not influenced
by human activities. The cities of Pinconing (Pop.: 1,320) and Kawkawlin are the
only areas of industrial activity.
Station
Station DAM River and
Location Station Numbers
Pinconning River 32102
a 3210201
Kawkawlin River 32106
b 3210601
c 3210602
d 3210603
405
-------�
tS L/Sk *//
T?%y *.VC//
A06
-------�
Hydrologic Area 3.2.2
Saginaw River
The Saginaw River drains an area of 1,617,000 hectares (3,995,000 acres).
The area is located in the east central portion of Michigan's Lower Peninsula.
Generally only maximum flows are measured at the river mouth of the Saginaw
River. Major tributaries to the Saginaw River are the Cass River, Flint River,
Shiawassee River, and the Tittabawassee River. The topography is mostly flat,
with rolling hills in the west. Approximately 25 percent of the area is forested,
about 60 percent is agriculturized, and about 10 percent is urbanized. The bed-
rock is composed mostly of limestone. The soil is generally composed of a silt
and clay combination with glacial till in some areas. The economy is based
heavily on manufacturing with some agriculture and mining of natural resources
such as oil, sand and gravel, salt, peat, and clay. The cities of Saginaw, Bay
City and Flint are all heavy industrial areas and subject the surface waters to
heavy wastewater loadings. A large number of municipalities and industries use
the surface waters of ths Saginaw River and its tributaries for waste assimilation.
The cities of Flint (Pop.: 193,317), Saginaw (Pop.: 91,849), Bay City (Pop.:
49,449), Midland (Pop.: 35,176), Mount Pleasant (Pop.: 20,504), and Owosso
(Pop.: 17,179) are the most highly developed urban centers in this area.
Station Key
Station
Location
Saginaw River
a.
b
c
d
e
f
g
h
i
j
k
1
m
n
o
DAM River and
Station Numbers
32201
3220101
3220102
3220103
3220104
3220105
3220106
3220107
3220108
3220109
3220110
3220111
3220112
3220113
3220114
3220115
407
-------�
Hydrologic Area 3.2.3
Thumb Complex
PorLAusti
fd
•. \-i
rLA
n
Caseville
•Harbor Beach
b c
HURON
TUSCOLA
v-=
Vicinity Map-RBG 3.2
0
408
SCALE IN MILES
5 10 15 20
-------�
Hydrologic Area 3.2.3
Thumb Complex
The Thumb Complex encompasses an area of 367,000 hectares (907,000 acres).
The area is located in the east central portion of Michigan's Lower Peninsula.
Important tributaries from the area and their mean annual discharges are the
Pigeon River (0.9 m3/s; 32 cfs), the Willow River (1.3 m3/s; 46 cfs), the
Pinnebog River (ungauged), and the Sebewaing River (ungauged). The area is flat
with many additional small streams draining into Lake Huron. The area is also
characterized by many man-made drains crossing over the countryside. Less than
20 percent of the area is forested, about 60 percent is agriculturalized, and 5
percent is urbanized. Bedrock is composed of sandstone. Overlying material
contains glacial till as well as a silt and clay mixture. The economy is based
mainly upon agriculture, although there is some manufacturing. At least 5
municipalities and one industry discharge significant amounts of wastewater to
the surface waters of the area. The cities of Bad Axe (Pop.: 2,999), and Pigeon
(Pop.: 1,174) are the most highly developed centers in this sparsely populated
area. Large portions of this complex are extensively drained by tile systems.
Station Key
Station
Location
Quanicassee River
a
Sebewaing River
b
Pigeon River
c
d
e
f
Pinnebog River
g
h
Taft Drain
i
Willow River
3
White River
k
DAM River and
Station Numbers
32301
3230101
32307
3230701
32310
3231001
3231002
3231003
3231004
32311
3231101
3231102
32312
3231201
32316
3231601
32323
3232301
409
-------�
APPENDIX 2
POINT SOURCE AND
TRIBUTARY PHOSPHORUS LOADS
-------�
APPENDIX 2
LAKE ERIE
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN
STATE
TRIBUTARY
DRAINAGE AREA
HYDROLOGIC AREA CODE
MONITORED/UNMONITORED TRIBUTARY
Historical Tributary Loads
1976
1977
1978
1979
1980_
1981
LOAD
TRIBUTARY
7
DIRECT MUNICIPAL +
DIRECT INDUSTRIAL +
O 1^ y* I
TOTAL
DIRECT MUNICIPAL EXCESS
- V
, 9
LOAD
TRIBUTARY
/. 7
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL - /V, 9
NONPOINT
INDIRECT MUNICIPAL EXCESS
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN ERIE
STATE
TR1BUTARY &LAC<
DRAINAGE AREA W6.QOO acres
HYDROLOCIC AREA CODE
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN'
£#16
STATE MICH/6AM
TRIBUTARY ST. CLAlK COMPLEX
DRAINAGE AREA 3?3j.OOO e«.rc. 1082.
:» 1
«.,,«
-------�
1982 PHOSPHORUS LOAD
(Metelc Tons/Year)
BASIN_
STATE
TRIBUTARY
DRAIKAGE AREA 3?3,DQO
HYDROLOGIC AREA CODE V. /. 3
Historical Tributary Loads
1976 llel. 0
1977 / 33" r
197E /D7-0
1979
1980
1981
7f. 7
// 3- 7
79.3
LOAD
TRIBUTARY
99.3
DIRECT MUNICIPAL +
DIRECT INDUSTRIAL + O
TOTAL 99 3
DIRECT MUNICIPAL EXCESS
FLOW
LOAD
TRIBUTARY
99.3
INDIRECT MUNICIPAL - 62. /
INDIRECT INDUSTRIAL - 6 • 5~
NONPOINT 3C?-7
INDIRECT MUNICIPAL EXCESS "/
/•*/
ifl.VZ
9.? 3
7P-67
6 2.9V
-39.V7
O.
/.02.6V
f. OOO O
Forflf /v\o"tor Co-
A/ationG I I MIS'
Co -
O. /V2.3
O. 77$~
O.oi
O.O(o
0.9-725-
00
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
Historical Tributary Loads
BASIN ££)£ 1976 VS~
STATE /MlCj4/6A/\/ 1977 35~/.
TRIBUTARY fcOU&f- R\\/£fc 1978 / / c
DRAINAGE AREA V^g^OOO 1979 2O5~
HYDPOLOCIC AREA CODE V- /• V 1980 3?
MONITOREDdJMNITOREJ
LOAP
^TRIBUTARY
TRIBUTARY 2 £on^par> y
M^U£r"\ ^-Grbiolc. C.or-p
O.V347
/7. fiOOo
3-2?
2.V/ ,
3./Z.
76 .-7V
0./7
3TAJD/«fCT /AJ^DST^.HU
fcetv-oi-t- /^^tro fl/r/3orr J ^. 29^4, / 3.33
I / 1
1
2.?.0
CIPAL EXCESS £>
^Si%x)
-IMU.o ?
O.T 1
7. ft
Pkt-z 0^(^/-f)
l.toot
/.IC60
1. ?z/ 7
AV3/7
/. /far
•
•
0. //7V
0.17/7
-
0 .7300
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN
STATE MICHIGAN
TRIBUTARY t\(j£ON
DRAINAGE AR[/> S V 3^
HYDROLOGIC AREA CODE
«cr«rS
/ /• 5"
roN'iTOREufj">or;iTOREr TRIBUTARY
Historical Tributary Loads
1976_
TOTAL £>5~. 2.
DIRECT MUNICIPAL EXCESS O
PLOW/
LOAD
TRIBUTARY
INDIRECT MUNICIPAL - 34, ./
INDIRECT INDUSTRIAL - /.*V
NONPOINT
INDIRECT MUNICIPAL EXCESS - '
HI. 01
?. /s:
7. 37
o.
/. 2.2.
/.
/'flu;
. £25-0
i xc<*\
0.
0.6922.
6 . fO
0.7S-
2. GO '
0-
o. /a£"i
0. 79/2.
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN_
STATE
TRIBUTARY 5tU A/I/
DRAINAGE AREA fg2.,OOO acr
DIRECT INDUSTRIAL +
TOTAL -.. (e>
DIRECT MUNICIPAL EXCESS Q
LOAD
TRIBUTARY
INDIRECT MUNICIPAL -
O
INDIRECT INDUSTRIAL - ° 8
NONPOINT *~1'* "
INDIRECT MUNICIPAL EXCESS O
C.
O .OOiO
0. 0 3ff«/
O./O
c.oo,
£>. 7o
o. 63-33
o. r/^r
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN ERt£
STATE
TRIBUTARY
DRAINAGE ARC A
acres
HYDROLOGIC AREA CODE V. /• 7
TRIBUTARY
Historical Tributary Loads
1976 .237. 2.
1977
1978 /P/.9
1979
. O
1980
1981 /?/. O
LOAD
TRIBUTARY
233.5"
DIRECT MUNICIPAL
DIRECT INDUSTRIAL +
TOTAL
DIRECT MUNICIPAL EXCESS -//. /
LOAD
TRIBUTARY
.233.5"
INDIRECT MUNICIPAL .23 . 9
INDIRECT INDUSTRIAL - O
NONPOINT
INDIRECT MUNICIPAL EXCESS F.fe
Monro-e
If.fT
- 30.3V 6.390?
/* "vie i /%f i.
5~. 35-
/./r
9.25-
V.
O.O I
-------�
1982 PHOSPHORUS LOAD
(Metelc Tons/Year)
4
BASIN
STATE OH-IQ
TRIBUTARY
DRAINAGE AREA
HYDROLOGIC AREA CODE
2 . /
MONITORED/UNMONITOREWTRIBUTARY
Historical Tributary Loads
1976 ""
1977 -af.s"
1978
1979
1980_
1981
?
2.1. I
.2.
LOAD
TRIBUTARY
7V Z
DIRECT MUNICIPAL +
DIRECT INDUSTRIAL + O
7V. 2.
TOTAL
DIRECT MUNICIPAL EXCESS O
LOAD
TRIBUTARY
-7V.2.
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL - O
NONPOINT
INDIRECT MUNICIPAL EXCESS 7V- "2.
-------�
198? PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN_
STATE
QH-IO
TRIBUTARY MAl)
DRAINAGE AREA V, 2.2.?^ OO 0
HYDROLOGIC AREA CODE */. Z . "2-
(TON1TOREB/UNMOMTORED TRIBUTARY
Historical Tributary Loads
1976 /If7. 0 _
1977
1978 2 |
1979
1980
1981
LOAD
TRIBUTARY
DIRECT MUNICIPAL -t- I O 2 • 2.
DIRECT INDUSTRIAL * I • *1
TOTAL "3 I fF. 2.
OreG.
cn
"K0.f2.95
/.Po
. /o
o F6.ro
Ai ^r, ouTT- Sheu»e.-e.
Arckbolct
/.Z7/(e>
i/./f
Z.Z5-
3V.
y.^f
P. 30
V5".
y.
7. T7YJ
^v-^7
2..V657
-------�
..2_
TVCxtttT KUNtctPAL Ctwr-3 FUWfrMfrfc) /ys U>t,J*M*£\t"**sfy4&J) Phts a>»J'W',
At*\po/eor\.
Wky/TP
I. IIIcO
2.2.. //
^.23
-2.07
A 2?
56.2.
V-32.
/.^8
77.33-
0.6/73
o.
9. /30C,
-,26.?<.
77
Kte/u-
0.003-0
O.7377
3.
t>. /70j
0.3f72-
Forol fftoi~ur~ (-o
(Soold XAc. ~ /torr/S"
5 - Alk,OA
o .
o.
o. co S~o
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN
STATE
QH/0
TRIBUTARY TQUSSfllAJr-.POg/fl6£
DRAINAGE AREA 6?S"fc. QQQ a.cres.
HYDRCLOGIC AREA CODE */ "2 .3
Historical Tributary Loads
1976 /73.Z.
1977_ 237-5"
1978_
1979
1980
LOAD
TRIBUTARY
DIRECT MUNICIPAL +
,2.
DIRECT INDUSTRIAL +
TOTAL
DIRECT MUNICIPAL EXCESS ~0.~l
LOAD
TRIBUTARY
INDIRECT MUNICIPAL - //. fe
INDIRECT INDUSTRIAL - Q
NONPOINT
INDIRECT MUNICIPAL EXCESS - 1 -1 _
570933
/s:
-3.2.9
o.V?
o.7?SI
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN_
STATE
E&IE-
/ O
TRIBUTARY
DRAINAGE AREA °CiO_.OOC>
HYDROLOGIC AREA CODE V. 2. */
OKTORED)UN,':OKITORED TRIBUTARY
Historical Tributary Loads
1976 /py. y
1977 /V3.?
1978 £>?3.4
1979
97-T- 6
1980_
1981
I0
31
V.2.9O
o./y
«. 77/V
0.0?
. P7/ 7
-------�
1982 PHOSPHORUS LOAD
(Meteic Tons/Year)
BASIN ££/£
STATE <5UlO
TRIBUTARY
DRAINAGE AREA £>£>/, OOP ficrgs
HYDROLOGIC AREA CODE V. 2 . S"
Historical Tributary Loads
1976_
1977_
1978_
1979
1980_
19E1
. O
&0ulol
LOAD
TRIBUTARY
V7F.7
DIRECT MUNICIPAL + I <£> .7
DIRECT INDUSTRIAL + 0. 2.
TOTAL
DIRECT MUNICIPAL EXCESS /2.f
FLOW f»"6C)
LOAD
TRIBUTARY
INDIRECT MUNICIPAL - 23.3
INDIRECT INDUSTRIAL -
NONPOINT
INDIRECT MUNICIPAL EXCESS
/. 0 fa1/?
9.V?
Ve.r™i|/,on wu/TTP
/''?7?
32.. /3
JC..2.7
(,. 62.96
2.
TVDOST/f(A<-
C.C
0.37
O.OVi?
0.
-------�
BASIN € gi£
STATE OH- I O
TR1ELTARY
1982 PHOSPHORUS LOAD
(Keteic Tons/Year)
DRAINAGE AREA 5k g, OOP
HYDPOLOGIC AREA CODE
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN
STATE OHIO
TRIBUTARY
DRAINAGE AREA S 7 8. OOP
HYDRCLOGIC AREA CODE
/. 3.
/rONITOPED/L'N"ON!TORED TRIBUTARY
Historical Tributary Loads
1976 3II-J
1977 2EE.(e
1978 <1 I
1979 r/2-7
1980 "7/V-3
1981
.4.
LOAD
TRIBUTARY
DIRECT MUNICIPAL + 2. W-Z
DIRECT INDUSTRIAL * P.?
TOTAL J/^-i
DIRECT MUNICIPAL EXCESS /*?. /
LOAD
TRIBUTARY
INDIRECT MUNICIPAL - 3^5". Z
INDIRECT INDUSTRIAL - O
NONPOINT
INDIRECT MUNICIPAL EXCESS
9. ?
W
/2-fcOl?
30. 5-0 5"?
J.//.72.
5.YY
//9. 3o
•iVZ.O"?
Afcr-on ti-
Bcdfora/ /•
Bedford /
<5rOO^-^^r/c.
C w y o. K 3 a c\
^-,r ,c,f
^ ii?(i^' •£ t j
/-•-"•-',•;. r~
-y o-f
fe,^AtSj Clfyrf
c,fy "f
s city ^
Cit-y A>» /J
y^
-O /7< .- -"v
C
76. /Z2.V
3./9fr
^ . T2 VO
/.2.?5"0
^.Ofc/3
i. /9//
i 33^,
Mr.'^ '
affc.frY
^2.39
2V- 3)
'?. ?0
/ V- 9/
70. 2 /
//. /to
5^:7-
-/.33
/O.i9
/V. 76 .
/3.9V
-?.//
67.92.
2.?v
^7.53
/.coi?
/• f S-Vf
i.3-f/3
«/.03'*7
/.9/z9
«?. 575-7
y.3/2?
•'•/Vi/
-------�
CUYAHO<3A
TA;l>«f£cT
(tort,}
UK.
CA/TY co-
re , CI^Y '
I. POO/
-2.-i02.fc
2 .
I.
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN
STATE
TR 1 BUTARY C H /A 6 R I
DRAINAGE AREA /S"?,OOQ
HYDRCLOGIC AREA CODE
-------�
1962 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN ERlB
STATE
TRIBUTARY
OOO
DRAINAGE AREA
HYDROLOGIC AREA CODE V- 3 • V
fiCNI TOREDX'NVON I TORE D TRIBUTARY
LOAD
TRIBUTARY
~1 1 .
DIRECT MUNICIPAL +
DIRECT INDUSTRIAL + 0 .
TOTAL
DIRECT MUNICIPAL EXCESS
9. O
Historical Tributary Loads
1976_
1977
9V. 5~
19?6_
1979
, 2.
1980_
1981_
LOAD
TRIBUTARY
* ? ?> . 2.
/2-V. 3
~7/. *V
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL -
P*'*,
NONPOINT '/• • ''
INDIRECT MUNICIPAL EXCESS O
6vcfsi
C.ejnfy -
Coo
/e
"7. V 3 / 7
/-V77/
?. vr
-------�
EASIN ER\&
STATE
TRIBUTARY
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
- COAM]£A(jT
DRAINAGE AREA 22.0,0OO
HYDROLOGIC AREA CODE V. 3- 5"
'fwNITOP.EL
Historical Tributary Loads
1976_ VS" 3
197?
1978_
1979
1980
/.
2.3(c.J>
. 0
fe.7. O
f */
LOAD
TRIBUTARY
2. 2.. V
DIRECT MUNICIPAL +
7.7
DIRECT INDUSTRIAL +
TOTAL 30 .1
DIRECT MUNICIPAL EXCESS - j. 7
LOAD
TRIBUTARY
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL -
NONPOINT -2-2-V ,.
INDIRECT MUNICIPAL EXCESS O
C-or»r>e«w1-
of
/V.VJ
v.
-Z.V?
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
Historical Tributary Loads
BASIN £R.l£
STATE fa/ NY
TRIBUTARY EEl£- C
DRAINAGE AREA Hi
1976 '
1977 -2/U ?
-HA»UT«UQU<4 1978 / ? 2. . C-,
r.CJOO acres 1979 -?/.~7
HYDROLOGIC AREA CODE ^-/.V- / 1980 lie. \
KONITOREQ/lWONITOREDTJRIBUTAP.Y 19S1 2i~Y. Y
LOAD
TRIBUTARY
DIRECT MUNICIPAL +
DIRECT INDUSTRIAL +
/r/.?
LOAD
TRIBUTARY /T/-P
FT 2. INDIRECT MUNICIPAL - O
/• O INDIRECT INDUSTRIAL - ^
TOTAL 2*2-0 NONPOINT 'S~I-F -
DIRECT MUNICIPAL EXCESS -*»• / INDIRECT MUNICIPAL EXCESS O
p,««T fOW.c.OMu Ft
AjQrir\ ^OSf &oro^k 1
1^-JD £>u^»:irl<. SrP \
Fi-€dior\,0. $TP \
__ \
•Soutk lou/oS /?WT fi«t
\A/«5"f £.
H
O. 0 I TO
O.V3
O <5>
C cP
. —
/' £• c • fe a_
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN_
STATE
NEW
TR I BUTARY
DRAINAGE AREA
HYDROLOGIC AREA CODE */*/. 2-
(JONITORED^UNMONITORED TRIBUTARY
jjjstorical Tributary Loads
1976
1977
1978
1979
1980
1981
LOAD
TRIBUTARY
DIRECT MUNICIPAL +_
DIRECT INDUSTRIAL <
TOTAL
DIRECT MUNICIPAL EXCESS
LOAD
TRIBUTARY
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL -
0
NONPOINT
INDIRECT MUNICIPAL EXCESS O
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN_
STATE
TRIBUTARY 8/6
DRAINAGE AREA
HYDROLOGIC AREA CODE V. V. 3
KONITORED/W1CNITORCD TRIBUTARY
Historical Tributary Loads
1976
1977 —--
1976
1979
1980_
1981
LOAD
TRIBUTARY
O
DIRECT MUNICIPAL + Jl.f
DIRECT INDUSTRIAL + £
TOTAL •>''
DIRECT MUNICIPAL EXCESS
2 fc.
V. 3 2(5=0
9
LOAD
TRIBUTARY
O
INDIRECT MUNICIPAL - 0
INDIRECT INDUSTRIAL - 0
NONPOINT 0
INDIRECT MUNICIPAL EXCESS Q
-6.00
27. y?
-------�
APPENDIX 2
LAKE ONTARIO
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
Historical Tributary Loads
BASIN OA/TA£iD 1976
STATE A)£\*J YOKK 1977
TRIBUTARY ALL 1978_
DRAINAGE AREA ALL 1979
HYDROLOGIC AREA CODE 1980_
MONITORED/UNMONITORED TRIBUTARY 1981
LOAD LOAD
TRIBUTARY y732>f TRIBUTARY /7 ?3.*/
DIRECT MUNICIPAL + 725*. ? INDIRECT MUNICIPAL -
DIRECT INDUSTRIAL + .27. / INDIRECT INDUSTRIAL - 3 . 3
TOTAL .2 VST. 2. NONPOINT I*
DIRECT MUNICIPAL EXCESS /5"V-O INDIRECT MUNICIPAL EXCESS
-------�
1982 PHOSPHORUS LOAD
(Metfic Tons/Year)
BASIN
STATE
TRIBUTARY
DRAINAGE AREAS (c(e^, OOP *trts
HYDROLOGIC AREA CODE 5~. I. I
fcONITOPrefclWONITORtfc TRIBUTARY
Historical Tributary Loads
1976_
1977_
197£
1979 IF7-2-
1980_
1981
2.32.. I
LOAD
TRIBUTARY
DIRECT MUNICIPAL + 5" 6 3. I
. 7
DIRECT INDUSTRIAL + O
TOTAL
DIRECT MUNICIPAL EXCESS
. O
LOAD
TRIBUTARY
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL -
Q. I
NONPOINT 3S~F.,7
INDIRECT MUNICIPAL EXCESS /2 .
»<&/f]
6, rets
Two
Y.Z57?
f/.Z?
*Tf**2.
?. 03
7.6,1
3^.S7
Creet St> pi.
of
A'OrTn Tc r
TP
5V 77 2.7
10. 0035-
?0. SI ?2-
7. HI 3Y
X/3.53
22. /f
/. /O
0.37
-/o. /y
/ /2- . 2.5-
-•23.6?
- P.
5TVZ2-2.
/.rr?3
"S-OCOO
0. 7W2.
. Fit-'"
-------�
(font)
2. of 2.
577s
Village o-f- A& A/I;
02.
y.
."2-?
-20.35
o./9
-------�
1982 PHOSPHORUS LOAD
(Metpic Tons/Year)
BAS1N_
STATE
TRIBUTARY
DRAINAGE AREAS /. Sf(ot OOP ctc
HYDROLOGIC AREA CODE S7 A Z
TRIBUTARY
Historical Tributary Loads
1976 5VO. /
1977
197P
1979
2T7. ?
1980
1981
LOAD
TRIBUTARY
. O
DIRECT MUNICIPAL * /3V.
DIRECT INDUSTRIAL +
TOTAL
DIRECT MUNICIPAL EXCESS -_//. Z.
LOAD
TRIBUTARY
. o
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL - 2- O
NONPOINT J r^l . 3
INDIRECT MUNICIPAL EXCESS ~2.~7?
//. 3V/7
330. 03.
-2V. 2.Y
O.
o. 9z5o'
AVOV
Wei Is v.1 fie
/.04.7/
SIP
~. 70
0.77(0?
£>. S757
/. / OQ O
Co,
73.
0 Scf 7
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
EASIN
STATE A/£-fc/
TRIBUTARY
DRAINAGE AREAS VB7. OOP a
HYDRCLOGIC AREA CODE 5T 2 . /
MOM TORE D^JNflONI TOR[F>! 1 B UTAR Y
Historical Tributary Loads
1976
1977
74. V
197£
1979
1980_
1981
vs. 3
LOAD
TRIBUTARY
9/-0
DIRECT MUNICIPAL
DIRECT INDUSTRIAL +
TOTAL //^ .5"
DIRECT MUNICIPAL EXCESS /?
Direct municipal
C^&b)
LOAD
TRIBUTARY
9/.O
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL -
NONPOINT Rl-O'*
INDIRECT MUNICIPAL EXCESS O
Webster PWS PH to. •$
J2.6797
3V. fo
33. f 3
H. 3,000
-l-oooo
-/.oo
5".
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
EASIN OAJTARiO
STATE
TR I BL'TARY QSlOf&O
DRAINAGE AREAS 3. 25*2.000
HYDROLOGIC AREA CODE 5^2.. "2-
TRIBUTARY
Historical Tributary Loads
1976 9/f.D _
1977 //.Zfe.3
1978
1979 SQ79.2-
1980
1981
LOAD
TRIBUTARY
V33./
DIRECT MUNICIPAL +
3. /
DIRECT INDUSTRIAL +
TOTAL V 3 6 • 2.
DIRECT MUNICIPAL EXCESS "O
LOAD
TRIBUTARY
V33. /
INDIRECT MUNICIPAL -
INDIRECT INDUSTRIAL -
1-2.
NONPOINT /6>3 . /
INDIRECT MUNICIPAL EXCESS IZO,(t>
P/ios L**d "y#*v &c£*s *¥((** Phos.
STP
/0.7/f2
I. 3700
2.9/71?
ST/°
Fulton V/pC-f>
STP
27.33
2.5". O2.
Oc\(c
UVTP
2.00OO
22.70
/. V/Z/
s-.s-t
30.33
Road
-/. 67
0.2g
10.12.
-1-62.
2./0
1.2.7
G.ll
21. sy
1,1.zr
/.
o.
3.0000
H.oooo
2..5T50O
/. 20^3
2.2791
3. OOOO
/.27/V
r. vv / 7
-------�
(calf-.) 5". 2.:
of 2.
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STP
UJests.d*
/.OC75"
/. 522.7
Y. 02.
JosepK
- /. coco
0. 0/1 9
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2..II
o. n
- /.
9.63^0
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN DA/rA£lQ
STATE
TRiBUTARY S/VLnaflA/
DRAINAGE AREAS 67^OOP
HYDROLOGIC AREA CODE S". 2.
Historical Tributary Loads
1976
1977
1978
1979
1980_
1981
A2/.
. Q
92.7
LOAD
TRIBUTARY
DIRECT MUNICIPAL +
DIRECT INDUSTRIAL +
. 9
o
O
TOTAL
DIRECT MUNICIPAL EXCESS
Q
LOAD
TRIBUTARY
5T.?
INDIRECT MUNICIPAL - Q_
INDIRECT INDUSTRIAL - Q
NONPOINT
INDIRECT MUNICIPAL EXCESS
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN_
STATE
TRIBUTARY
DRAINAGE AREAS /, Zg?.OOO
HYDROLOGIC AREA CODE 5" "3 . /
TRIBUTARY
Historical Tributary Loads
1976
1977
. O
1978
1979
1980
1981
//f.
/33-r
LOAD
TRIBUTARY
DIRECT MUNICIPAL +
DIRECT INDUSTRIAL +
0
TOTAL
DIRECT MUNICIPAL EXCESS
Xr.diree.~f
LOAD
TRIBUTARY
INDIRECT MUNICIPAL - I 2.J .
INDIRECT INDUSTRIAL -
*/
NONPOINT --.-!
INDIRECT MUNICIPAL EXCESS /'OS". 7
F;e.lel
ft II a
•y-
9-05-5-J-
O.
9fc.&,/
3.9V
62.35
-2 37. 0(o
- <*. 73
3.6933
65". 750O
0.2900
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN QA/T4£lO
STATE
TR I BUTARY
CO
DRAINAGE AREAS 3//.QOQ acre*
HYDROLOGIC AREA CODE 5T. B . 2.
MONI TOREtXjUNMON I TO^EpTR I BUTARY
Historical Tributary Loads
1976
1977
1978
1979
1980_
1981
//.
LOAD
TRIBUTARY
DIRECT MUNICIPAL +
o
DIRECT INDUSTRIAL +
O
TOTAL
DIRECT MUNICIPAL EXCESS
LOAD
TRIBUTARY
INDIRECT MUNICIPAL -
O
INDIRECT INDUSTRIAL -
NONPOINT /.
INDIRECT MUNICIPAL EXCESS O
-------�
APPENDIX 2
SAGINArt BAY
-------�
PHOSPHORUS LOAD
(Metric Tons/Year)
B AS I N
STATE
BM
TRIBUTARY
ALL
DRAINAGE AREA
HYDROLOGIC AREA CODE
MONITORED/UNMONITORED TRIBUTARY
Historical Tributary Loads
1976
1977
1978
1979
1980_
1981
LOAD
TRIBUTARY
620,3
DIRECT MUNICIPAL + 38 . 1
DIRECT INDUSTRIAL +
. 0
TOTAL >. 0
DIRECT MUNICIPAL EXCESS ___/_?•?
LOAD
TRIBUTARY
. 3
INDIRECT MUNICIPAL - /
INDIRECT INDUSTRIAL - 76. /
NONPOINT 3^' ^
INDIRECT MUNICIPAL EXCESS //.*/
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN
STATE
TR I BUTAR Y
IE - AO G>RES
DRAINAGE AREA lO^.OOO *vcre5
HYDROLOGIC AREA CODE
MONITORED/UNMONITORED TRIBUTARY
LOAD
TRIBUTARY
DIRECT MUNICIPAL •
DIRECT INDUSTRIAL
O
TOTAL
DIRECT MUNICIPAL EXCESS
Historical Tributary Loads
1976
1977 —
1978
1979
1980_
1981
3Z.Z.
vy.2.
LOAD
6 TRIBUTARY
INDIRECT MUNICIPAL - Q
INDIRECT INDUSTRIAL -
NONPOINT
INDIRECT MUNICIPAL EXCESS
-------�
1982 PHOSPHORUS LOAD
(Metric Tons/Year)
BASIN
STATE MjCrt/6/Q/V/
TRIBUTARY
DRAINAGE AREA
HYDROLOGIC AREA CODE 3."2..f
MONITORED/UNMONITORED TRIBUTARY
LOAD
RIBUTARY
DIRECT MUNICIPAL + O
DIRECT INDUSTRIAL +
TOTAL
DIRECT MUNICIPAL EXCESS
Historical Tributary Loads
1976
1977 -
1978 •
1979
1980_
1981
LOAD
flflVRIBUTARY
INDIRECT MUNICIPAL - A
INDIRECT INDUSTRIAL - 0
NONPOINT
INDIRECT MUNICIPAL EXCESS O
-------�
1962 PHOSPHORUS LOAD
(Metric Tons/Year)
B AS i N __ SA(3//VAW
STATE
Historical Tributary Loads
1976 '—'
1977 "~
TRIBUTARY
1978
DRAINAGE AREA 3;? 3S"_. OOP
HYDROLOG1C AREA CODE 3.2.
1979
MONITORED/UNMON1TOPED TRIBUTARY
1960_
1981
LOAD
(/f?3) TRIBUTARY
LOAD
DIRECT MUNICIPAL + 3?. "7
DIRECT INDUSTRIAL * 3.2
TOTAL
DIRECT MUNICIPAL EXCESS
INDIRECT MUNICIPAL - /f 3. 9
INDIRECT INDUSTRIAL - 76» /
NONPOINT
INDIRECT MUNICIPAL EXCESS //. V
C'.iy
TtoP -sw fcisT.1,
27.JS-
0.775-0
,j WWTP
vv/WTF
STP
/. 22.57
-?0.
3.7?
-3.0?
-37V/
5766
/2.V7
7.9o
3 7.50
0.70
o.
5.5"OOO
0.5-5-?/
o. 79 ?3
0.
/.
3.
-------�
3.2.2.
.2 "f 2—
WWTP
WWTP
)xpt »* 0*1.
•J
west &\y
2. i lu;«j|c«e
7.3000
6.77
//. 12.
Affjelf>H
i4r\
£>/T)C -6i»c)< ftftar X>»V
6M6- /^ster
^J. 5bc3C>
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0.05"70
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0>.OOI(e>
0.02-
0.<5 I
6.0(o
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/P-B'r
O.M
o.o/
0.02,
/•/a.
-5727
5.2V
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0. 9525"
L 8-65"
H.tfoo
o.o^FO
*.H?00
H.
I
/. oooo
0.?/36>
0-626,7
-/.
-------�
1962 PHOSPHORUS LOAD
(Metric Tons/Year)
B AS i N 5^6 /A/AW
STATE
TRIBUTARY
DRAINAGE AREA ^07,000
HYDROLOGIC AREA CODE 3. 2 .
MCNITORED/UNMCNITORED TRIBUTARY
LOAD
(TRIBUTARY
DIRECT MUNICIPAL + Q
DIRECT INDUSTRIAL + */.
TOTAL •*• i">
DIRECT MUNICIPAL EXCESS O
Historical Tributary Loads
1976 -
1977 —
1978 ~
1979 — •
1980 /9. 7
1981
-------�
APPENDIX 3
LAKES ERIE AND ONTARIO
TRIBUTARY LOAD DATA
-------�
APPENDIX 3
LAKE EKIE
-------�
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-------�
APPENDIX 3
LAKE ONTARIO
-------�
Y
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