U.S. ENVIRONMENTAL PROTECTION AGENCY
NATIONAL EUTROPHICATION SURVEY
WORKING PAPER SERIES
REPORT
ON
LAKE TIPPECANOE
KQSCIUSKQ COINIY
INDIANA
EPA REGION V
WORKING PAPER No, 342
CORVALLIS ENVIRONMENTAL RESEARCH LABORATORY - CORVALLIS, OREGON
and
ENVIRONMENTAL MONITORING & SUPPORT LABORATORY - LAS VEGAS, NEVADA
699-440
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REPORT
ON
LAKE TIPPECANOE
KDXIUSKD COUNTY
INDIANA
EPA REGION V
WORKING PAPER No, 342
WITH THE COOPERATION OF THE
INDIANA STATE BOARD OF HEALTH
AND THE
INDIANA NATIONAL GUARD
JULY, 1976
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CONTENTS
Page
Foreword i i
List of Indiana Study Lakes iv
Lake and Drainage Area Map v
Sections
I. Conclusions 1
II. Lake and Drainage Basin Characteristics 3
III. Lake Water Quality Summary 4
IV. Nutrient Loadings 8
V. Literature Reviewed 12
VI. Appendices 13
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FOREWORD
The National Eutrophication Survey was initiated in 1972 in
response to an Administration commitment to investigate the nation-
wide threat of accelerated eutrophication to fresh water lakes and
reservoirs.
OBJECTIVES
The Survey was designed to develop, in conjunction with state
environmental agencies, information on nutrient sources, concentrations,
and impact on selected freshwater lakes as a basis for formulating
comprehensive and coordinated national, regional, and state management
practices relating to point-source discharge reduction and non-point
source pollution abatement in lake watersheds.
ANALYTIC APPROACH
The mathematical and statistical procedures selected for the
Survey's eutrophication analysis are based on related concepts that:
a. A generalized representation or model relating
sources, concentrations, and impacts can be constructed.
b. By applying measurements of relevant parameters
associated with lake degradation, the generalized model
can be transformed into an operational representation of
a lake, its drainage basin, and related nutrients.
c. With such a transformation, an assessment of the
potential for eutrophication control can be made.
LAKE ANALYSIS
In this report, the first stage of evaluation of lake and water-
shed data collected from the study lake and its drainage basin is
documented. The report is formatted to provide state environmental
agencies with specific information for basin planning {§303(e)>, water
quality criteria/standards review {§303(c)>, clean lakes {§314(a,b)>,
and water quality monitoring {§106 and §305(b)} activities mandated
by the Federal Water Pollution Control Act Amendments of 1972.
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m
Beyond the single lake analysis, broader based correlations
between nutrient concentrations (and loading) and trophic condi-
tion are being made to advance the rationale and data base for
refinement of nutrient water quality criteria for the Nation's
fresh water lakes. Likewise, multivariate evaluations for the
relationships between land use, nutrient export, and trophic
condition, by lake class or use, are being developed to assist
in the formulation of planning guidelines and policies by EPA
and to augment plans implementation by the states.
ACKNOWLEDGMENT
The staff of the National Eutrophication Survey (Office of
Research & Development, U. S. Environmental Protection Agency)
expresses sincere appreciation to the Indiana State Board of
Health for professional involvement, to the Indiana National
Guard for conducting the tributary sampling phase of the Survey,
and to those Indiana wastewater treatment plant operators who
provided effluent samples and flow data.
The staff of the Division of Water Pollution Control, Indiana
State Board of Health, provided invaluable lake documentation and
counsel during the Survey, reviewed the preliminary reports, and
provided critiques most useful in the preparation of this Working
Paper series.
Major General Alfred F. Ahner, Adjutant General of Indiana,
and Project Officers Lt. Colonel Charles B. Roberts (Retired)
and Colonel Robert L. Sharp, who directed the volunteer efforts
of the Indiana National Guardsmen, are also gratefully acknowledged
for their assistance to the Survey.
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IV
NATIONAL EUTROPHICATION SURVEY
STUDY LAKES
STATE OF INDIANA
LAKE NAME
Bass
Cataract
Crooked
Dallas
Geist
Hamilton
Hovey
James
James
Long
Marsh
Mississinewa
Maxinkuckee
Monroe
Morse
01 in
Oliver
Pigeon
Sylvan
Tippecanoe
Versailles
Wawassee
Webster
Westler
Whitewater
Winona
Witmer
COUNTY
Starke
Owen, Putnam
Steuben
LaGrange
Hamilton, Marion
Steuben
Posey
Kosciusko
Steuben
Steuben
Steuben
Grant, Miami, Wabash
Marshall
Brown, Monroe
Hami1 ton
LaGrange
LaGrange
Steuben
Noble
Kosciusko
Ripley
Kosciusko
Kosciusko
LaGrange
Union
Kosciusko
LaGrange
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LAKE >PECANOE
Tributary Sampling Site
X Lake Sampling Sitt
• Sewage Treatment Facility
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LAKE TIPPECANOE
STORE! NO. 1844
I. CONCLUSIONS
A. Trophic Condition:
Survey data indicate that Lake Tippecanoe is mesotrophic.
It ranked fourth in overall trophic quality when the 27 Indiana
lakes sampled in 1973 were compared using a combination of six
parameters*. Four of the lakes had less and one had the same
median total dissolved phosphorus, four had less and three had
the same median dissolved phosphorus, three had less median inor-
ganic nitrogen, six had less mean chlorophyll a^ and two had
greater mean Secchi disc transparency. Hypolimnetic dissolved
oxygen was depleted at station 2 in October.
Survey limnologists reported submerged macrt>phytes were
common in the shallows near station 1 but were sparse near sta-
tion 2.
B. Rate-Limiting Nutrient:
The algal assay results indicate the lake was phosphorus
limited at the time the sample was taken (05/03/73). The lake
data indicate phosphorus limitation at all sampling times.
C. Nutrient Controllability:
1. Point sources—No known municipal or industrial point
sources directly impacted Lake Tippecanoe during the sampling
year. However, municipal waste treatment facilities are planned
* See Appendix A.
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2
for the Town of North Webster (BonHomme, 1976) with an effluent
discharge to the Tippecanoe River upstream from James Lake* (see
map, page v). The treatment plant will contribute some nutrients
to Lake Tippecanoe via the river and the James Lake outlet, and it
will be necessary to evaluate the possible significance of this new
phosphorus source once the plant is put in operation.
The present phosphorus loading of 1.10 g/m2/yr is a little
more than that proposed by Vollenweider (Vollenweider and Dillon,
1974) as a eutrophic loading (see page 11). Apparently, much of
the phosphorus input is utilized by macrophytes so that other
symptoms of eutrophy are minimal.
2. Non-point sources—Both the Tippecanoe River and Grassy
Creek drain relatively large lakes which have well-developed shore-
t
lines. The percentages of total phosphorus contribution of the
streams are similar (44.9% and 48.3%) as are the non-point phos-
phorus export rates (11 and 12 kg/km2/yr; see page 10).
*~ltorking Paper No. 330
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II. LAKE AND DRAINAGE BASIN CHARACTERISTICS1"
A. Lake Morphometry :
1. Surface area: 3.11 kilometers2.
2. Mean depth: 11.3 meters.
3. Maximum depth: 37.5 meters.
4. Volume: 35.143 x 106 m3.
5. Mean hydraulic retention time: 148 days.
B. Tributary and Outlet:
(See Appendix C for flow data)
1. Tributaries -
Drainage Mean flow
Name area (km2)* (m3/sec)*
Tippecanoe River 144.8 1.37
Grassy Creek 134.2 1.27
Minor tributaries &
immediate drainage - IQjS 0.10
Totals 289.6 2.74
2. Outlet -
Tippecanoe River 292.7** 2.74**
C. Precipitation***:
1. Year of sampling: 79.7 centimeters.
2. Mean annual: 88.5 centimeters.
t Table of metric conversions—Appendix B.
tt Winters, 1975.
* For limits of accuracy, see Working Paper No. 175, "...Survey Methods,
1973-1976".
** Includes area of lake; outflow adjusted to equal sum of inflows.
*** See Working Paper No. 175.
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4
III. LAKE WATER QUALITY SUMMARY
Lake Tippecanoe was sampled three times during the open-
water season of 1973 by means of a pontoon-equipped Huey helicopter.
Each time, samples for physical and chemical parameters were
collected from a number of depths at two stations on the lake
(see map, page v). During each visit, a single depth-integrated
(4.6 m to surface) sample was composited from the stations for
phytoplankton identification and enumeration; and during the first
visit, a single 18.9-liter depth-integrated sample was composited
for algal assays. Also each time, a depth-integrated sample was
collected from each of the stations for chlorophyll a^ analysis.
The maximum depths sampled were 9.8 meters at station 1 and 9.1
meters at station 2.
The sampling results are presented in full in Appendix D and
are summarized in the "following table.
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PARAMETER
TEMP (C)
DISS OXY (MG/L)
CNDCTVY (MCROMO)
PH (STAND UNITS)
TOT ALK (MG/L)
TOT P (MG/L)
ORTHO P (MG/L)
N02«N03 (MG/L)
AMMONIA (MG/L)
KJEL N (MG/L)
INORG N (MG/L)
TOTAL N (MG/L)
CHLRPYL A (UG/L)
SECCHI (METERS)
A. SUMMARY OF PHYSICAL AND
1ST SAMPLING ( 5/ 3/73)
? SITES
CHEMICAL CHARACTERISTICS FOR TIPPECANOE LAKE
STORET CODE 1844
2ND SAMPLING ( 8/ 4/73)
2 SITES
3RD SAMPLING (10/13/73)
2 SITES
RANGE
11.9
9.1
495.
6.2
200.
0.017
0.002
0.100
0.050
0.600
0.160
0.800
4.8
7 -U
- 13.4
9.7
- 500.
8.3
- 204.
- 0.028
- 0.006
- 1.200
- 0.070
- 0.800
- 1.270
- 2.000
5.5
- T.n
MEAN
13.1
9.3
499.
8.2
202.
0.024
0.003
0.950
0.057
0.700
1.007
1.650
5.1
?-7
MEDIAN
13.2
9.3
500.
8.2
201.
0.025
0.002
1.050
0.060
0.700
1.105
1.750
5.1
3-7
RANGE
14.0
7.0
383.
7.4
166.
0.013
0.002
0.060
0.060
0.700
0.120
0.820
9.2
- 25.6
9.8
- 426.
8.5
- 198.
- 0.019
- 0.009
- 0.710
- 0.130
- 1.000
- 0.840
- 1.610
9.6
MEAN
22.7
7.9
410.
8.2
172.
0.016
0.004
0.180
0.080
0.857
0.260
1.037
9.4
' MEDIAN
33.6
7.7
412.
8.3
168.
0.016
0.003
0.110
0.070
0.900
0.180
0.990
9.4
RANGE
15.5
0.0
376.
7.6
163.
0.016
0.009
0.030
0.060
0.800
0.100
0.640
2.9
?.7
- 19.8
8.0
- 385.
8.3
- 187.
- 0.030
- 0.022
- 0.100
- 0.420
- 1.300
- 0.450
- 1.330
4.3
?_8
MEAN
18.9
5.3
380.
8.1
170.
0.021
0.012
0.054
0.134
0.967
0.189
1.021
3.6
?.H
MEDIAN
19.5
6.0
380.
8.2
171.
0.019
0.011
0.050
0.100
0.900
0.1SO
0.960
3.6
?.H
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B. Biological Characteristics:
1. Phytoplankton -
Sampling
Date
05/03/73
08/04/73
10/13/73
2. Chlorophyll a_ -
Sampling
Date
05/03/73
08/04/73
10/13/73
Dominant
Genera
1.
2.
3.
4.
5.
1.
2.
3.
4.
5.
1.
2.
3.
4.
5.
Frazil aria sjs.
Aster ion ell a sj).
Melosira SJD.
Flagellates
Cryptomonas sp.
Other genera
Total
Cyclotella sp.
Lyngbya S£.
Oscillatoria SJD.
Microcystis sp.
Synedra sp.
Other genera
Total
Lyngbya sp.
Aphanizomenon SJD,
Scenedesmus sp.
Dinobryon s£.
Achnanthes sp.
Other genera
Algal Units
per ml
627
292
292
292
204
656
2,363
Total
Station
Number
1
2
1
2
1
2
4,794
682
185
128
85
85
440
1,605
Chlorophyll
(ug/D
4.8
5.5
9.2
9.6
2.9
4.3
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7
Limiting Nutrient Study:
1. Autoclaved, filtered, and nutrient spiked -
Ortho P Inorganic N Maximum yield
Spike (mg/1) Cone, (mg/1) Cone, (mg/1) (mg/1-dry wt.)
Control 0.005 1.000 1.0
0.050 P 0.055 1.000 22.1
0.050P+1.0N 0.055 2.000 30.2
1.0 N 0.005 2.000 0.2
2. Discussion -
The control yield of the assay alga, Selenastrum capri-
cornutum, indicates that the potential primary productivity
of Lake Tippecanoe was moderate at the time the assay sample
was collected. The significant increase in yield when ortho-
phosphorus was added and the lack of increase when nitrogen
alone was added indicate phosphorus limitation.
The lake data also indicate phosphorus limitation; i.e.,
the mean inorganic nitrogen/orthophosphorus ratios were 16/1
or greater at all sampling times, and phosphorus limitation
would be expected.
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8
IV. NUTRIENT LOADINGS
(See Appendix E for data)
For the determination of nutrient loadings, the Indiana National
Guard collected monthly near-surface grab samples from each of the
tributary sites indicated on the map (page v), except for the high
runoff month of March when two samples were collected. Sampling was
begun in June, 1973, and was completed in May, 1974.
Through an interagency agreement, stream flow estimates for the
year of sampling and a "normalized" or average year were provided'by
the Indiana District Office of the U.S. Geological Survey for the
tributary sites nearest the lake.
In this report, nutrient loads for sampled tributaries were
determined by using a modification of a U.S. Geological Survey computer
program for calculating stream loadings*. Nutrient loads for unsampled
"minor tributaries and immediate drainage" ("ZZ" of U.S.G.S.) were esti-
mated using the nutrient loads at station C-l, in kg/km2/year, and multi-
plying by the ZZ area in km2.
Nutrient loads at station A-2 were based on the flow and nutrient
concentrations at outlet station A-l of James Lake** which is the same
location as inlet station A-2 of Lake Tippecanoe.
Note that estimates of septic tank phosphorus loads were reduced
by 50% to adjust for the Indiana ban on phosphate detergents instituted
in January, 1972.
* See Working Paper No. 175.
** Working Paper No. 330.
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9
A. Waste Sources:
1. Known municipal - None
2. Known industrial - None
B. Annual Total Phosphorus Loading - Average Year:
1. Inputs -
kg P/ % of
Source ,y_r total
a. Tributaries (non-point load) -
Tippecanoe River 1,535 44.9
Grassy Creek 1,650 48.3
b. Minor tributaries & immediate
drainage (non-point load) - 125 3.7
c. Known municipal STP's - None
d. Septic tanks* - 50 1.5
e. Known industrial - None
f. Direct precipitation** - 55 1.6
Total 3,415 100.0
2. Outputs -
Lake outlet - Tippecanoe River 2,410
3. Net annual P accumulation - 1,005 kg.
* Estimate based on 357 lakeshore dwellings; see Working Paper No. 175.
** See Working Paper No. 175.
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10
C. Annual Total Nitrogen Loading - Average Year:
1. Inputs -
kg N/ % of
Source yr total
a. Tributaries (non-point load) -
Tippecanoe River 97,490 45.9
Grassy Creek 99,780 47.0
b. Minor tributaries & immediate
drainage (non-point load) - 7,885 3.7
c. Known municipal STP's - None
d. Septic tanks* - 3,805 1.8
e. Known industrial - None
f. Direct precipitation** - 3^360 1.6
Total 212,320 100.0
2. Outputs -
Lake outlet - Tippecanoe River 171,350
3. Net annual N accumulation - 40,970 kg.
D. Mean Annual Non-point Nutrient Export by Subdrainage Area:
Tributary kg P/km2/yr kg N/km2/yr
Tippecanoe River 11 673
Grassy Creek 12 744
* Estimate based on 357 lakeshore dwellings; see Working Paper No. 175.
** See Working Paper No. 175.
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11
E. Yearly Loads:
In the following table, the existing phosphorus loadings
are compared to those proposed by Vollenweider (Vollenweider
and Dillon, 1974). Essentially, his "dangerous" loading is
one at which the receiving water would become eutrophic or
remain eutrophic; his "permissible" loading is that which
would result in the receiving water remaining oligotrophic
or becoming oligotrophic if morphometry permitted. A meso-
trophic loading would be considered one between "dangerous"
and "permissible".
Note that Vollenweider's model may not be applicable to
water bodies with short hydraulic retention times.
Total Phosphorus Total Nitrogen
Total "Accumulated" Total Accumulated
grams/mVyr - 1.10 0.32 68.3 13.2
Vollenweider phosphorus loadings
(g/m2/yr) based on mean depth and mean
hydraulic retention time of Lake Tippecanoe:
"Dangerous" (eutrophic loading) 1.00
"Permissible" (oligotrophic loading) 0.50
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12
V. LITERATURE REVIEWED
BonHomme, Harold L., 1976. Personal communication (planned
waste treatment facilities at North Webster). IN Div. of
Water Poll. Contr., Indianapolis.
Vollenweider, R. A., and P. J. Dillon, 1974. The application of
the phosphorus loading concept to eutrophication research.
Natl. Res. Council of Canada Pub!. No. 13690, Canada Centre
for Inland Waters, Burlington, Ontario.
Winters, John, 1975. Personal communication (lake morphometry).
IN Div. of Water Poll. Contr., Indianapolis.
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VI. APPENDICES
APPENDIX A
LAKE RANKINGS
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LAKE DAT-A 10 BE 'JSED IN RANKINGS
LAKE
CODE
1805
1811
1817
1827
182n
1829
183b
1837
1839
1840
1841
1842
1H43
1844
1845
1B46
1847
104«
1849
1850
1851
1852
1853
1854
1855
1856
1857
LAKE NAME
CATARACT LAKE
GEIST RESERVOIR
JAMES LAKE
MISS1SSINEWA RESERVOIR
MONKOE RESERVOIR
MORSE RESERVOIR
WAWASEE LAKE
WEBSTER LAKE
WHITEWATER LAKE
WINONA LAKE
WESTLER LAKE
WITHER LAKE
LAKE MAMNKUCKEE
TIPPECANOE LAML
DALLAS LAKE
OLIN LAKE
OLIVER LAKE
SYLVAN LAKE
HOVEY LAKE
VERSAILLES LAKE
BASS LAKE
CROOKED LAKE
LAKE JAMES
LONG LAKE
R1GEON LAKE
MARSH LAKL
HAMILTON LAKE
MEUUN
TOTAL P
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
.059
.07*
.024
.107
.025
.084
.012
.025
.084
.035
.035
.035
.020
.019
.029
.012
.009
.170
.062
.139
.040
.019
.016
.204
.058
.093
.033
MEDIAN
INORG N
l.hbO
1.080
1.030
2.400
• 0.325
3.325
0.210
0.790
1.62C
1.250
0.860
0.900
0.220
0.195
0.830
1.460
0.920
0.130
1.050
1.090
0.250
0.120
0.190
1.920
1.445
0.270
0.720
500-
MEAN i£C
466
472
434
473
43o
473
364
431
470
444
427
440
400
391
413
403
392
469
489
482
471
410
352
442
442
451
413
.667
.500
.000
.444
.023
.222
.500
.000
.167
.667
.125
.333
.400
.500
.333
.333
.000
.833
.333
.000
.375
.111
.444
.667
.067
.333
.167
C
10
45
11
15
b
56
5
11
33
11
1C
11
5
6
10
4
3
47
84
25
29
5
4
16
1 1
J4
n
n!o?a
.744
.950
.533
.778
.947
.167
.000
.500
.083
.211
.712
.917
.483
.050
.067
.867
.767
.480
.267
.07o
.367
.578
.856
.100
.900
.467
.4*0
M
15
11
15
15
IS
15
14
15
15
15
15
15
15
15
15
14
14
14
7
14
7
15
15
15
15
15
15
I '•! LIU
.000
.60C
.OOli
.000
.uuc
.000
.600
.UOO
.000
.000
.000
.000
.000
.000
.000
.900
.800
.800
.600
.500
.000
.000
.000
.ooc
.000
.000
.000
0 J ri S 'J •* T •
0.0 1 j
0.009
O.Ouc*
0.02-y
0. JO 1
0 . 0 0 •>
O.OOJ
0.005
0.012
0.011
0.013
0.011
0.003
0.005
0.014
0.003
0.004
0.017
0.024
O.U19
0.012
0.005
0.005
O.lbC
0.015
0.055
o.oia
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PERCENT OF LAKES WITH HIGHER VALUES (NUMBED OF LAKES WITH HIGHE« VALUES)
LAKE
CODE
IH05
1611
1817
1827
1628
1H29
1636
1837
1B39
1840
1841
1842
1843
1844
1845
1846
1847
1848
1849
1850
1851
1853
1853
1854
1855
1856
1857
LAKE NAME
CATARACT LAK.E
GEIST RESERVOIR
JAMES LAKE
MISSISSINEWA RESERVOIR
MONROE RESERVOIR
MORSE RESERVOIR
WAWASEE LAKE
WEBSTER LAKE
WHITEWATER LAKE
WINONA LAKE
WESTLER LAKE
WITHER LAKE
LAKE MAXINKUCKEE
TIPPECANOE LAKE
DALLAS LAKE
OLIN LAKE
OLIVER LAKE
SYLVAN LAKE
HOVEY LAKE
VERSAILLES LAK.E
BASS LAKE
CROOKED LAKE
LAKE JAMES
LONG LAKE
PIGEON LAM:
MARSH LAKE
HAMILTON LAKE
MEDIAN
TOTAL f
37
27
73
12
67
?3
94
67
19
50
50
50
77
85
62
94
100
4
31
8
42
81
88
0
37
15
58
I 9)
( 71
I 191
( 3)
( 17)
( 6)
I 24)
( 17)
( 5)
< 12)
( 12)
( 12)
( 20)
( 22)
( 16)
< 24)
( 26)
( 1)
( 8)
< 2)
< 11)
( 21)
( 23)
( 0)
< 9)
( 4)
( 15)
MEDIAN
INO>*li N
15
35
42
4
69
0
85
62
19
27
54
50
81
88
58
23
46
96
38
31
77
100
92
12
8
73
65
( 41
( 9)
( 11)
( 1)
I 18)
< 0)
( 22)
( 161
( 5)
( 7)
( 14)
< 13)
( 21)
< 23)
< 15)
( 6)
( 12)
1 25)
I 10)
( 8)
( 20)
( 26)
( 24)
( 3)
( 2)
( 19)
( 17)
500-
MEAN SEC
31 <
IS (
b8 (
a <
54 (
12 (
96 (
62 (
23 (
38 (
65 (
50 (
85 (
92 (
69 (
81 I
88 (
27 (
0 (
4 (
19 (
77 1
100 (
44 (
44 (
35 (
73 (
8)
4)
15)
2)
14)
3)
25)
16)
6)
10)
17)
13)
22)
24)
18)
21)
23)
7)
0)
1)
5)
20)
26)
11)
11)
9)
19)
MEAN
CHLORA
62
12
50
38
73
4
88
54
19
58
65
42
85
77
69
92
100
8
0
27
23
81
96
35
46
15
31
( 16)
I 3)
( 13)
I 10)
( 19)
I 1)
( 23)
I 14)
I 5)
( 15)
< 17)
I ID
( 22)
I 20)
( 18)
( 24)
( 26)
1 2)
( 0)
( 7)
( 6)
< 21)
( 25)
( 9)
I 12)
( 4)
I 8)
15-
MIN DO
35 (
92 (
35 (
35 (
35 (
35 (
85 (
35 <
35 (
35 (
35 (
35 <
35 (
35 (
35 (
73 (
79 (
79 (
96 (
88 (
100 (
35 (
35 (
35 (
35 (
35 (
35 (
0)
24)
0)
0)
0)
0)
22)
0)
0)
0)
0)
0)
0)
0)
0)
19)
20)
20)
25)
23)
26)
0)
0)
0)
0)
0)
0)
MEDIAN
D1SS ORTHO P
37
62
65
8
69
58
98
81
42
52
37
52
98
85
31
92
88
23
12
15
46
75
75
0
27
4
19
( 9)
( 16)
( 17)
( 2)
I 18)
( 15)
( 25)
( 21)
( 11)
( 131
( 9)
I 13)
( 25)
( 22)
( 8)
I 24)
( 23)
( 6)
I 3)
( 4)
( 12)
( 19)
( 19)
( 0)
( 7)
( 1)
( 5)
1NJEX
NO
217
243
323
105
367
132
b46
361
157
260
3U6
279
461
462
324
455
501
237
177
173
307
449
48o
126
HI
177
281
-------�
LAKES RANKED BY iNut* NOS.
RANK LAKE CODE LAKE NAME INDEX NO
1 1836 nAHAStE LAKE 546
2 1847 'OLlVtlR LAKE 501
3 1853 LAKE JAMES 486
4 1844 T1PPECANOE LAKE 462
5 1843 LAKE MAMNKUCKEE 461
6 1846 OLUl LAKE 455
7 1852 CROOKEO LAKE «49
8 1828 MONROE RESERVOIR 367
9 1837 HEaSTER LAKE 361
10 1845 DALLAS LAKE 324
11 1817 JAMES LAKE 323
12 1B51 BASS LAKE 307
13 1841 KESTLER LAKE 306
14 1857 HAMILTON LAKE 281
15 1842 WITMER LAKE 279
16 1840 WINONA LAKE 260
17 1811 GEIST RESERVOIR 243
18 184B SYLVAN LAKE 237
19 1805 CATAkACT LAKE 217
20 1855 PIGEON LAKE 197
21 1856 MARSH LAKE 177
22 1849 HOVEY LAivE 177
23 1850 VERSAILLES LAKE 173
24 1839 WHITEWATER LAKE 157
25 1829 MOHSE RESERVOIR 132
26 1854 LONG LAKE 126
27 1827 MISSISSINEWA RESERVOIR 105
-------�
APPENDIX B
CONVERSION FACTORS
-------�
CONVERSION FACTORS
Hectares x 2.471 = acres
Kilometers x 0.6214 = miles
Meters x 3.281 = feet
-4
Cubic meters x 8.107 x 10 = acre/feet
Square kilometers x 0.3861 = square miles
Cubic meters/sec x 35.315 = cubic feet/sec
Centimeters x 0.3937 = inches
Kilograms x 2.205 = pounds
Kilograms/square kilometer x 5.711 = Ibs/square mile
-------�
APPENDIX C
TRIBUTARY FLOW DATA
-------�
TRIBUTARY FLOW INFORMATION FOR INDIANA
03/29/76
LAKE CODE 1844
LAKE TIPPECANOE
SUB-DRAINAGE
TRIBUTARY AREAISQ KM)
1844A1
1844A2
1B44C1
18442Z
292.7
144.8
134.2
10.6
i OF LAKE (SO KM> 292,
JAN
3.77
1.82
1.68
0.119
FES
4.25
2.09
1.94
0.150
MAR
5.86
2.92
2.71
0.221
.7
APR
5.55
2.76
2.55
0.204
MAY
3.65
1.80
1.67
0.130
NORMALISED FLOWS(CMS)
JUN JUL AUG
2.72
1.35
1.25
0.099
1.68
0.83
0.76
0.059
0.71
0.32
0.29
0.017
SEP
0.62
0.29
0.27
0.018
OCT NOV
0.69 1.44
0.32 0.71
0.29 0.66
0.018 0.051
DEC
2.55
1.28
1.19
0.099
MEAN
2.78
1.37
1.27
0.098
SUMMARY
TOTAL
SUM OF
DRAINAGE AREA OF LAKE =
SUB-DRAINAGE AREAS =
292.7
289.6
TOTAL FLOW
TOTAL FLOW
IN =
OUT =
32.93
33.49
MEAN MONTHLY FLOWS AND DAILY FLOWS(CMS)
TRIBUTARY MONTH YEAR MEAN FLOW DAY
1844A1
1844A2
1844C1
6
7
a
9
10
12
1
2
3
4
5
6
8
9
10
1 1
12
1
2
3
4
5
6
7
a
9
10
11
12
1
2
3
4
5
73
73
73
73
73
73
74
74
74
74
74
73
73
73
73
73
73
74
74
74
74
74
73
73
73
73
73
73
73
74
74
74
74
74
FLOW DAY
FLOW DAY
FLOW
5.409
1.710
1.665
0.532
0.524
2.588
6.031
7.192
8.778
5.097
4.049
2.662
0.821
0.263
0.261
0.5?7
1.280
2.973
3.568
4.33?
2.520
2.002
2.4S1
0.794
0.765
0.244
0.241
0.490
1.186
2.764
3.285
4.021
2.336
1.858
9
14
11
15
13
15
22
2
2
13
19
9
11
15
13
16
15
19
2
2
13
19
9
14
11
15
13
16
15
22
2
2
13
19
6.541
1.133
1.246
0.453
0.283
2.549
4.927
10.562 16
7.334 16
6.031
5.805
3.228
0.623
0.224
0.139
0.396
1.274
1.869
5.239 16
5.239 16
2.973
2.860
3.002
0.510
0.566
0.207
0.130
0.368
1.161
2.265
4.842 16
3. 370 16
2.775
2.fr(S2
5.493
10.704
2.832
5.295
2.520
4.899
-------�
TRIBUTARY FLOW INFORMATION FOR INDIANA
03/29/76
LAKE CODE 1844
LAKE TIPPECANOE
MEAN MONTHLY FLOWS AND DAILY FLOWS(CMS)
TRIBUTARY MONTH YEAR MEAN FLO* DAY
1844ZZ
6
7
8
9
10
11
12
1
2
3
4
5
73
73
73
73
73
73
73
74
74
74
74
74
0.195
0.062
0.059
0.020
0.020
0.040
0.093
0.218
0.261
0.311
0.184
0.147
9
14
11
15
13
16
15
19
2
2
13
19
FLOW DAY
0.238
0.042
0.045
0.017
0.011
0.031
0.093
0.139 22
0.396 16
0.266 16
0.218
0.210
FLOW DAY
FLOW
0.178
0.198
0.396
-------�
APPENDIX D
PHYSICAL and CHEMICAL DATA
-------�
STORET RETRIEVAL DATE 76/03/30
41 19 46.0 085 46 47.0 3
TIPPECANOE LAKE
18085 INDIANA
05179?
DATE
FROM
TO
73/05/03
73/08/04
73/10/13
DATE
FROM
TO
73/05/03
73/08/04
73/10/13
TIME DEPTH
OF
DAY FEET
14 00 0000
14 00 0004
14 00 0020
14 00 0032
14 05 0000
14 05 0005
14 05 0012
14 35 0000
14 35 0005
14 35 0015
14 35 0024
TIME DEPTH
OF
DAY FEET
14 00 0000
14 00 0004
14 00 0020
14 00 0032
14 05 0000
14 05 0005
14 05 0012
14 35 0000
14 35 0005
14 35 0015
14 35 0024
00010
MATER
TEMP
CENT
13.2
13.2
12.9
11.9
24.7
23.6
23.4
19.8
19.5
19.0
18.4
00665
PHOS-TOT
MG/L P
0.026
0.017
0.019
0.022
0.016
0.019
0.016
0.026
0.016
0.019
0.023
00300
DO
MG/L
9.
9.
9.
7.
7.
6.
5.
3.
32217
2
4
1
7
1
0
4
6
00077 00094
TRANSP CNDUCTVY
SECCHI FIELD
INCHES MICROMHO
120 495
500
500
500
417
411
410
110 380
380
380
384
11EPALES 2111202
0036 FEET DEPTH CLASS 00
00400 00410 00610 00625
PH T ALK NH3-N TOT KJEL
SU
8.20
8.20
8.20
8.20
8.40
8.30
8.30
8.30
8.00
7.80
CAC03
MG/L
200
201
201
200
167
168
168
171
171
174
171
TOTAL
MG/L
0.070
0.060
0.060
0.060
0.090
0.070
0.070
0.090
0.110
0.140
0.160
N
MG/L
0.800
0.600
0.700
0.700
0.900
0.800
0.700
1.200
0.900
0.800
0.900
00630
N02&N03
N-TOTAL
MG/L
1.200
1.000
0.100
1.100
0.110
0.110
0.120
0.050
0.060
0.070
0.100
00671
PHOS-DIS
ORTHO
MG/L P
0.006
0.004
0.002
0.003
0.006
0.009
0.004
0.022
0.013
0.012
0.013
CHLRPHYL
A
UG/L
4.
9.
2.
8
2
9
-------�
STORET RETRIEVAL DATE 76/03/30
184402
41 19 12.0 085 45 08.0 3
TIPPECANOE LAKE
18085 INDIANA
051792
DATE
FROM
TO
73/05/03
73/08/04
73/10/13
DATE
FROM
TO
73/05/03
73/08/04
73/10/13
TIME DEPTH
OF
DAY FEET
14 40 0000
14 40 0004
14 40 0015
14 40 0028
14 25 0000
14 25 0005
14 ?5 0015
14 25 0027
IS 00 0000
15 00 0005
15 00 0015
15 00 0020
15 00 0030
TIME DEPTH
OF
OAT FEET
14 40 0000
14 40 0004
14 40 0015
14 40 0028
14 ?5 0000
14 ?5 0005
14 25 0015
14 25 0027
15 00 0000
15 00 0005
15 00 0015
15 00 0020
15 00 0030
00010
WATER
TEMP
CENT
13.4
13.3
13.3
13.3
25.6
24.3
23.2
14.0
19.6
19.6
19.5
19.3
15.5
00665
PHOS-TOT
MG/L P
0.025
0.028
0.025
0.027
0.016
0.016
0.016
0.013
0.019
0.018
0.019
0.019
0.030
00300
DO
MG/L
9.7
9.4
9.2
9.8
8.0
7.0
8.0
7.8
6.0
0.0
32217
CHLRPHYL
A
UG/L
5.5
9.6
4.3
00077 00094
TRANSP CNOUCTVY
SECCHI FIELD
INCHES MICROMHO
96 500
500
500
500
426
413
412
383
108 376
377
377
379
385
11EPALES 2111202
0032 KEET DEPTH CLASS 00
00400 00410 00610 00625
PH T ALK NH3-N TOT KJEL
SU
8.20
8.30
8.30
8.30
8.50
8.40
8.10
7.40
8.30
8.30
8.30
8.10
7.60
CAC03
MG/L
203
204
200
203
168
166
168
198
164
164
163
165
187
TOTAL
MG/L
0.060
0.050
0.050
0.050
0.060
0.060
0.080
0.130
0.070
0.060
0.060
0.100
0.420
N
MG/L
0
0
0
0
1
0
0
0
1
0
0
0
1
.800
.600
.600
.800
.000
.800
.900
.900
.000
.800
.900
.900
.300
00630
N02&N03
N-TOTAL
MG/L
1.000
1.100
1.100
1.000
0.060
0.060
0.090
0.710
0.050
0.040
0.040
0.050
0.030
00671
PMOS-OIS
ORTHO
MG/L P
0.003
0.002
0.002
0.002
0.003
0.003
0.002
0.002K
0.009
0.010
0.010
0.010
0.011
K VALUd KNOHN TO 6E.
LESS THAN INDICATED
-------�
APPENDIX E
TRIBUTARY DATA
-------�
P.ETWIEVAL DATE 76/03/30
41 19 14.0 085 47 38.0 4
TIPPECANOE KlVEk
IB 7.5 LEESbOKG
0/LAKE TlPPECAuOE 051792
PO 6P-DG IN OSwEOO
211120<4
OOCO FEtT DEPTH CLASS 00
DATE
FrtOM
TO
73/06/09
73/07/14
73/08/11
73/09/15
73/10/13
73/12/15
74/01/22
74/02/02
74/02/16
74/03/02
74/u3/16
7'./0'./13
74/05/19
00630 00625
TIME DEPTH N02Mvi03 TOT KJEL
OF N- TOTAL N
DAY FEET
13
07
11
14
10
08
15
11
10
09
09
09
15
S5
55
00
05
50
50
00
20
50
20
20
?7
15
MG/L
0
0
(j
0
0
0
0
0
I
(i
1
1
1
.690
.033
.023
.012
.033
.192
.H5u
.560
.600
.890
.260
.340
.120
MG/L
1.
1.
1.
0.
0.
0.
0.
0.
1.
1.
1.
1.
].
600
320
680
960
980
900
400
500
000
600
POO
800
300
00610
NM3-N r
TOTAL
Md/L
0 .
G.
0.
0.
Q.
J.
r\
•j •
0.
0.
0 .
0.
0 .
0.
066
022
04h
031
105
160
052
020
030
020
040
035
050
00671
Jri05-OIb P
OPTHO
MG/L
0.
0.
0.
0.
0.
c.
0.
0.
c.
0.
0.
0.
0.
p
005*
005K
007
006
J2P
005K
005
005
005
005K
005
005
010
00665
HOb-TOT
MG/L P
0.0 ?0
0.030
0.027
0.025
0.0*0
0.025
0.015
C.020
0.045
0.025
0.025
0.030
f- VALUu KNOWN fO HC.
-------�
STOKET RETRIEVAL DATE 76/03/30
181 Ml and 1U44A2
41 19 50.0 0^5 44 02.0 4
TIPPECANGE RIVE*
18 7.5 N WEBSTEK
O/JAMES LAKE 051792
BANK OFF PENINSULA IN BETwEEN THE LAKES
11EPALES 211120'+
0000 FEET DEPTH CLASS 00
DATE
FROM
TO
73/06/09
73/07/14
73/Ort/ll
73/09/09
73/10/13
73/11/10
73/11/16
73/12/15
74/02/02
74/02/16
74/03/02
74/03/16
74/04/13
74/05/19
(>0630 00625
TIME DEPTH N02^N03 TOT KJEL
OF N-TOTAL N
DAY FEET
13
07
11
13
10
12
12
09
11
10
09
09
U9
K
50
45
30
50
40
30
54
30
00
40
05
00
27
10
MG/L
0
0
0
0
0
0
0
0
1
1
u
1
1
1
.520
.013
.010K
.022
.011
.270
.034
.156
.260
.900
.460
.430
.200
.680
MG/L
2.
1.
0.
1.
0.
1.
0.
0.
1.
1.
1.
3.
2.
1.
IOC
380
960
050
900
250
950
900
100
700
900
300
200
100
00610 00671 00665
NH3-N PHOS-DIS PHOb-TOT
TOTAL OWTHO
MG/L
0.
c.
0.
o.
0.
0.
r>.
a.
0.
0.
0.
0.
0.
0.
052
016
021
040
028
168
231
168
060
050
230
06U
060
040
MG/L
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
p
OOb
005*
005K
007
005
007
008
010
015
015
005K
005
010
MG/L P
0.020
0.020
0.015
0.025
0.030
0.04U
0.026
0.025
0.060
0.095
O.OS5
0.030
0.025
0.030
K VALUE rsNOWN 1U BE
LtbS THAN IMOIC'.TEO
-------�
STORE! RETRIEVAL DATE 76/03/30
I844dl
41 19 30.0 085 46 25.0 4
UNNAMED STREAM
18 7.5 LEESBURG
T/LAKE TIPPECANOE 051792
STANTON RO ttROG .3 MI SE OF STONY RIDGE
11EPALES 2111204
0000 FEET DEPTH CLASS 00
DATE
FROM
TO
73/06/09
74/03/02
74/03/16
74/04/13
74/05/19
TIMF. DEPTH
OF
DAY FEET
14 10
09 ?5
09 15
09 41
14 00
00630
N02NN03
N-TOTAL
MG/L
0.0?5
0.064
0.060
0.004
0.02S
00625
TOT KJEL
N
MG/L
?.600
1.300
1.500
1.800
3.100
00610
NH3-N
TOTAL
MG/L
0.098
0.030
0.025
0.050
0.190
00671
PHOS-DIS
ORTHO
MG/L P
0.140
0.050
0.020
0.035
0.055
00665
PHOS-TOT
MG/L P
0.200
0.210
0.075
0.065
0.065
-------�
STORE! RETRIEVAL DATE 76/03/30
1844C1
41 IB 30.0 085 44 10.0 4
G9ASSY CKEEK
18 7.5 N WEBSTER
T/LAKE TIPPECANOE 051792
500 N HO dhiDG NEAR PUBLIC FISHING SITE
11EPALES 2111204
0000 FEET DEPTH CLASS 00
DATE
FROM
TO
73/06/09
73/07/14
73/08/11
73/09/15
73/10/13
73/11/16
73/12/15
74/01/22
74/02/02
74/02/16
74/03/02
74/03/16
7W04/13
74/05/19
00630 00625
TIME DEPTH N02S.N03 TOT KJEL
OF N-TOTAL N
DAY FEET
12
07
10
13
11
12
10
14
10
11
08
08
08
14
45
?0
35
15
05
25
00
45
35
00
35
?5
45
45
MG/L.
1.
0..
0.
0.
0.
0.
0.
0.
2.
2.
2.
2.
1.
1,
000
120
022
010K
012
084
216
460
640
520
400
500
920
340
MG/L
2.
1.
2.
1.
1.
1.
0.
0.
0.
1.
1.
1.
1.
1.
310
680
000
100
000
500
600
500
800
000
200
600
200
700
00610 00671 00665
NH3-N PHOS-DIS PHOS-TOT
TOTAL ORTHO
MG/L
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
060
080
132
030
042
210
056
020
025
025
030
015
020
045
MG/L P
0
0
0
0
0
0
0
0
0
0
0
0
0
0
.005K
.006
.005K
.006
.009
.005K
.012
.005K
.025
.015
.015
.015
.010
.005
MG/L P
0.030
0.040
0.040
0.037
0.040
0.03?
0.025
0.015
0.050
0.045
0.065
0.075
0.010
0.070
K VALUE KNOWN TO BE
LESS THAN INDICATED
-------� |