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RESULTS OF TESTING LANDSPREADING OF TREATED MUNICIPAL WASTEWATER AT ST. PETERSBURG, FLORIDA
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U.S. GEOLOGICAL SURVEY
Water-Resources Investigations 78-110
Prepared in cooperation with the CITY of ST. PETERSBURG, FLORIDA
BIBLIOGRAPHIC DATA SHEET
1. Report No. 3. Recipient's Accession No.
4. Title and SubtitleRESULTS OF TESTING LANDSPREADING (^TREATED MUNICIPAL WASTEWATER AT ST. PETERSBURG, FLORIDA
5. Report Date
February 19796.
7. Authors) R. C. Reichenbaugh, D. P. Brown, and C. L. Goetz
8. Performing Organization Rept.No. USGS/WRI 78-110
9. Perfonning Organization Name and Address
U.S. Geological Survey, Water Resources Division 325 John Knox Road, Suite F-240Tallahassee, Florida 32303
10. Projeei/Task/Work Unh
12. Spoosoring Organization Name and Address
U.S. Geological Survey, Water Resources Division 325 John Knox Road, F-240 Tallahassee, Florida 32303
13. Type off Report & Period Covered
14.
15. Supplementary Notes
Prepared in cooperation with the City of St. Petersburg, Florida
16. Abstracts , , . - , ,Chlorinated secondary-treated effluent was used to irrigate a grassed 4-acre
site at rates of 2 and 4 inches per week for periods of 11 and 14 weeks, respectively. Part of the site was drained by tile lines 5 feet below land surface. Irrigation of the drained plot resulted in rapid passage of the applied wastewater through the soil and, consequently, poor nitrogen removal. The rapid percolation permitted nitrifica tion but prevented denitrification. Total phosphorus in the shallow ground water at the site increased from a maximum of 1.4 milligrams per liter before irrigation to as much as 5 milligrams per liter in the ground water 5 feet below land surface. Concen trations of nitrogen and phosphorus did not increase in ground water downgradient from the site, although increased chloride concentrations demonstrated downgradient migra tion of the applied wastewater. Prior to irrigation, total coliform bacteria were not detected in ground water at the site. After irrigation, total and fecal coliforms were detected in the ground water at the site and downgradient.
17. Key Words and Document Analysis. I7o. Descriptors
*Ground water, *Ground-water recharge, *Artificial recharge, *Wastewater disposal,*Water pollution effects, *Irrigation effects, *Bacteria, *Waste dilution, Irrigation water, Sewage disposal, Water pollution, Water table, Water reuse, Nutrients, Infiltration, Soil-water movement
7b. Identifiers/Open-Ended Terms
*Florida, *St. Petersburg, Sampling technique, Secondary treated effluent
17e. COSATI Field/Group
18. Availability Statement
No restriction on distribution
19.. Security Class (This Report)
UfrjCLASSIFJ20. Security^Claa
PageUNCLASSIFIED
21. No. of Pages 53
22. Price
FQRM NTi«.»» <««v. 10-TiJ ENDORSED BY ANSI AND UNESCO. THIS FORM MAY BE REPRODUCED USCOMM-DC
RESULTS OF TESTING LANDSPREADING OF TREATED MUNICIPAL
WASTEWATER AT ST. PETERSBURG, FLORIDA
By R. C. Reichenbaugh, D. P. Brown, and C. L. Goetz
U.S. GEOLOGICAL SURVEY
Water-Resources Investigations 78-110
Prepared in cooperation with the
CITY of ST. PETERSBURG, FLORIDA
1979
UNITED STATES DEPARTMENT OF THE INTERIOR
CECIL D. ANDRUS, Secretary
GEOLOGICAL SURVEY
H. William Menard, Director
For additional information write to:
U.S. Geological SurveyWater Resources Division325 John Knox Road, Suite F-240Tallahassee, Florida 32303
CONTENTS
Page
Abstract ........................................................... 1Introduction ....................................................... 2
Obj ectives .................................................... 2Previous investigations ....................................... 4Acknowledgments ............................................... 4
Site description ................................................... 4Hydrogeology .................................................. 5Character of the treated wastewater ........................... 12Water quality in the shallow aquifer before irrigation ........ 12
Methods of investigation ........................................... 12Results ............................................................ 16
Water-level responses ......................................... 16Water quality ................................................. 16
In the drained coastal bermuda grass plot ................ 16Under the undrained argentine bahia grass plot ........... 29Downgradient from the irrigated site ..................... 36Changes in the effluent from the drains .................. 40Changes upgradient from the irrigated site ............... 40
Summary and conclusions ............................................ 45Selected references ................................................ 46Conversion factors .................................. inside back cover
ILLUSTRATIONS
Page
Figure 1. Map showing location of area of investigation .......... 3
2. Map showing plan of the wastewater disposal site ....... 6
3. Map showing locations of the monitor wells, layout of the irrigation-pipeline network and location of the subsurface drains .................................... 7
4. Geologic sections through the shallow aquifer .......... 9
5. Map showing altitude of the water surface in the upperunit of the shallow aquifer, August 1971 ............. 10
6. Map showing altitude of the water surface in the lowerunit of the shallow aquifer, August 1971 ............. 11
7. Graphs showing rainfall, irrigation and variation of the water surface in the shallow aquifer during the 2-inches-per-week irrigation period .................. 17
8. Graphs showing rainfall, irrigation and variation of the water surface in the shallow aquifer during the 4-inches-per-week irrigation period .................. 18
9. Map showing altitude of the water surface in the upperunit of the shallow aquifer in December 1973 ......... 19
iii
ILLUSTRATIONS - Continued
Figure 10. Map showing altitude of the water surface in the lowerunit of the shallow aquifer in December 1973 ......... 20
TABLES
Page
Table 1. Chemical analyses of treated wastewater ................ 13
2. Chemical analyses of the ground water in the shallowaquifer sampled before irrigation .................... 14
3. Activities at the test site between July 1971 andJanuary 1974, including duration and intensity of irrigation and volumes of wastewater applied ......... 15
4. Chemical analyses of ground water from site CB-1 ....... 21
5. Bacterial analyses of ground water and soil from siteCB-1 .................................................. 25
6. Chemical analyses of ground water from site AB-1 ....... 30
7. Bacterial analyses of ground water and soil from siteAB-1 ................................................. 33
8. Chemical analyses of ground water from site CB-2 ....... 37
9. Chemical analyses of ground water from site CB-4 ....... 38
10. Bacterial analyses of ground water from sites CB-2 andCB-4 ................................................. 39
11. Chemical analyses of the drain effluent ................ 41
12. Bacterial analyses of the drain effluent ............... 42
13. Chemical analyses of the ground water from site BG-1 ... 43
14. Bacterial analyses of ground water and soil from siteBG-1 ................................................. 44
iv
RESULTS OF TESTING LANDSPREADING OF TREATED MUNICIPAL WASTEWATER AT ST. PETERSBURG, FLORIDA
By R. Ci Reichenbaugh, D. P. Brown, and C. L. Goetz
ABSTRACT
Chlorinated secondary-treated effluent was used to irrigate a grassed 4-acre site at rates of 2 and 4 inches per week for periods of 11 and 14 weeks, respectively. Part of the site was drained by tile lines 5 feet below land surface. Chemical and bacteriological changes in the acidic ground water in the shallow sand aquifer and in the effluent from the drains were studied.
Irrigation of the drained plot resulted in rapid passage of the ap plied wastewater through the soil and, consequently, poor nitrogen removal. The rapid percolation permitted nitrification but prevented denitrification. Thus, the effluent from the drains contained as much as 5.2 milligrams per liter nitrate-nitrogen. Irrigation of the undrained plot resulted in more extensive nitrogen removal.
Total phosphorus in the shallow ground water at the site increased from a maximum of 1.4 milligrams per liter before irrigation to as much as 5 milligrams per liter in the ground water 5 feet below land surface.
Concentrations of nitrogen and phosphorus did not increase in ground water downgradient from the site, although increased chloride concentra tions demonstrated downgradient migration of the applied wastewater.
Prior to irrigation, total coliform bacteria were not detected in ground water at the site. After irrigation, total and fecal colifonus were detected in the ground water at the site and downgradient. The ni trifying bacteria Nitrosomonas and Nitrobacter at the irrigated site were most abundant at the soil surface; their numbers decreased with depth.
INTRODUCTION
.St. Petersburg (fig. 1), on the southern tip of Pinellas County in west-central Florida, operates four secondary wastewater treatment plants that utilize the activated sludge process. The chlorinated effluent is discharged into Tampa Bay, east of the city, or to Boca Ciega Bay, west of the city. Existing treatment facilities (and expansions thereof) that discharge to Tampa or Boca Ciega Bays are required to provide advance treatment or an alternative disposal in order to comply with State regu lations.
Florida.regulations define advanced waste treatment as that which will provide an effluent containing no more than the following concentra tions: 5-day BOD (biochemical oxygen demand), 5 mg/L; suspended solids, 5 mg/L; total nitrogen as N, 3 mg/L; and total phosphorus as P, 1 mg/L. Disinfection is required to be not less than 15 minutes contact time at maximum flow, and the effluent shall have a free chlorine residual of no less than 1 mg/L or the equivalent (Florida Department of Environmental Regulation, 1976a).
The Florida Department of Environmental Regulation defines alter nate effluent disposal as a minimum of secondary treatment (90 percent removal) followed by an effluent disposal system approved by the Depart ment which will prevent any effluent from being discharged to the sur face waters of the State. Such disposal may include land disposal, deep injection wells, or combinations thereof, or other methods approved by the Department (Florida Department of Environmental Regulation, 1976b).
City officials recognized that grassed areas in the city might be sprinkler irrigated with treated wastewater, thereby reducing the irri gation demand on the area's freshwater resources and recharging the thin freshwater zone in the shallow sand aquifer underlying the peninsula. The shallow aquifer is generally unused except for lawn irrigation.
Objectives
In July 1971, the U.S. Geological Survey began an investigation of the hydrologic effects of an effluent-disposal system using sprinkler ir rigation in Pinellas County. The objectives of the investigation were to determine: (1) the chemical and bacteriological character of the treated wastewater, (2) the changes that occur in the ground water in the shallow aquifer, and (3) the practical irrigation rates.
The approach was to monitor a plot on which treated wastewater was used for sprinkler irrigation of grass. Data were collected from July 1971, before irrigation commenced, to January 1974, and Included applica tion rates, ground-water-level changes, measurement of discharge from the
82° 55' 28*15'
50' 40'
10'
28*00'
501
40'
27*35'
AREA OF INVESTIGATION
82*30'T~
BASE FROM FLORIDA STATE ROAD DEPARTMENT, FEBRUARY 1963 I! 126,720 REDUCED
Figure 1. Location of area of investigation,
area, and chemical and bacterial determinations of ground water, effluent, and soil. This report details investigation of irrigation of drained and undrained grassed plots at rates of 2 in. (inches) per week and 4 in. per week between August 1973 and January 1974.
Previous Investigations
Before July 1973, the study site was irrigated for periods of as much as 6 weeks at rates of 2, 4, and 11 in. per week. Preliminary find ings were reported by Cherry and others (1973). Data collected during these preliminary tests confirmed that high rates of effluent application required site drainage. To accomplish drainage, a network of subsurface drains was installed about 5 ft (feet) below land surface under part of the study site (fig. 3). Afterward, that part of the site was irrigated at 11 in. per week. At this higher rate, the upper water surface was within 18 in. of land surface. After 6 weeks of effluent application at 11 in. per week, effluent from the subsurface drains contained 6.2 mg/L of total nitrogen (N) and 3.0 mg/L of total phosphorus (P).
These concentrations were in excess of the limits of 3 mg/L of nitro gen and 1 mg/L of phosphorus permissible under existing Florida statutes for treated effluent discharged to surface waters. The rapid percolation of the wastewater through the shallow sandy soil did not allow time for the physical, chemical, and biochemical processes to reduce the nitrogen and phosphorus to acceptable levels.
Acknowledgments
Many personnel of the city of St. Petersburg, by their advice and actions, aided the authors. Art Day, District Conservationist of the U.S. Department of Agriculture, Soil Conservation Service, provided ad vice regarding site design. The cooperation of Dr. F. M. Wellings, Director, Epidemiology Research Center, Florida Department of Health and Rehabilitative Services, who concurrently conducted virus studies at the site, is acknowledged.
SITE DESCRIPTION
The 6.2-acre study site was located near St. Petersburg's Northwest Wastewater Treatment Plant which is near Boca Ciega Bay on the southwest side of Pinellas County (fig. 1). For the study, the site was leveled, diked, and fenced. Coastal bermuda and argentine bahia grasses were es tablished. An irrigation-pipeline network, a monitor-well network, sub surface drains, and associated drain-discharge pipe were installed.
The site was designed to permit irrigation, at differing rates, of a drained plot, an undrained plot, or the entire site. Sprinklers, 18 in. high, were placed 75 ft apart along lateral lines spaced 75 ft apart. Perforated 6-in. drains were buried 5 ft beneath the soil surface on the west part of the site. The two lateral drains were connected to a weir and discharge was routed to a submerged outfall in the lake (fig. 2).
A network of wells was constructed within and near the site (fig. 3). The network consisted of clusters of wells whose casings consisted of 2-in, diameter PVC-pipe (polyvinylchloride) terminating in slotted PVC screens 12 to 18 in. long. The clusters consisted of wells placed into augered holes 2, 5, 10, 15, and 20 ft deep. Water-level recorders were placed on two wells in the drained part of the site (well cluster CB-1). The recorders continuously monitored water levels 5 ft and 10 ft below the surface.
Wells clustered at CB-1 and CB-3 were sampled to determine water quality below that part of the site covered by coastal bermuda grass. Wells at AB-1 were likewise sampled to determine water quality below the part of the site covered by argentine bahia grass. Wells at sites CB-2 and CB-4 were sampled to determine water quality between the irrigated site and the lake. One well at site BG-1 was sampled to determine water quality outside the irrigated site.
Hydrogeology
The hydrogeology of Pinellas County has been described by Heath and Smith (1954). The sequence of marine deposits underlying the study site includes the shallow aquifer (water-table aquifer) consisting of about 50 ft of sand and shelly sand with increased proportions of clay near the bottom. The shallow aquifer is underlain by the Miocene Hawthorn Forma tion, consisting of about 100 ft of quartzose and calcareous sediment ranging in texture from sand to sandy clay. The clay content of the Hawthorn Formation is sufficient to confine the water of the underlying Floridan aquifer, the top of which is about 150 ft below land surface. The Floridan aquifer is a sequence of limestones with numerous large and very permeable, cavernous zones.. It is not locally a source of public water supply because of potential saltwater encroachment, but it is tapped by irrigation wells, small industrial supply wells, and isolated domestic (private) wells.
The Immokalee soil series (Vanatta and others, 1972), which appears at the surface of the shallow aquifer at the study site, consists of fine- to-very-fine non-calcareous acid sand (pH 4 to 5) with varying amounts of clay and disseminated organic matter. Downward from the gray-white sur face soil, the sand is increasingly stained by decaying organic materials (humate), Staining is greatest in the dark brown-to-black acid sands of the spodic horizon, commonly referred to as the organic-stain layer or hardpan, about 5 ft below land surface.
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EXPLANATION
7\ Argentine bahia grass
D Coastal bermuda grass
Figure 3. Locations of the monitor wells, layout of the irrigation-pipeline net work and location of the subsurface drains.
The spodic horizon is the zone of accumulation of water-soluble humic and fulvic acids (humate) leached over many decades from decaying surface vegetation. It consists of humate-cemented quartz sand stained or coated with dark brown organic matter that is a small percentage of the total sediment.
Swanson and Palacas (1965) reported that the organic carbon content of humate-cemented sand elsewhere in Florida varied from 0.57 to 5.42 per cent by weight and that the total organic matter ranged from 1 to 8 per cent by weight. The principal constituents in the humate (in decreasing order of concentration) are carbon, oxygen, hydrogen, nitrogen and sulfur. Analyses of the humate by the U.S. Geological Survey indicate phosphorus is present at the St. Petersburg site, though no data are available on its percentage by weight.
The mobility of the Florida humate in aqueous solutions has been des cribed as unique and intriguing by Swanson and Palacas (1965). Percolating surface water, which is weakly alkaline to nearly neutral, easily removes the material from the surficial sediments. Precipitation or floculation of the humate occurs by one or a combination of the following processes: (a) the absorption or complexing of dissolved cations such as aluminum, ferric iron or magnesium; (b) complexing with clay colloids; and (c) a lowering of pH. All of these conditions are encountered as humate in solution is carried deeper in the shallow aquifer under the site.
The poorly permeable hardpan (Cherry and others, 1973) produces two different water zones in the shallow aquifer. In this report the two water-bearing units are referred to as the upper and lower units of the shallow aquifer and the hydraulic gradient is generally downward. Other water-bearing units in the shallow aquifer, deeper than 20 ft below land surface, were not identified in this study.
Below the spodic horizon the shallow aquifer consists of various layers of sand, sandy clay, and clay to a depth of about 50 ft (fig. 4). Laboratory analysis of cores from the shallow aquifer to a depth of 50 ft shows (1) the water-storage capacity is high (effective porosity of about 35 to 40 percent); (2) pH is low (4 to 5); (3) ion^exchange capacity is less than 11 milliequivalents per 100 g (grams); (4) median grain size ranges from 0.17 to 0.21 mm (millimeters); and (5) the vertical hydraulic conductivity ranges from 1.9 ft/d (feet per day) to 30 ft/d (Cherry and others, 1973).
The water surfaces of the upper and lower units of the shallow aqui fer were mapped in August 1971 before the drains were constructed or the site irrigated (figs. 5 and 6). Altitude of the land surface is about 25 ft above mean.sea level.
SEA LEVEL
A1 B
40' J
15 II
B 1
r40'
20'
SEA LEVEL
20'
1-40'
200 400FEET
EXPLANATION
SAND-SANDY CLAY
LIMESTONE-CLAY
ORGANIC HARDPAN (Spodic horizon)
Figure 4. Geologic sections through the shallow aquifer.
30th AVENUE NORTH
UNNAMED LAKE
EXPLANATION22
WATER-LEVEL CONTOUR Shows altitude of water surface. Dashed where inferred. Contour interval I foot. Datum is mean sea level
°23.8WELL SITE
Number indicates water surface in feet above mean sea level
Lake stage 15 feet above mean sea level, estimated
26 th AVE~NUE~~NORTH
Figure 5. Altitude of the water surface in the aquifer, August 1971.
unit of the shallow
10
30th AVENUE NORTH
UNNAMED LAKE
EXPLANATION
22WATER-LEVEL CONTOUR Shows altitude of water surface. Contour interval I foot. Datum is mean sea leve
°22.0WELL SITE
Number indicate* water surface in feet above mean sea level
Lake stage 15 feet above mean sea level, estimated
26th AVENUE NORTH
Figure 6. Altitude of the water surface in the lower unit of the sha'flow aquifer, August 1971.
11
Analyses made of the treated wastewater from the plant are shown in table 1. Total nitrogen in the wastewater ranged from 8.6 to 19 mg/L and averaged 14 mg/L, chiefly as ammonia and organic nitrogen. Total phos phorus ranged from 0.9 mg/L to 3.2 mg/L and averaged 2.0 mg/L primarily as inorganic orthophosphate which averaged 1.7 mg/L. The wastewater was generally alkaline, pH ranging from 7.2 to 7.4. The chloride concentration averaged 120 mg/L and ranged from 110 to 150 mg/L. COD (chemical oxygen demand) in the wastewater averaged about 55 mg/L and varied from 48 to 60 mg/L. Based on records at the treatment plant, the 5-day BOD (biochemical oxygen demand) averaged about 12 mg/L and suspended solids averaged about 15 mg/L.
Water Quality in the Shallow Aquifer Before Irrigation
The water in the shallow aquifer was sampled prior to irrigation of the site with treated wastewater from August 1971 to February 1972. Sam ples were collected from wells 5, 10, 15, and 20 ft deep at sites CB-1 and CB-2 (fig. 3) and are considered representative of water quality throughout the shallow aquifer at th£, study site before wastewater was applied. The analyses are listed in £able 2.
Total nitrogen concentration ranged from 2.3 mg/L to 6.9 mg/L, pre dominantly in the forms of ammonia nitrogen and organic nitrogen; nitrate nitrogen was absent from the samples. Total phosphorus ranged from 0.40 to 1.4 mg/L in the shallow ground water and organic carbon ranged from 28 to 132 mg/L. Maximum chloride concentration was 26 mg/L. Total and fecal coliform bacteria were not detected in water from the shallow aquifer.
METHODS OF INVESTIGATION
The site was irrigated twice weekly for 11 weeks at 2 in. per week commencing August 1, 1973. Samples of the wastewater, ground water, and soil were collected 15, 43, and 76 days after the irrigation of the site began. The irrigation rate was increased to 4 in. per week for the ensu ing 14 weeks, and samples of the wastewater, ground water, and soil were collected 24, 52, and 94 days after the rate increase. A summary of activities at the site is shown in table 3.
About 9 Mgal (million gallons) of treated wastewater were applied to the site during the two tests. Ground water was sampled at the background well (BG-1) outside the area irrigated. Also, ground water was sampled from the drained part of the site (CB-1), from the undrained part (AB-1 and CB-3), and downgradient from the site (CB-2 and CB-4). The effluent from the drains was also sampled. All locations are shown in figure 3.
12
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Table 1. Chemical analyses of
the
treated
wast
ewat
er
[Concent
rati
ons
are reported as
milligrams
per
lite
r ex
cept
where no
ted.
All
analyses are
by the
U.S.
Geological Su
rvey
.]
ate
of
collection
o
8-1
5-7
3
9-1
2-7
3
12
-13
-73
1-2
3-7
4
AV
ERA
GE
CO cO rH
2 0
4J oT CO 4J
H ^ 0.0
1
.05
.01
0.0
0
.02
itrogen,
ammonia, otal
as N
53
4-»
7.1
6.2
16 14 11
rH
CO
4-1 0
534-1
CO
»
CO
Pi
0)
U
C?
C
M
CO
4-1
60
H
}-i53
0
4.7
2.3
3.2
2.2
3.1
CO
CO rH
CO
4J O
4J 8 00
0 H 53 12 8.6
19 16 14
hosphorus, total rtho
as P
PH
O
1.6 .7
9
2.4
2.2
1.7
hosphorus, total s P
PM
CO
1.6 .9
0
3.2
2.4
2.0
pel (X
7.4
7.3
7.4
7.2
__ _
pecific
conductance micromho
s/cm at
25°C)
C/i ^
750
750
900
810
802
T3 0) 5 O
CO
CO
H /C0
H
O CO
'
64 63 77 68
hloride
(Cl),
dissolved
0 110
110
150
110
120
hemical oxyge
n deman
d COD)
0 ' '
48 58 60 55
arbon,
organic is
solve
d
O
Tj
14 20 24 19
Table 2. Chemical analyses of
the
grou
nd w
ater
in the
shal
low aq
uife
r sa
mple
d be
fore
irrigation
[Samples collected
between August 19
71 and
February 1972.
Concentrations ar
e in
milligrams
per
lite
r except where no
ted.
All
anal
yses
ar
e by th
e U.S. Geolog
ical
Survey.]
V >
4J CX
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X a § en 51
015 2
0 510
15
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CB
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B-1
CB
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B-1
CB
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B-2
CB
-2
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4.8
4.1
4.5
4.5
__
_
fie
conductance o
mhos/cm
at
25°C)
H
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0
CD
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CO ^
10
21
53
165 86
16
01
93
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5.8
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26.0
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00
.00
gen,
ammonia,
as N
0
rHM
cd
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1 1 H
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1.6
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COZ
cd
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3.4
6.9
4.0
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O CX
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PL,
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COPL
. Cd
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01.4 .6
31.3 .4
0
143
9.9
16.0
67
76
0.00
1.7
1.8
3.9
.94
a =
Sampled
in September
1972
at CB
-3.
Table 3. Activities at
the
test
site between July 19
71 and Ja
nuar
y 19
74,
including
duration and
intensity of irrigation and volumes of
wastewater applied
Dates
7/71
to 7/
73
7/73 to 8/
73
8/1/73 to
10/18/73
10/22/73 to
1/25/74
Duration
of
period
2 years
1 month
11 weeks
14 weeks
Intensity
of
irrigation
vari
ed
vari
ed
2 in
. per wk
4 in
. per wk
Description of ac
tivi
ty
and
remarks
Construction of facilities;
numerous short-term tests
of low
rates
of ir
riga
tion
up
to
4
in.
per
wk;
exte
nded
pe
riod
of testing a
low-rate ir
riga
tion
(4 in
. per
wk
for
10 wee
ks)
and high- ra
te ir
riga
tion
(1
1 in
. pe
r wk
for
6 weeks);
evaluation of da
ta co
llec
ted;
preparation
of preliminary report (Cherry, Br
own,
St
amer
an
d Goetz,
1973); to
tal volume of wa
stew
ater
ap
plie
d was
14.7 Mgal
Sampled
grou
nd water
previous to co
mmen
cing
irrigation.
Sampled
ground water
15,
43 an
d 76
da
ys after
start
of
the
irrigation period.
Doubled
the
irrigation ra
te;
sampled
ground water
24,
52 and
94 days after
star
t of
th
e testing
period;
total
volume of
treated
wast
ewat
er ap
plie
d during the
two
irrigation periods was
9 Mg
al.
Soil and water samples were collected periodically for enumeration of bacteria. Nitrifying and denitrifying bacteria were chosen for study to evaluate nitrogen removal from the treated wastewater. Pathogen- indicating bacteria were studied in order to evaluate contamination of ground water.
Water levels in the upper and lower units (above and below the organic-^stain layer) were measured continuously during the tests at the drained part of the site, and periodically elsewhere.
RESULTS
Water-Level Responses
Hydrographs relating the irrigation and rainfall on the site, and the depths to water in the shallow aquifer under the drained and undrain- ed parts of the site for the irrigation periods are shown in figures 7 and 8.
Water levels above and below the stain layer rose in response to irrigation of the site; however, there was no marked difference in the water levels as the rate increased from 2 to 4 in. per week (figs. 9 and 10). Ponding did occur in a low area in the undrained part of the site for a short time during a rainy period in December 1975. Where present, the drains maintained the water levels about 3 ft below the soil surface throughout the tests.
Water Quality
In the Drained Coastal Bermuda Grass Plot
During the irrigation periods samples were collected from the wells at site CB-1 (fig. 3) to determine water-quality changes in the vicinity of the drained coastal bermuda grassed plot (table 4). Effects of the irrigation with treated wastewater were most prominent in ground water less than 10 ft deep.
The pH increased from less than 5 before irrigation to 5.3 to 7.5 after irrigation, more like the pH of the effluent. The pH change was limited to the 5-ft depth.
Chloride concentration increased from less than 26 mg/L at all depths to a maximum 160 mg/L at the 5-ft depth and to 140 mg/L at the 10-ft depth, but averaged 129 mg/L at both depths. Deeper than 10 ft,
16
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00
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00 C ro
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03
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00 03 ft H- o a
c <
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03H
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ftro CD i
DE
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AT
ER
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UR
FA
CE
, IN
F
EE
T
BE
LO
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LA
ND
S
UR
FA
CE
RA
INF
AL
L,
IN
INC
HE
SIR
RIG
AT
ION
. IN
IN
CH
ES
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UD
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ER
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L
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EL
oo
H-
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en
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<-l
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l l-{
ro H-
n 03 rt
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H-
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rt
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f{
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n>
en i
oo
DE
PT
H
TO
W
AT
ER
S
UR
FA
CE
, IN
F
EE
T
BE
LO
W
LA
ND
S
UR
FA
CE
R
AIN
FA
LL
,IN
IN
CH
ES
-«JO
)oi4
»oi
ro
o
oi-^o
iro
o
o
ro
IRR
IGA
TIO
N,
IN
INC
HE
S
1I
I m
1 m
SF i
O
\
m F 4
3.0
'
m
T
~-"~rororororo
->ioou)o
ro
CM
4kro
ro
ro
ro
ro
O
ro
oJ
4k
AL
TIT
UD
E
OF
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, IN
F
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AB
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EA
LE
VE
L
30th AVENUE NORTH
UNNAMEDLAKE
EXPLANATION22
WATER-LEVEL CONTOUR Shows altitude of water sur face. Dashed whtre inferred. Contour interval I foot. Datum is mean sea level
°22.6 WELL SITE
Number indicates water surface in feet above mean sea level
Lake stage 15 feet above mean sea level, estimated
26th AVENUT x 7i6R~TH
Figure 9. Altitude of the water surface in the upper unit of the shallow aquifer in December 1973.
19
30th AVENUE NORTH
UNNAMED LAKE
EXPLANATION22 -
WATER-LEVEL CONTOUR Shows altitude of water sur face. Dashed where inferred. Contour interval I foot. Datum is mean sea level
°22.2 WELL SITE
Number indicates water surface in feet above mean sea level
Lake stage 15 feet above mean sea level, estimated
I x x x x .26th AVENUE NORTH S °2f.2
Figure 10. Altitude of the water surface in the lower unit of the shallow aquifer in December 1973.
20
w7
Cnl-h rt
4s -P* to to to
h* to H1 O vo 00 -vjI I I I I I Its> H» M H« H» M OCo co cn cn to cn CoI I I I I I I**J ^J -si «vl -J -J »>J.P* CO CO CO CO CO CO
.p- .p. .p-ro
ON I ON & 4> Cn Cn. | .....O ON O to vo O
H* 10 h-» O vo 00 «vJI I I I I I I to H M H« M M O CO Co Cn Cn to cn CO I I I I I I I- J sj »sj ^J »sj -v.1 *J P- CO CO CO CO CO CO
P* Cn cn J> co £»*J I Cn O -P* OO to. I .....O O O O O O
CO CO to 10 CO J^ CO O O O O O O O
!- O> 4> to N3 VO ON O O O O O M O
!- O to CO to Cn ON
O O
P* Cn 4> (-* to -P* Cn
ON CO O -^ CO O O
H H H > Cn co
10 Cn H« O VO M H* -»J O ON VO
CO CO O
O O O CO O 00 ON
co co co co co co coN> O M 4> M O 0>
Cn
10 O
H* h-1 O to Cn J> h-1 ON ON Cn **J
to
vO ^J Cn -P* to 00 *-j ^J to 00 VO ON
00 10 O I-1 Cn 10VO
Cn -P» £» -P* 4> ON -P* Cn ON -P* Cn Cn Cn --J
CO VO 10 H CO 00 ON O O O -P* -P- vo CO
10I t_i f* t_i |-i |_i t-t | |_i (_i ^ K> fo I 00 -P* vo Cn H» ON| CO Cn H» IO O
CO CO | CO CO -P- CO CnCnl ^J ON ON ^J
^J-sj| 00--JOOO COON| sJ^JMCn
Sampling site
Depth sampled
Rate (in. per week)
Date of collection
Calcium (Ca), dissolved
Chloride (Cl), dissolved
Phosphorus, total as P
Nitrate, total as N
Nitrogen, ammonia, total as N
Nitrogen, total organic as N
Nitrogen, total as N
Carbon, organic total
PH
o0 O (D 3 rt H
0 H«
OQ
' 8on H* o H. M rt O (t
OQ i-» H'o n> P XM O
grt
H% H (D
-P-*l
I
00n o
I §l-hl-t
Ocd
zz
oW
to o
<?
en
Hi
10 10 10
H ro M o vo oo vjI I I I I I I ro H H H H H* OCO CO Cn Cn ro Cn CoI I I I I I I V! Vl Vl Vl Vl VI Vj C* U) CO CO CO CO CO
ro ho to to ro ro CO I vl en CO 4> Cn I .....o o o o o o
to ro ro
H H H H* to H* O VO 00 vlI I I I I I I10 H« H H M I-1 OCO (JJ Ln Cn to Ui COI I I I I I I^J VI Vl VI Vl VI Vl4> CO CO CO CO CO CO
I Cn CO ON M to
10 M to vl O
CO CO *- CO to M 10ro ^i ON oo ON oo to
Cnto M H to CO 00 Cn O
M 10 |-« H» 10 CO vl 00 J> 00 ON -^J O 00 O*
CO Cn Cn Cn M to vi .P- O 00
OOOOOOO OOOOOOO
b b b o b o b OOOOOOO
to to to |-« M H1 H
VIH H 00 Cn cn 00
co co co to i-> ro to oo .> ro co \o o co
toCO M
ON ON ON ON 00 CO 00 -O CO vo -P^ CO CO
VO 00 O ON ON CO ON K-1 00
co -> ro to to i-* ro Co «^l vi en CO 00 o>
vl CO CO CO CO CO
ro co vo en co vo
H I M ro (- M roON I 00 vl vl en *^Ml to co ro co
VO | vj Cn ON I-1
4> -P- Ln Cn *> ON Cn
Cn VO vi (- ON O ro
4S 4>- | Cn .> Cn 4s. . | . . . .Cn CO I vl CO vo ro
Sampling site
Depth sampled
Rate (in. per week)
Date of collection
Calcium (Ca), dissolved
Chloride (Cl), dissolved
Phosphorus, total as P
Nitrate, total as N
Nitrogen, ammonia, total as N
Nitrogen, total organic as N
Nitrogen, total as N
Carbon, organic total
pH
Hg-
I
O
CDm cooK>
JQH» o
ft n>
§COH. rt n>o w
II IIo o H H-ft COD* COO O d H« 3* <O (DCO O.
0) Q)ft I-1
c
CJ Cd
(D
sO*
to K> ro
H1 N> H O vo 00 *^lI I I I I I I NJ M I-1 H* H »-« OOJ W Ui Ui K> Cn WI I I I I I I>J «^l ^J «*J -vl ^J ^JJ> W to Oi W W W
ro 10
vo
o o03
10
10
o o
0000
o 00
VO ON
VO
Sampling site
Depth sampled
Rate (in. per week)
Calcium (Ca), dissolved
Chloride (Cl), dissolved
Phosphorus, total as'P
Nitrate, total as N
Nitrogen, ammonia, total as N
Nitrogen, total organic as N
Nitrogen, total as N
Carbon, organic total
pH
HS- !- (D
QQn o
I
iCO H« rt
O td
8.
chloride concentrations increased gradually through the period, reaching a high of 61 mg/L in December at the 15-ft depth and 46 mg/L in November at the 20-ft depth.
At the 5-ft depth, total phosphorus concentration increased to 5 mg/L after irrigation of the site began; decreased to 1.7 mg/L by the end of the 2-in.-per-week irrigation period; but increased to nearly 5 mg/L by the end of the 4-in.-per-week irrigation period. Total phosphorus in the water from 10 ft below land surface was as high as 1.6 mg/L, probably a residual effect from earlier high-rate tests on the site. Total phosphorus in water from the 15- and 20-ft deep wells was generally about the same or less than pre-irrigation values.
The most prominent effect of irrigation of the drained plot was the increase in nitrate concentrations less than 10 ft below the surface. During 11 weeks of irrigation at 2 in. per week, the nitrate concentration at CB-1 increased to a maximum 4.3 mg/L (as N) at a depth of 5 ft below the land surface, and to about 0.2 mg/L (as N) at 10 ft. After the irri gation rate was increased to 4 in. per week, nitrate concentrations in creased to as much as 15 mg/L (as N) at the 5-ft depth, and to as much as 1 mg/L (as N) at the 10-ft depth. No nitrate was detected deeper than 10 ft.
During the entire test period, the ammonia concentration in ground water from the 5-ft depth was lower than the pre-irrigation values of about 1 mg/L, as N. However, in samples from the 10-ft deep well, the ammonia concentration ranged from 3.0 to 3.6 mg/L, as N. In samples from the 15- and 20-ft deep wells, ammonia concentration was also higher than before irrigation started and increased during both tests. The increase was greater during the 4-in.-per-week test. At the end of the irrigation periods, the concentrations of organic-nitrogen in the shallow aquifer at all depths sampled were less than pre-irrigation values.
Soil samples tested during Feburary 1973 from the drained plot and from outside the irrigated site were analyzed for coliforms. The number of total coliforms within the drained plot was 45,000 MPN/g (most probable number per gram) of soil; outside the site the total coliform count was 4,900 MPN/g of soil. The fecal coliform count from within the drained plot was 420 MPN/g of soil; outside the site the fecal coliform count was less than 170 MPN/g of soil. The higher counts of coliform organisms within the test site indicate that irrigation with the treated effluent encouraged the growth of the total and fecal coliform organisms at the soil surface.
The treated wastewater contained 118 col/100 mL (colonies per 100 milliliters) total coliforms and 15 col/100 mL fecal coliforms. After irrigation commenced, both types were present in ground water from the upper unit of the shallow aquifer; total coliform concentrations ranged from 20 to 1,900 col/100 mL (table 5).
24
I
H Ol-tjft
.p* .> £* to is) to |
H1 H1 H* H1 10 H O VO 00 sj
1 1 1 II II
CO CO Cn O> to .> CO1 111 1 II
P- CO CO CO CO CO CO
Hen 10 H* to A O H 00 CO Cn 00 H
A A A A A A A
A 1 1 A.I A 1 CO | j CO j CO |0 00
(III 1 III II1 1 1 A I A 1
co co^D ^^
1 1 h-» 1 CO 1 | Ul I VO O
P* 1 1 O 1 CO OO O O O
?
Cn
hhft
£>.(>.> to to to I
H I-1 H H to p-» O VO 00 sj
1 1 1 1 1 1 1to 1 * | ' H-1 H1 r- ' O CO CO Cn O> to -P* CO
1 1 1 1 1 1 1
.p- co co co co co co
oH M 0
to O O sj ov H-1 O 2 O O O O CO O O O
arj
gHM
A A A A AH« 00 H« CO H H1 H
X*N
IO A ^
O 1 1 CO | O O HO O O O C
CO
p>(D d
n 0 to n o P* CO
II 1 O H ft VO I 1 1 < O00 | I ^*J I C^ ^D *OO Cn vo O _ ^O O O O 0 O f 0*
N ' Q)0* H*
0*" 6 CO 0
1 1 VO 1 sj w O*)-> 1 1 CO | O O fDJN i i o i o o n0 000
S±te sampled
Depth sampled
Rate (in. per week)
Date of collection
Total coliformcolonies per 100 mL
Fecal coliformcolonies per 100 mL
Nitrosomonas
Nitrobacter
Denitrifiers
H
H-1 to
Cn
11
^ g*
H 0H* ft
(D ft) hj gu.p*
ft)»- M
CO P)(D 0 CO P)
P) ^l-» COfl> n>CO Q*
V^ Qi-h
ft3* W 0) rt
Oc S S CO O-
o § (0 rt O (DH* H O
OQ P>H. s O D.P>H CO
0CO H.C p-1
5 I-h
vrf O
L, eCOH- rt<D
ow1M
Table 5.
Bac
teri
al analyses of
ground wat
er a
nd so
il f
rom
site CB-1 -
cont
inue
d
ISJ
*XJ <y i_| O.
cd 00 Q)
jj
H CO
CB
-1
CB
-1
,54 0) S 3
^
^40)
a)
iH
O.
t3
*cd
cs
00
«rl
V« X
43 4J
a)
p,
. 4J
cu
cdC
3 P
^
15. ft
2 2 2 4 4 4
20
ft
2 2 2 4 4 4
a o H 4J O 0) rH rH O O M-l O (!)
4J cd 0
7-0
3-7
38
-14
-73
9-1
2-7
310-1
6-7
311-1
5-7
312-1
4-7
31
-24
-74
7-0
3-7
38
-15
-73
9-1
2-7
310-1
7-7
311-1
6-7
312-1
4-7
31
-24
-73
g o o gl 1
0 fc
y_l
(j) H
O
u
O
COO
(!) H
H
acd
o
4J.
rH
C
0E-
« 0
46
083
12
00
.j 1 o o ef i
O
M
09(M
O)
cd H
O.
fiiH
O
O
00
go
cu
5 H
CO
^
a o
cd o
V4O
iH
4
JOJ
O
«H
pp|
^
*g
^
<1
M CU 4J O cd o M H S3 _
<1
<30
<
30<1
.<!
<1
<30
<
30
232
70 <!
20 2157
0 23 <1 5
-
<1 .
<1
<30
1
50
<1_
_
<1
<30
<
30<1
<1
<30
<30
<1 <1
<1
<30
1
50
0
CO ^1 <u tl_t
rl
M 4J <r4 a <u Q
40
00
<30
70-
-. 28
0
<30
00 <30 <
30
40
Table 5. Bacterial analyses of ground w
ater
and
soil from si
te CB
-1 -
cont
inue
d
d 0) rH O.
cd 00 0) 4-1
H
CO
CB
-1
T3 0) rH S*
§ 09 .C o. OJ
0
50
ft
Q> g M 0) O.
* a H v«^
0) 4J s ¥J 2 2 2 4 4 4
c o H
4-1 U 0) rH O 0 M-l O 0) 4J cd
Q
7-0
3-7
38-1
5-7
39-1
2-7
310-1
7-7
311-1
6-7
312-1
4-7
31-2
4-7
4
0 MH
H rH O a r-l
CCJ
4J O
H -
ti -d
o
o
o
o e(_)
K<
O
M
CO0)
M
-l 0)
Cd
ex
-HO
- C
rH
0oo
o
oo
6
0)
00)
0 H
«H
CO
C
rH
C
0O
C
d O
rl
rH
0
rH
4JO
0)
O
-H
0
PL
, 0
!S
<1
<1
.
'
- -
COM
M
0)
0) U
iH
o
MHcd
-H
>0
M
O
4-1
M
*H4-
* fj
H
0)
5S
0
40
00
;
SOIL
CB-1
CB-1
0 ft
1 ft
7-06
-73
10-1
8-73
1-28-74
7-06
-73
10-1
8-73
1-28-74
(Val
ues
are most pr
obab
le n
umbe
r pe
r gram o
f sample (dry w
eigh
t))
45,000
260,
000
2,600,000
4600
12,000,000
260,000
48,000,000
>26,000,000
260,
000
2,600,000
2,70
0,00
0 500,000
9,70
0,00
0 1,
000,
000
12,000,000
460,000
2,70
0,00
0 2500
Table 5. Bacterial an
alys
es o
f go
und
wate
r and
soil fr
om s
ite
CB-1 -
continued
to 00
*o 0) rH Du ft 3 00 0) 4J H w
CB
-1
TJ 0) H (X g cd 00 f^ 4J Cu 0) Q 2 ft
<o 0) [J J^ <u (X q H V S 0) 4_
l{r
trf 2 4
a o H 4J O 0) rH , |
O o U-I o Q)
4-1 cd Q
7-0
6-7
310-1
8-7
31
-28
-74
g 0 o e!_
°
Irf
i|_l
g)*H
CU
rH O
Cd0
<U H
rH
ticd
o4J
rH
O
0H
0
O o el 1
O
MM
-l <U
H
P-
rH O
09O
(!) H
rH
Ccd
O
0
rH0)
O
f*4
O
CO cd g o Q CO o 4J H *
COH
M
a> a)
O
«Hcd
4*4
.0
MO
4J
4_)
. £j
*r4
d)^?^
-
r*\
<33
0 82,0
00
330
180,0
00
30
,00
0
53
,00
028
00
2800
49
0
CB-1
3 ft
7-06
-73
<360
52,000
<360
Nitrosomonas, Nitrobacter, and denitrifying bacteria were much more numerous in the soil than in ground water (table 5). Concentrations of these organisms were greatest near the surface and decreased with depth. The presence of the nitrifying aerobacters (Nitrosomonas and Nitrobacter) is likely the source of the great amount of nitrate in the shallow ground water.
Under the Undrained Argentine Bahia Grass Plot
Under the undrained argentine bahia grassed plot, the most pronounced chemical changes in ground water from site AB-1 (fig. 3) were increases in pH and total phosphorus in the upper 10 ft of the aquifer, and an increase in chloride and total coliform concentrations at all depths (tables 6 and 7), compared to pre-irrigation conditions at sites CB-1 and CB-2 (table 2).
Chloride concentrations in ground water from the 2-, 5-, 10-, and 15-ft depths of AB-1 were similar to that in the applied wastewater, but varied throughout both tests from a low of 83 mg/L in a sample from a depth of 2 ft, to a high of 220 mg/L in a sample from a depth of 5 ft.
The pH increased in ground water from the 2- and 5-ft depth but re mained similar to pre-irrigation values in samples from the 10- and 15-ft depth. The high pH (usually greater than 6) in samples from the 20-ft deep well probably reflects the increased amounts of shell fragments, as evidenced by increased calcium in water from that depth (see table 6).
At the start of the tests, total phosphorus was higher than pre-irri gation levels in the ground water from 2 ft and 5 ft below land surface, probably as a result of previous periods of irrigation of the site with wastewater. The total phosphorus concentration in ground water from 2 ft below land surface increased to more than 5 mg/L by the conclusion of the tests. The total phosphorus concentration also increased at the 5-ft depth during the latter part of the irrigation period of 4 in. per week. At a depth of 10 ft or greater, total phosphorus decreased or remained less than the maximum pre-irrigation value of 1.4 mg/L.
Nitrate concentration was negligible in ground water from all depths except in a sample collected from the 2-ft deep well during the middle of the irrigation period of 4 in. per week. The sample contained 0.76 mg/L of nitrogen.
Ammonia concentrations in ground water from the 2- and 5-ft deep wells were similar to pre-irrigation concentrations throughout the irrigation period. However, in ground-water samples from 10 and 15 ft below land sur face, ammonia increased.
Organic-nitrogen and organic-carbon concentrations in most of the ground-water samples from all depths below the land surface at site AB-1 remained near pre-irrigation levels at the conclusion of the test. Thus,
29
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Sampling site
Rate (in. per week)
Date of collection
Calcium (Ca), dissolved
Chloride (Cl), dissolved
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Sampling site
Depth sampled
Rate (in. per week)
Date of collection
Calcium (Ca) , dissolved
Chloride (Cl) , dissolved
Nitrogen, ammonia, total as N
Nitrogen, total organic as N
Nitrogen, total as N
Carbon, organic total
pH
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Depth sampled
Rate (in. per week)
Date of collection
Calcium (Ca) , dissolved
Chloride (Cl), dissolved
Phosphorus, total as P
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Nitrogen, ammonia, total as N
Nitrogen, total organic as N
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Sampling site
Depth sampled
Rate (in. per week)
Date of collection
Total coliformcolonies per 100 mL
Fecal coliformcolonies per 100 mL
Nitrosomonas
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Tabl
e 7.
Bac
teri
al analyses o
f ground w
ater
an
d so
il f
rom
site
AB-
1 -
cont
inue
d
CO
o 0) iH O. a § (0 <u 4J H CO
"0 V tH CX 1 CO 00 .13 U ex, (U P
s~\ J* 0) S > M (U O, C3 «H N
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a o o firt
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ues
are
mos
t pro
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le n
umbe
r
AB
-1
AB
-1
AB
-1
AB
-1
0 ft
1 ft
2 ft
3 ft
2 2 4 _ 2 2 4 _ 2 4 _
7-0
5-7
38
-17
-73
10-1
8-7
31-2
8-7
4
7-0
5-7
38
-17
-73
10-1
8-7
31
-28
-74
7-0
6-7
38
-17
-73
1-2
8-7
4
7-0
5-7
3
' __ __ __
-.
__
--
__
per
gr
am
98,0
00
290,
000
600,
000
5,0
00,0
00
410
11,0
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120,0
00
29,0
00
<350
<39
0012,0
00
510
of
sam
ple
, d
ry
190,
000
25,0
001
5,0
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0,0
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110,
000
<360
06,2
00,0
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5100
1,7
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,00
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12,0
00
5500
wei
ght)
980,
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27,0
0013
0,00
046
00
25,0
00 --16
0,00
011,0
00
2400
12,0
00 510
Tabl
e 7. Bacterial analyses of ground^water an
d soil from site AB-1 - continued
Ln
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Tj
<U
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fat §.
CO
CO03
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AB
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38
-15
-73
9-1
2-7
31
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6-7
31
1-1
5-7
312
-14
-73
1-2
3-7
4
7-0
5-7
38
-15
-73
9-1
2-7
31
0-1
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6-7
312-1
4-7
31
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-74
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l 1
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270 8
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f-<1 <1 <1 <1
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'. '
210 --
irrigation of the undrained plot resulted in more extensive nitrogen re moval from the wastewater than did irrigation of the drained plot.
Concentrations of total coliform bacteria (table 7) increased over pre-irrigation concentrations in ground water from all depths. Concen tration of total coliforms was highest (1,300 col/100 mL) in ground water from the 2-ft deep well and generally decreased with depth. Fecal coli form bacteria were detected in several samples from the 2-ft and 5-ft depths with counts ranging from 110 col/100 mL to less than 1 col/100 mL. Below 5 ft, no fecal coliforms were detected.
In both soil and water samples from site AB-1, numbers of nitrifying and denitrifying bacteria (table 7) were greater than concentrations at site BG-1 (table 14), outside the site. Soil samples had the highest con centrations of nitrifying and denitrifying bacteria (tables 7 and 14).
Downgradient from the Irrigated Site
Data from well sites CB-2 (tables 8 and 10) and CB-4 (tables 9 and 10) were used to evaluate changes in ground water downgradient from drained and undrained plots, respectively (fig. 3) by comparison with pre- irrigation data from wells CB-1 and CB-2. Samples were collected from depths of 5, 10, and 15 ft before and during irrigation periods.
Downgradient from the drained plot at CB-2, chloride concentration Increased and ranged from 90 to 140 mg/L in all samples from the 5- and lO^ft depths (table 8). There were no pronounced changes in pH, total phosphorus, total nitrogen or organic carbon. Total nitrogen, total phosphorus and organic carbon concentrations were generally lower than pre-irrigation levels.
Downgradient from the undrained plot, at site CB-4, samples from all depths indicated small increases in pH, and pronounced increases in chlor ide concentration. Ammonia concentrations in samples from the 10- and 15-ft deep wells increased slightly compared to pre-irrigation levels, but all other constituents sampled were near or below pre-irrigation values (table 9).
Downgradient from both plots, total colnorm organisms were detected in samples from 5-, 10- and 15-ft deep wells (table 10). Also, fecal col iforms were detected in ground water 10 ft below land surface.
36
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Depth sampled
Date of collection
Calcium (Ca), dissolved
Chloride (Cl), dissolved
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Nitrogen, ammonia, total as N
Nitrogen, total organic as N
Nitrogen, total as N
pH
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Sampling site
Depth sampled
Date of collection
Calcium (Ca) , dissolved
Chloride (Cl), dissolved
Phosphorus, total as P
Nitrate, total as N
Nitrogen, ammonia,total as N
Nitrogen, total organic as N
Nitrogen, total as N
Carbon, organic total
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Date of collection
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Samples of the effluent from the subsurface drains underlying part of the site were collected at a weir downgradient from the site (table 11 and fig. 3) during the irrigation periods. Compared to the applied wastewater, the drain effluent was generally lower in pH, higher in con centrations of total phosphorus and organic carbon, and similar in chlor ide concentration.
The greatest differences between the treated wastewater and the ef fluent from the drain were in concentrations of nitrogen species. For example, the effluent from the drains contained more nitrate and less ammonia, organic nitrogen and total nitrogen (table 11). Total nitrogen in the effluent from the drains doubled (from a maximum of 2.0 to 5.2 mg/L) after the irrigation rate was increased from 2 to 4 in. per week.
Total coliform counts in the drain effluent ranged from 35 to 7,000 col/100 mL during the irrigation periods (table 12). Fecal coliform counts in the drain effluent ranged up to 547 col/100 mL. Pathogen-indicating bacteria moved downward through 5 ft of soil and into the drains. The number of bacteria in the effluent from the drains was higher than the number in the applied wastewater, indicating that conditions at the soil were favorable for the growth and multiplication of at least some of the total coliform organisms.
Concentrations of Nitrosomonas, Nitrobacter, and denitrifiers in creased markedly over the corresponding values in ground water from the 10-ft deep background well BG-1 (table 14). Samples of the drain efflu ent contained high concentrations of Nitrosomonas and Nitrobacter.
Changes Upgradient from the Irrigated Site
The ground water in the shallow aquifer outside the site was sampled at site BG-1 before and during the irrigation periods. The data are shown in tables 13 and 14. The major changes in water quality detected during the entire study were decreases in total phosphorus and organic carbon.
Total coliform organisms were detected in samples from the well BG-1 twice during the irrigation periods (table 14). The concentrations were 50 col/100 mL and 11 col/100 mL. Fecal coliform organisms were not de tected in samples from the well.
Nitrosomonas and Nitrobacter concentrations were 400 MPN/100 mL or less at the well (BG-1), outside the site, during both irrigation periods. Concentrations of denitrifiers were less than 3,000.
40
p>IIort
IP*
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Sampling site
Date of collection
Rate (in. per week)
Calcium (Ca), dissolved
Chloride (Cl), dissolved
Phosphorus, total as P
Nitrate, total as N
Nitrogen, ammonia, totalas N
Nitrogen, total organic as N
Nitrogen, total as N
Carbon, organic total
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Depth sampled
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SUMMARY AND CONCLUSIONS
The wastewater applied to the study site was alkaline, and increased the pH of the shallow ground water. As soil water pH increased after ir rigation commenced, the humate was dissolved and mobilized by changes in the physical-chemical nature of the soil-water environment. The humate, because of its solubility in alkaline waters, is taken to be a source of some of the phosphorus in the effluent from drains under part of the site, and also a source of the phosphorus in ground water throughout the site. Effects such as increases in nitrogen and carbon, if they occurred, were probably masked by the high concentration of nitrogen and carbon in the applied wastewater, and the biological transformations naturally occurring in the soil system.
Nitrate is a very soluble form of nitrogen and is mobile in the ground water. However, under anaerobic (reducing) conditions, denitri fying bacteria are capable of rapidly reducing large amounts of nitrate to nitrogen gases. Several other complex reactions involving organic nitrogen compounds and small amounts of inorganic compounds occur in the soils concurrently, but are of minor importance in consideration of the major nitrogen-removal mechanisms.
Irrigation of the drained plot resulted in poor nitrogen removal owing to the rapid passage of the wastewater through the.upper 5 ft of drained soil and into the drains. In that zone, the major phenomenon (especially at the 4-in.-per-week rate) was extensive oxidation of am monia and some organic nitrogen in the wastewater to nitrate, where it was detected in high concentrations (as much as 15 mg/L) in the shallow ground water near the drains, and in the drain effluent. Rapid percola tion prevented complete denitrification.
Conversely, irrigation of the undrained plot at a rate of as much as 4 in. per week resulted in more extensive nitrogen removal. Under that plot, no nitrate was detected. Ammonia concentrations increased to a max imum of 3.8 mg/L at a depth of 15 ft below land surface, and total nitro gen increased to a maximum of 6.9 mg/L at the same depth.
The undrained plot of argentine bahia grass was saturated with water to within a few inches of the surface during irrigation. Irrigation of 4 in. per week, coupled with only moderate rainfall, was nearly the maxi mum amount of water that the plot could accept weekly without extensive surface ponding. But the absence of drains and the frequent cyclic sat uration of the soil in that plot slowed the percolating wastewater, per mitting the processes of sorption, nitrification, and denitrification to remove nitrogen more effectively.
At no time during or after irrigation did total nitrogen or phos phorus concentrations increase in ground water downgradient from either plot. The minor changes in concentrations of ammonia and organic nitro gen noted are not attributed to either soil processes or to dilution.
45
The sprinkler irrigation of the grass-covered site, using chlori nated, secondary-treated wastewater, resulted in an enrichment of the nitrifying and denitrifying bacteria on the site. High concentrations of the aerobic, nitrifying bacteria, Nitrosomonas and Nitrobacter, were detected within the irrigated area. The concentrations of nitrifying and denitrifying bacteria were highest at the soil surface and decreased great ly below a depth of 2 ft, implying a large scale conversion of ammonium to nitrate in the soil within 2 ft of land surface.
Comparisons of chloride concentrations showed that dilution by native ground water was not sufficient to explain the reduction in total nitro gen in the upper 10 ft of the shallow aquifer. Therefore, denitrification may account for a significant part of the reduction in total nitrogen in wastewater applied to the site.
Prior to irrigation with the treated wastewater, total coliforms were not detected in ground-water samples from the site. After irrigation there were total coliforms and fecal coliforms in the soil and ground water throughout the site. Coliforms were also detected downgradient from the site.
This experience suggests that an irrigation rate of 4 in. per week was about the maximum desirable at the study site, and that installation of drain tiles to permit increased irrigation rates probably will result in inadequate reduction of nitrogen and phosphorus in the applied waste- water.
SELECTED REFERENCES
Cherry, R. N., Brown, D. P., Stamer, J. K., and Goetz, C. L., 1973, Hydro- biochemical effects of spraying waste-treatment effluent in St. Petersburg, Florida: reprinted from the proceedings of a 1973 work shop on landspreading municipal effluent and sludge in Florida, spon sored by the Institute of Food and Agricultural Science, University of Florida, Agricultural Experiment Station, 21 p., 2 figs., 4 tables-
Environmental Protection Agency, 1975, National interim primary drinking water regulations: Federal Register, v. 40, no. 248, p. 59566- 59588.
Florida Department of Environmental Regulation, 1976a, Chap. 17-3, Supp. 69, Pollution of Waters: State of Florida.
____ 1976b, A proposed rule on land application of domestic wastewaters,Third draft: December 14, 1976, State of Florida.
Heath, R. C., and Smith, P. C., 1954, Ground-water resources of Pinellas County, Florida: Florida Geological Survey Report of Investigation 12, 132 p.
46
Reichenbaugh, R. C., 1976, Effects of pasture irrigation with sewage ef fluent near Lakeland, Florida: U.S. Geological Survey Water-Resources Investigation 76-108, 56 p.
Swanson, V. E., and Palacas, J. G., 1965, Humate in coastal sands of northwest Florida: U.S. Geological Survey Bulletin 1214-B, 29 p.
Vanatta, Earl S., and others, 1972, Soil survey of Pinellas County, Florida: U.S. Department of Agriculture, 64 p.
47
CONVERSION FACTORS
For use of those readers who prefer to use metric units rather than U.S. inch-pound units, the conversion factors for the terms used in this report are listed below:
U.S. inch-pound units Multiply by To obtain metric units
inch (in.) 25.4 millimeter (mm)
foot (ft) 0.3048 meter (m)
mile (mi) 1.609 kilometer (km)
acre 0.4047 hectares (ha)
3 gallon (gal) 0.0038 cubic meter (m )
foot per day (ft/d) 0.3048 meter per day (m/d)