Interactions
of pH, Carbon Dioxide,
Alkalinity
and Hardness in Fish Ponds
William A. Wurts
and Robert M. Durborow*
Water
quality in fish ponds is affected by the interactions of several chemical
components. Carbon dioxide, pH,
alkalinity and hardness are interrelated and can have profound effects on pond
productivity, the level of stress and fish health, oxygen availability and the
toxicity of ammonia as well as that of certain metals. Most features of water quality are not
constant. Carbon dioxide and pH
concentrations fluctuate or cycle daily.
Alkalinity and hardness are relatively stable but can change over time,
usually weeks to months, depending on the pH or mineral content of watershed
and bottom soils.
pH and carbon
dioxide
The
measure which indicates whether water is acidic or basic is known as pH. More precisely, pH indicates the hydrogen ion
concentration in water and is defined as the negative logarithm of the molar
hydrogen ion concentration (-log [H+]).
Water is considered acidic when pH is below 7 and basic when pH is above
7. Most pH values encountered fall
between 0 and 14. The recommended pH
range for aquaculture is 6.5 to 9.0 (Figure 1).
Fish
and other vertebrates have an average blood pH of 7.4. Fish blood comes into close contact with
water (1- or 2-cell separation) as it passes through the blood vessels of the
gills and skin. A desirable range for
pond water pH would be close to that of fish blood (i.e., 7.0 to 8.0). Fish may become stressed and die if the pH
drops below 5 (i.e., acidic runoff) or rises above 10 (e.g., low alkalinity
combined with intense photosynthesis by dense algal blooms-phytoplankton or filamentous
algae).
Pond
pH varies throughout the day due to respiration and photosynthesis. After sunset, dissolved oxygen (DO)
concentrations decline as photosynthesis stops and all plants and animals in
the pond consume oxygen (respiration).
In heavily stocked fish ponds, carbon dioxide (CO2)
concentrations can become high as a result of respiration. The free CO2, released during
respiration reacts with water, producing carbonic acid (H2CO3)
and pH is lowered.
H2O
+ CO2 = H2CO3 = H+ +HCO3
Table
1 summarizes the relative changes in dissolved oxygen, CO2 and pH
over 24 hours.
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Table 1. Relative concentration changes for
dissolved oxygen, carbon dioxide and pH in ponds over 24 hours.
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Change
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Time
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Dissolved Oxygen
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Carbon Dioxide
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pH
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Daylight
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Increases
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Decreases
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Increases
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Nighttime
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Decreases
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Increases
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Decreases
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Tucker
(1984)
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Carbon
dioxide rarely causes direct toxicity to fish.
However, high concentrations lower pond pH and limit the capacity of
fish blood to carry oxygen by lowering blood pH at the gills. At a given dissolved oxygen concentration
(e.g., 2 mg/L, milligrams per liter; same as parts per million, ppm), fish may
suffocate when CO2 levels are high and appear unaffected when CO2
is low. Catfish can tolerate 20 to 30
mg/L CO2 if accumulation is slow and dissolved oxygen concentrations
are above 5 mg/L. In a reservoir or natural pond, CO2 , rarely
exceeds 5 to 10 mg/L.
High
CO2 concentrations are almost always accompanied by low dissolved
oxygen concentrations (high respiration); the aeration used to increase low
dissolved oxygen will, to some extent, help reduce excess CO2, by
improving its diffusion back into the atmosphere. Chronically high CO2 levels can be
treated chemically with hydrated lime, Ca(OH)2. Approximately 1 mg/L of hydrated lime will
remove 1 mg/L of CO2. This treatment should not be used in waters
with poor buffering capacity (low alkalinity) because pH could rise to levels
lethal to fish. Also, fish could be
endangered if hydrated lime is added to waters with high ammonia
concentrations. High pH increases the
toxicity of ammonia.
Alkalinity
The
quantity of base present in water defines what is known as total
alkalinity. Common bases found in fish
ponds include carbonates, bicarbonates, hydroxides, phosphates and
berates. Carbonates and bicarbonates are
the most common and most important components of alkalinity. Alkalinity is measured by the amount of acid
(hydrogen ion) water can absorb (buffer) before achieving a designated pH. Total alkalinity is expressed as milligrams
per liter or parts per million calcium carbonate (mg/L or ppm CaCO3). A total alkalinity of 20 mg/L or more is
necessary for good pond productivity. A
desirable range of total alkalinity for fish culture is between 75 and 200 mg/L
CaCO3.
Carbonate-bicarbonate
alkalinity (and hardness) in surface and well waters is produced primarily
through the interactions of CO2 water and limestone. Rainwater is naturally acidic because of
exposure to atmospheric carbon dioxide.
As rain falls to the earth, each droplet becomes saturated with CO2
and pH is lowered. Well water is pumped
from large, natural underground reservoirs (aquifers) or small, localized
pockets of underground water (groundwater).
Typically, underground water has high CO2 concentrations, and
low pH and oxygen concentrations. Carbon
dioxide is high in underground water because of bacterial processes in the
soils and various underground, particulate mineral formations through which
water moves. As ground- or rainwaters
flow over and percolate through soil and underground rock formations containing
calcitic limestone (CaCO3) or dolomitic limestone [CaMg(CO3)],
the acidity produced by CO2 will dissolve limestone and form calcium
and magnesium bicarbonate salts:
CaCO3 +
H2 O + CO2 = Ca+2 + 2HCO3
or
CaMg(CO3)2
+ 2H2O + 2CO2 = Ca+2 + Mg+2 + 4HCO3
The
resultant water has increased alkalinity, pH and hardness.
Alkalinity, pH and
carbon dioxide concentrations
In
water with moderate to high alkalinity (good buffering capacity) and similar
hardness levels, pH is neutral or slightly basic (7.0 to 8.3) and does not fluctuate
widely. Higher amounts of CO2
(i.e., carbonic acid) or other acids are required to lower pH because there is
more base available to neutralize or buffer the acid. The relationship among alkalinity, pH and CO2
can be determined from Table 2. The
number (factor) found in the table which corresponds to the measured pH and
water temperature is multiplied by the measured alkalinity value (mg/L as CaCO3). The product of these numbers estimates CO2
concentrations (mg/L).
For
example, Mr. Jacobs measures a pH of 7.2, a temperature of 77°F (25°C) and
total alkalinity of 103 mg/L in his catfish pond. He determines the corresponding factor,
0.124, from Table 2 and multiplies this number by the measured alkalinity, 103
mg/L. The resulting product gives him an
estimate of the CO2 concentrations in his pond:
0.1
24x
103 mg/L alkalinity = 12.8 mg/L CO2
A
prompt pH measurement within 30 minutes of water sampling is required to
minimize error when using this method.
Due to several sources of error that can occur with this method, direct
measurement of CO2 using a chemical test procedure is preferred.
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Table 2. Factors for calculating carbon dioxide
concentrations in water with known pH, temperature and alkalinity
measurements.a
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Temperatures (°C)
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pH
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5
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10
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15
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20
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25
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30
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35
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6.0
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2.915
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2.539
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2.315
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2.112
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1.970
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1.882
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1.839
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6.2
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1.839
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1.602
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1.460
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1.333
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1.244
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1.187
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1.160
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6.4
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1.160
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1.010
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0.921
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0.841
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0.784
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0.749
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0.732
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6.6
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0.732
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0.637
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0.582
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0.531
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0.495
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0.473
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0.462
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6.8
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0.462
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0.402
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0.367
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0.335
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0.313
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0.298
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0.291
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7.0
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0.291
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0.254
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0.232
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0.211
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0.197
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0.188
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0.184
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7.2
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0.184
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0.160
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0.146
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0.133
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0.124
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0.119
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0.116
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7.4
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0.116
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0.101
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0.092
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0.084
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0.078
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0.075
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0.073
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7.6
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0.073
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0.064
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0.058
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0.053
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0.050
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0.047
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0.046
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7.8
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0.046
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0.040
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0.037
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0.034
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0.031
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0.030
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0.030
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8.0
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0.029
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0.025
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0.023
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0.021
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0.020
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0.019
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0.018
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8.2
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0.018
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0.016
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0.015
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0.013
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0.012
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0.012
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0.011
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8.4
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0.012
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0.010
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0.009
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0.008
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0.008
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0.008
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0.007
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Tucker
(1984)
aFactors should
be multiplied by total alkalinity (mg/L) to get carbon dioxide (mg/L). For
practical purposes, CO2 concentrations are negligible above pH =
8.4.
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Alkalinity, pH and
photosynthesis
The
bases associated with alkalinity react with and neutralize acids. Carbonates and bicarbonates can react with
both acids and bases and buffer (minimize) pH changes. The pH of well buffered water normally
fluctuates between 6.5 and 9. In waters
with low alkalinity, pH can reach dangerously low (CO2 and carbonic
acid from high respiration) or dangerously high (rapid photosynthesis) levels
(Figure 2).
Phytoplankton
are microscopic or near microscopic, aquatic plants which are responsible for
most of the oxygen (photosynthesis) and primary productivity in ponds. By stabilizing pH at or above 6.5, alkalinity
improves phytoplankton productivity (pond fertility) by increasing nutrient
availability (soluble phosphate concentrations). Alkalinities at or above 20 mg/L trap CO2
and increase the concentrations available for photosynthesis.
Because phytoplankton use CO2 in
photosynthesis, the pH of pond water increases as carbonic acid (i.e., CO2)
is removed. Also, phytoplankton and
other plants can combine bicarbonates (HCO3) to form CO2
for photosynthesis, and carbonate (CO3-2) is released:
2HCO3 +
phytoplankton = CO2(photosynthesis) + CO3-2 +
H2O)
CO3-2
+ H2O = HCO3 + OH-
(strong base)
High
pH could also be viewed as a decrease in hydrogen ions (H+):
CO3-2
+ H+ = HCO3
or HCO3 + H+
= H2O + CO2
The
release of carbonate converted from bicarbonate by plant life can cause pH to
climb dramatically (above 9) during periods of rapid photosynthesis by dense
phytoplankton (algal) blooms. This rise
in pH can occur in low alkalinity water (20 to 50 mg/L) or in water with
moderate to high bicarbonate alkalinity (75 to 200 mg/L) that has less than 25 mg/L
hardness. High bicarbonate alkalinity in
soft water is produced by sodium and potassium carbonates which are more
soluble than the calcium and magnesium carbonates that cause hardness. If calcium, magnesium and photosynthetically
produced carbonate are present when pH is greater than 8.3, limestone is
formed. Ponds with alkalinities below 20
mg/L do not usually support good phytoplankton blooms and do not commonly
experience dramatic pH increases because of intense photosynthesis.
Hardness
Water
hardness is important to fish culture and is a commonly reported aspect of
water quality. It is a measure of the
quantity of divalent ions (for this discussion salts with two positive charges)
such as calcium, magnesium and/or iron in water. Hardness can be a mixture of divalent salts;
however, calcium and magnesium are the most common sources of water hardness.
Hardness
is traditionally measured by chemical titration. The hardness of a water sample is reported in
milligrams per liter as calcium carbonate (mg/L CaCO3). Calcium carbonate hardness is a general term
that indicates the total quantity of divalent salts present and does not
specifically identify whether calcium, magnesium and/or some other divalent
salt is causing water hardness.
Hardness
is commonly confused with alkalinity (the total concentration of base). The confusion relates to the term used to
report both measures, mg/L CaCO3.
If limestone is responsible for both hardness and alkalinity, the
concentrations will be similar if not identical. However, where sodium bicarbonate (NaHCO3)
is responsible for alkalinity it is possible to have low hardness and high
alkalinity. Acidic, ground or well water
can have low or high hardness and has little or no alkalinity.
Calcium
and magnesium are essential in the biological processes of fish (bone and scale
formation, blood clotting and other metabolic reactions). Fish can absorb calcium and magnesium
directly from the water or from food.
However, calcium is the most important environmental, divalent sale in
fish culture water. The presence of free
(ionic), calcium in culture water helps reduce the loss of other salts (e.g.,
sodium and potassium) from fish body fluids (i.e., blood). Sodium and potassium are the most important
salts in fish blood and are critical for normal heart, nerve and muscle
function. Research has shown that
environmental calcium is also required to re-absorb these lost salts. In low calcium water, fish can lose (leak)
substantial quantities of sodium and potassium into the water. Body energy is used to re-absorb the lost
salts. For some species (e.g., red drum
and striped bass), relatively high concentrations of calcium hardness are
required for survival.
A
recommended range for free calcium in culture waters is 25 to 100 mg/L (63 to
250 mg/L CaCO3 hardness).
Channel catfish can tolerate low calcium concentrations as long as their
feed contains a minimum level of mineral calcium but may grow slowly under
these conditions. Similarly, rainbow
trout can tolerate waters with free calcium concentrations as low as 10 mg/L if
pH is above 6.5. If freshwater culture
of striped bass, red drum or crawfish is being considered, free calcium
concentrations in the 40 to 100 mg/L range (100 to 250 mg/L as CaCO3,
hardness) are desirable; a value of 100 mg/L (250 mg/L calcium hardness)
matches the calcium concentration of fish blood. Tests specific for calcium hardness should be
performed on samples of the water source being considered for these animals.
A
low CaCO3 hardness value is a reliable indication that the calcium
concentration is low. However, high
hardness does not necessarily reflect a high calcium concentration. But, since limestone is common in the soil
and bedrock of the southern United States, it would be reasonably safe to
assume that high hardness measurements reflect high calcium levels.
A
CaCO3 hardness value is a reliable indication that the calcium
concentration is low. However, high
hardness does not necessarily reflect a high calcium concentration. But, since limestone is common in the soil
and bedrock of the southern United States, it would be reasonably safe to
assume that high hardness measurements reflect high calcium levels.
A
CaCO3 hardness value of 100 mg/L represents a free calcium
concentration of 40 mg/L (divide CaCO3 value by 2.5) if hardness is
caused by the presence of calcium only.
Similarly, a CaCO3 value of 100 mg/L represents a free
magnesium value of 24 mg/L (divide CaCO3 value by 4.12) if hardness
is caused by magnesium only. These
factors (2.5 and 4.12) are related to the molecular weight of CaCO3
and the difference in weights between calcium and magnesium atoms. Where hardness is caused by limestone, the
CaCO3 value usually reflects a mixture of free calcium and magnesium
with calcium being the predominant divalent salt.
Agricultural
limestone can be used to increase calcium concentrations (and
carbonate-bicarbonate alkalinity) in areas with acid waters or soils. However, at a pH of 8.3 or greater, agricultural
limestone will not dissolve.
Agricultural gypsum (calcium sulfate) or food grade calcium chloride
could be used to raise calcium levels in soft, alkaline waters. Expense might be prohibitive if large volumes
of water need treatment. Identifying a
suitable water source may be more practical.
Effects of pH,
alkalinity and hardness on ammonia and metal toxicities
Ammonia
becomes more toxic as pH increases.
Higher concentrations of the toxic form of ammonia (NH3) are
formed in basic waters; while the less toxic form, ammonium (NH4+),
is more prevalent in acidic waters.
Since alkalinity increases pH, ammonia will be more toxic in waters with
high total alkalinity. Hardness is not
typically associated with ammonia toxicity.
Metals
such as copper and zinc are commonly used around aquatic environments (tanks,
plumbing and copper sulfate). These
metals become more soluble in acidic environments. The soluble or free ionic forms of these
metals are toxic to fish. High total
alkalinity increases pH and available bases which produce less toxic or
insoluble forms of copper and zinc. High
concentrations of calcium and magnesium (hardness) block the effects of copper
and zinc at their sites of toxic action.
Therefore, copper and zinc are more toxic to fish in soft, acidic waters
with low total alkalinity.
Ideally,
an aquaculture pond should have a pH between 6.5 and 9 are well as moderate to
high total alkalinity (75 to 200, but not less than 10 mg/L) and a calcium
hardness of 100 to 150 mg/L CaCO3.
Many of the principles of chemistry are abstract (e.g.,
carbonate-bicarbonate buffering) and difficult to grasp. However, a fundamental understanding of the
concepts and chemistry underlying the interactions of pH, CO2 ,
alkalinity and hardness is necessary for effective and profitable pond
management. There is no way to avoid it;
water quality is water chemistry.
References
Boyd,
Claude E. 1979. Water Quality in Warmwater Fish Ponds. Auburn University.
Agricultural Experiment Station.
Tucker,
C.S. 1984. Carbon dioxide, in T.L. Wellborn, Jr. and J. R. MacMillian (eds) For
Fish Farmers 84-2. Mississippi Cooperative Extension Service.
