CIVE 633 - ENVIRONMENTAL HYDROLOGY

NUTRIENT LOADS TO A WATERBODY

MAJOR PHOSPHOROUS AND NITROGEN SOURCES

  • Major sources can contribute nutrients to a waterbody.

  • External nutrient sources include effluents from municipal and industrial point sources and diffuse non-point sources such as land runoff and deposition from the atmosphere.

  • Internal nutrient sources include nutrient regeneration from the bottom sediments, and groundwater seepage.

    Point sources

  • Nutrient load from municipal and industrial point sources includes the direct discharge from a treatment facility.

  • The use of detergents can result in increased P content.

  • Private waste disposal systems, urine tanks, manure stacks and runoff from silos.

  • Urban runoff through piped sewer systems.

  • Private septic tanks also exist in some urban areas.

    Diffuse (Non-point) external sources

  • Nutrients are deposited via atmospheric inputs directly onto a lake or reservoir.

  • Atmospheric nutrient deposition include both particulate and soluble forms.

  • Rural sources include land drainage from agricultural and forested areas.

  • Animal feedlots, leaking manure stacks and urine tanks can contribute nutrients.

  • Inorganic fertilizers, animal manure, and night soil.

  • Fertilizers applied at excessive rates can cause elevated nutrient concentrations.

  • Intensive forest practices such as clearcutting can increase exposure of soil and increase nutrients washed by runoff.

    Diffuse (Non-point) internal sources

  • Nitrate nitrogen is often found in large concentrations in groundwater.

  • Nutrient recycling is particularly important in shallow lakes.

  • Nitrogen fixation can be a potentially significant source of nitrogen for some lakes and reservoirs.

  • Nitrogen fixation is important in eutrophic lakes containing high P levels and large populations of blue-green algae, including nitrogen-fixing algae.

    Biological availability of nutrients

  • The soluble fraction of P and N are easily utilized by algae.

  • This fraction is termed the "biologically available" fraction.

  • Only a portion of the particulate nutrients are biologically available.

  • Only one-third of the particulate sediments may be biologically available.

  • P in municipal treatment plants is largely bioavailable.

  • As eutrophication management becomes more refined, it will become important to consider the bioavailability of nutrients.

  • Nutrient control targets should focus on bioavailable nutrients.

QUANTIFYING THE NUTRIENT LOAD

  • Quantitative information on the annual total nitrogen and phosphorous load is often sufficient for developing eutrophication control programs.

  • It is desirable to measure particulate P, soluble orthophosphate, total nitrogen, ammonia, nitrate, and if possible, organic nitrogen.

  • Waterbodies that have rapid flushing rates require more detail than annual loads.

  • Direct measurement of nutrients loads provide the most accurate estimates.

  • Unit loads are used in lieu of measurements.

  • Unit load is the quantity per nutrient per unit area per unit time.

  • The greater the runoff, the greater the quantity of nutrients transported from the watershed to the waterbody.

    Point source loads

  • Unit loads from point sources are available directly from the discharger.

  • Knowledge of similar plants or similar conditions elsewehere may help when there is no data.

  • Municipal wastewater treatment plants are estimated from per capita inputs.

  • Effective per capita P and N contributions can vary from location to location, depending on food habits.

    Diffuse (non-point) external loads

  • Caused by drainage from urban, agriculture, and forested areas.

  • Estimates from direct measurements of unit loads.

  • Nutrient concentrations vary less than flow information.

  • Particulate quantities can vary significantly with the flow.

  • Measurements should be made during high runoff.

  • Large portion is contributed by short-term high-runoff events.

  • Flow and concentration measurements are taken over a year.

  • Techniques for calculation are:

    • The average short-term load

    • The product of the average short-term flow and average short-term concentration.

    • The product of the weighted mean concentration and the annual flow.

  • Under average hydrologic conditions, a given land-use activity will export a relatively constant load of nutrients per unit area.

  • Use of nutrient export coefficients should be done with caution.

  • Wet and dry fallout from the atmosphere add nutrients to a waterbody.

  • Inputs are proportional to lake surface area.

  • Large atmospheric inputs are associated with proximity to urban areas.

  • Volatilization of ammonia nitrogen from feedlots may add to N content of the atmosphere.

    Diffuse (non-point) internal loads

  • Groundwater may be a potential source of nutrients.

  • Release of nutrients from bottom sediments can contribute significantly to the total nutrient load of a waterbody.

  • This occurs most commonly under anoxic conditions.

  • It can also occur under oxic conditions.

  • Reliable method for estimating P flux between sediments and water column involves detailed P mass-balance calculations made at monthly or smaller intervals.
 
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