Many of our customers have commented that pond consultations are the most valuable service we offer! Our biologists will meet with you on site to discuss your pond concerns, collect physical, chemical, and biological data on your pond, and recommend management strategies. A professional pond consultation is the best place to start on the road to a healthy pond!
We will cover a wide range of management areas relating to your aquatic resource. Areas include:
|Water Quality Monitoring||Sediment Analysis||Aquatic Plant Identification|
|Oxygen Levels||Total Solids||Native and exotic plant species|
|Nutrient Loading||Percent organics||Density and abundance ratings|
|Turbidity||Depth of soft sediment|
|Nuisance Aquatic Growth||Nutrient content|
|Heavy metal and toxicity levels|
|Algae Analysis||Management Programs||Water Testing & Analysis|
|Species ID||Aquatic plant management and control||Understanding water quality parameters|
|Algal Challenge||Nutrient reduction techniques|
|Toxicity Testing||Nuisance algae management|
|Incorporating "beneficial" biological mirco-organisms and enzymes|
|Fishery management and assessments|
|Erosion control and structure failures|
The following list of definitions is intended to give you a basic understanding of the results derived from analysis of water samples collected from your lake or pond. For a more detailed discussion of your results and their management implications, please contact your biologist at Wisconsin Lake & Pond Resource (866-208-0724).
Alkalinity is a measure of the amount of carbonates, bicarbonates and hydroxide present in water. Alkalinity is determined by soil and bedrock characteristics. Lakes and ponds fed by groundwater from limestone aquifers tend to have high alkalinity. High alkalinity is often associated with high algae and aquatic plant production. Low alkalinity (< 25 mg/l) waters are susceptible to acid rain.
Ammonia is a nitrogen compound that is produced by microbial decomposition of organic matter. Ammonia is rapidly converted to nitrate in the presence of dissolved oxygen. Sudden increases in ammonia may indicate pollution from fertilizers, manure or septic systems. Concentrations above 0.03 mg/l may be toxic to fish and other aquatic organisms.
Carbon dioxide is present in water as a dissolved gas. It is essential to the survival and growth of aquatic plants and algae. Carbon dioxide concentrations increase as dissolved oxygen decreases. High carbon dioxide concentrations may inhibit the ability of fish to utilize available oxygen. Concentrations in surface water are usually less than 10 mg/l, although groundwater concentrations may be much higher.
Chloride occurs naturally in lakes and ponds, and may fluctuate seasonally with runoff patterns. High levels of chloride (> 10 mg/l) however, may indicate contamination from septic systems, fertilizers, animal wastes or road salts. At normal levels chloride is not toxic to aquatic life, but it may become toxic at higher concentrations.
Dissolved oxygen is one of the most important parameters in aquatic ecosystems, as most aquatic organisms depend on dissolved oxygen for survival. Oxygen is produced by aquatic plants in the process of photosynthesis. Supersaturation (>100%) may even occur during algae blooms. However plants, and microbes that digest dead plant matter, also consume oxygen. Thus, increased plant production increases the likelihood of oxygen depletion (anoxia). The most important source of oxygen in aquatic environments is atmospheric diffusion, but because oxygen diffuses into water rather slowly, mixing through wave action or current is essential for oxygenation of water. This is why small ponds with limited wind fetch are most susceptible to anoxia.
High plant or algae production, or heavy nutrient loading can lead to oxygen depletion or anoxia. Most common fish species require at least 4 mg/l dissolved oxygen for survival. Few species can survive less that 2 mg/l. When anoxia (<1 mg/l) occurs at the sediment layer, phosphorus is released from sediments – fueling algae blooms. Toxic gases such as ammonia, methane and hydrogen sulfide are also released from bottom sediments under anoxic conditions.
Hardness relates to the presence of Magnesium (Mg++) and Calcium (Ca++) ions in water. Waters with total hardness from 0-60 mg/l are termed soft, from 60-120 mg/l medium hard, from 120-180 mg/l hard, and > 180 mg/l very hard.
Nitrate is a nitrogen compound that is important for plant growth. Nitrate plus ammonia concentrations exceeding 0.3 mg/l may lead to nuisance algae blooms. Nitrate concentrations exceeding 10 mg/l pose a health risk to infants and expectant mothers. High nitrate levels may indicate pollution from fertilizers, animal wastes or septic effluent.
Phosphorus (phosphate) is an important growth nutrient for plants. Phosphorus concentrations are commonly the limiting factor in plant production in aquatic environments. Thus even small additions of phosphorus to a lake or pond may cause dramatic increases in plant and algae growth. Orthophosphate concentration is a measure of soluble phosphorus that is readily available to plants. Concentrations above 30 ug/l (0.03 mg/l) may lead to nuisance algae blooms. Concentrations above 100 ug/l suggest nutrient pollution.
pH is the negative logarithm of the hydrogen ion concentration. pH serves as a ready indicator of the acidity or basicity of water. A pH of 7 is neutral. Less than 7 is considered acidic. Greater than seven is considered basic or alkaline. Preferred pH ranges for most fish is 6-8. Few fish survive below 5. High plant production may elevate pH above 8.
Silica, or silicon dioxide, is found in all natural waters. Silica is a major nutrient for diatomaceous algae. High diatom populations are often associated with high silica concentrations. Normal values may range from 0 – 75 mg/l.
Sulfide occurs in groundwater and sometimes in lakes or ponds. Hydrogen sulfide may occur naturally as a result of microbial decomposition under anoxic conditions. Hydrogen sulfide produces a “rotten egg” smell. Its presence in a lake or pond is highly toxic to fish. Sulfide concentrations may also indicate pollution from sewage or industrial wastes, particularly from paper manufacture.