9/4/02
Lake Background Chemistry
pH, Conductivity, Calcium and Buffering, Humic Materials, and Clay Minerals
Lake Water Chemistry
• Major ions - those in higher concentrations - determine background ecology of lakes
• Measurement is often indirect - by pH, buffering (alkalinity), or conductivity, rather than concentrations of specific chemicals
• Nutrient chemicals are also important, but considered later
pH = -log10[H+]
Increases in H+ cause decreases in pH.
• pH < 5 and > 9.5 are toxic to lake organisms
– pH < 5 frees toxic Al+++ from clay and other minerals (silicates with AlO4---)
– Low pH from organic (humic) acids is less toxic, because humics bind Al +++
– pH > 9.5 converts NH4+ to toxic NH3
pH Frame of Reference Fig. 6-4
Factors Affecting pH in Lakes
• Solution from air and biotic fluxes of CO2
– photosynthesis, respiration, decay
• Buffering chemicals from rock and soil weathering
• Inflows of humic (and other) acids from peaty soils or coniferous forest litter
Conductivity (Electrolyte Strength)
• Water’s transmission of electrical current
– Units of micro-Siemens (mS)
– Specific Conductance is corrected for temp.
• Main electrolytes:
Ca++, Mg++, Na+, K+ ; HCO3-, Cl-, SO4--
• Conductivity often correlates with pH buffering, because Ca++ and HCO3- are dominant ions.
Buffering (Alkalinity)
• Resistance to changes in pH when H+ or OH- is added
• Buffers are chemicals that react with and remove H+ or OH-
• Most important buffer in lakes is bicarbonate
HCO3- + H+ ® H2CO3 ® H2O + CO2
HCO3- + OH- ® H2O + CO3--
Divalent Cations
• Especially Ca++ + Mg++
– Stabilize HCO3- in solution
– In combination with dissolved CO2
• Buffer water by precipitation / solution
• Make water “hard” and slightly alkaline
– Combine with detergents
Background Conditions
• Catchment rocks and soils weather to control inflowing water chemistry
• Sedimentary rocks (limestone, dolomite) yield Ca++, Mg++, and HCO3- ... strong buffering
• Our granitic rocks and lateritic soils yield Na+, Mg++, SiO2, Cl-, and SO4-- ... weak buffering
• Peaty soils yield dissolved humics which are acidic and chelate divalent ions
Saline Lakes
• Endorheic basins, dry climates … no outflow
• Salinities > 0.5 ppt (brackish), > 40 ppt (hypersaline), often extremely alkaline
• Restricted biota, often endemic
• Low productivity
• Examples: Caspian, Aral, and Dead Seas, Great Salt Lake, Mono Lake
Humic Materials
• Leached from acidic or waterlogged soils
• Yellowish-brown solutes with low pH
– Humic acids, humins, fulvic acids
• Chelate divalent cations, nutrients, toxic metals
• UV photolyses humics into free radicals
– Toxic to biota, consume oxygen
• Absorb visible and IR, heating the water
Ecological Tendencies
• Lakes with medium strong buffering are often productive and stable
– Extremely high buffering suppresses algae
• Lakes with weak buffering may or may not be productive, but are always unstable
• Humic (“dystrophic”) lakes are unproductive and stable
Effects of Suspended Clay
• Platelets of silica with various metallic ions
– especially Al+++, Fe+++, Na+, Mg++
• Surfaces have electrical charges
– Adsorb NH4+ and PO4--- (nutrients)
– May serve as nutrient reservoirs to plankton
– Scavenge nutrients from water to sediments
• Scatter light and interrupt line of sight
• Interfere with zooplankton filter-feeding
Clay Structure
1