Transcript Slide 1
Water chemistry overview
4 Oct 2001
• Announcements
– Canoe trip!!
– Exam next Wednesday
– College certified drivers?
• Today's lecture
– The idea of budgets
– Factors influencing chemical composition of
freshwater
– Some important ions
Budgets
Wind-blown
particles
Precipitation
Evaporation
Surface Inflow
Groundwater
discharge
Internal
cycling
Sedimentation
Groundwater
recharge
Surface
Outflow
Internal cycling driven by
Internal
cycling
• Seasonal changes in
biological demand
• Food web dynamics
• Seasonal changes in the
chemical environment
(usually oxygenated/not
oxygenated)
• Seasonal weather
changes
• Availability of limiting
nutrients
(Aquatic) Biogeochemistry
Biogeochemistry is chemistry in an environmental
context that considers the biology, geology, and
chemical interactions of elements.
Biogeochemistry focuses on the cycling of
substances between living (biotic) and non-living
(abiotic) components of ecosystems.
(see Schlesinger, W.H. 1997 Biochemistry for more information about
biogeochemistry)
Salinity
Salinity: summed concentrations of the major
cations (+) and anions (-) in the water (mg/liter
or meq/liter)
Major ions = concentrations > 1mg/liter
Conductivity (specific conductance): surrogate
measure of salinity, measures the ease by which
an electrical current passes between two
electrodes submersed in the water
(microSiemens (S)/cm at 25C)
Total dissolved solids (TDS): dry a filter of the
water sample; TDS= change in weight of filter
containing "stuff" in the water. (not accurate)
Factors determining the occurrence of
an element
1.
Occurrence and forms of elements in water
1. Solubility
2. Disassociation
2. Major source pools
1. Atmosphere (dry/wet deposition, etc)
2. Lithosphere (rocks)
3. Biosphere (humans…)
3. Biological demand (e.g. limiting elements)
Liebig's Law of the Minimum:
C
H
O
P K
N
Environment
100
50 50
5
10 25
Organism
50
25 25
5
1
20
Lithosphere contribution to major ions
Other terms
•
•
"Soft water" low salinity (~conductivity) often
in drainages with acidic igneous rocks (e.g.
granite)
"hard water" high salinity, due to large
concentrations of carbonate (CO3=), usually
from the the drainage of calcareous deposits
(e.g., limestone)
Proportional occurrence controlled by:
• Types of minerals in the area
• Atmospheric inputs
• Evaporation vs precipitation
CaHCO3
NaCl
Dominant ions
High
Salinity (TDS) (mg/l)
Precipitation or runoff
Low
Ion concentration (salinity) lake space
• Note: simplification
that works best at
global scale
• At small spatial
scales, precipitation,
evaporation, and
climate are similar,
so differences in
geology predominate
Dominant ions
• On average…
Ca2+ > Mg2+ > Na+ > K+
HCO3- > SO42- > Cl• Mostly rock-weathering
• In rich agricultural systems, NO3- can be
important (> 1mg/liter)
• P,N,Fe and trace elements (micronutrients) are
biologically important (although unimportant in
terms of total ions)
Exceptions
• Ocean-derived spray and rain increase Na+ >
Mg2+
• Rock-weathering sequence is less applicable to
small drainages (local precipitation)
• Acidification leads to H+ > Al ions > Ca2+ >
Mg2+
• Local applications of road salt (NaCl) and
fertilizers increase SO4-, Cl-, NO3- and decrease
HCO3• Inter-year variation and climatic signals (=
changes in evaporation rates or precipitation)
Changes in ions
• Conservative ions: little change over time (Mg2+,
Na+, K+)
• Dynamic ions: concentrations are influenced by
organism metabolism (HCO3-, SO4-, Si, Fe, Ca2+,
P, N) ==> Biological demand
Calcium (Ca2+)
• From rocks
• Critical for membrane ion exchange
• Can limit the distribution of organisms that use Ca2+
in building exoskeletons or shells
(e.g. crayfish uncommon at [Ca2+]< 2 ppm)
• Interacts with CO3- (carbonate) to form CaCO3 (=
whiting or marl) in the presence of high levels of
photosynthesis
(loss of CO2)
Annual Calcium distributions
Silica
• From rocks (igneous)
• Found in many forms
• High biological demand, primarily from diatoms (to build
frustule), also sponges and some macrophytes
Diatom (algae) frustules
Distribution of silica (Si) under
stratified conditions
Annual Silica
Oligotrophic
hardwater
lake
Question of the day:
Given the above isopeth plot of calcium distributions in Wintergreen Lake,
1. plot the Ca conc. vs. depth profile for mid-August
2. relative to that Ca profile, sketch in plausible temperature and oxygen profiles (say
max O2 is 8 mg/l and max temp is 25 oC)
3. give a plausible explanation(s) as to the mechanisms that increase calcium
concentration in the water column during the winter months.