Wetland Water Budget & Hydrology PDF

Summary

This document provides an overview of wetland water budgets, discussing the influence of precipitation and surface flow, defining hydrological terms, and exploring the impact of groundwater, evapotranspiration, and tides. It also covers vegetation and nutrient cycling and how hydrology influences these processes.

Full Transcript

1. Describe the components of a wetland water budget and their interrelationships

Water budget is the balance between the inflows and outflows

The equation is

Water volume change = net precip + surface water inflows + ground water inflows -
evapotranspiration - surface water outflows - ground water outflows +- tidal in/outflow

Inflows - precipitation, surface flow, groundwater

Outflows - evapotranspiration, surface outflows, groundwater outflows

2. Discuss the influence of precipitation and surface flow to wetland water budgets

Gross precipitation - liquid or solid water falling onto earths surface

Net precipitation - amount of water that reaches the surface (throughfall and streamflow)

Interception - water that is intercepted by vegetation or buildings

Throughfall - water that falls through or drips from leaves

Streamflow - water that runs down the main stem of vegetation, usually trees

Infiltration - water that enters the soil

Surface flow - water that travels overland and not infiltrating the soil; may be dispersed (sheet)
or in channels (stream)

Overland flow - travels in sheet over surface, often creates rivulets

Streamflow - more permanent, often channelized

Flood pulse - seasonal or episodic flood flow, may or may not be hydrologically connected
outside floor window

Riparian wetlands - wetland areas adjacent to rivers or streams, occasionally flooded by those
waters

3. Define key hydrological terms and concepts

Recharge wetland - water level in wetland is higher than water table; water flows out

Discharge wetland - water lever of wetland is lower than the water table; water flows in
Flow-through wetland - groundwater inflows at one location but outflows at another

Novitski groundwater flow patterns

Surface water depression - little groundwater outflow, low permeability soils, water table
separated from wetland

Surface water slope - little groundwater outflow, adjacent to lakes, rivers, streams, water
table usually below, may be connected

Groundwater depression - high groundwater inflow, low point/deep depression, water
table connected to coarse soils

Groundwater slope - high groundwater inflow, slopes/hills, water table connected to
surface, seeps/springs

Evaporation - water that vaporizes from water or soil

Transpiration - water that passes through vascular plants to atmosphere

Seiches - wind tides, common in Great Lakes, periodic fluctuations in nontidal inland wetlands
adjacent to lakes

4. Explain the influence of groundwater, evapotranspiration and tides to wetland
water budgets

Groundwater affects water budget cuz it plays a factor in where the wetland gets its water from
(see Novitski flow patterns).

Evapotranspiration affects water budget because it is water leaving the wetland (vegetation
decreases with the loss of water.

Tides create zonation that is periodic and predictable, bring stressors (submergence, saline
intrusion, and anaerobic conditions but brings subsidies (removal of excess salts, reestablishing
aerobic conditions, nutrient pulse. Seiches also affect it by changing water levels

5. Discuss the four main principles underscoring the importance of hydrology on
wetland structure and function
1. Hydrology leads to a unique vegetation composition but can limit or enhance diversity
a. Selection for water-tolerant spp, exclusion of flood intolerant spp, diversity
decreases by long flooding duration & high energy waters & flowing/periodic
hydrology, diversity increases when niches are created such as ecotones, riparian
corrido movement and tidal zonation
2. Primary productivity and other ecosystem functions in wetlands are often enhanced by
flowing conditions and a pulsing hydroperiod and are often depressed by stagnant conditions
a. Bogs clog (less diverse, not much water flow, dominated by sphagnum moss)
b. fens flush (more diverse, water flow flushes nutrients, dominated by graminoids,
forbs, shrubs, stunted conifers)
3. Accumulation of organic material in wetlands is controlled by hydrology through its
influence on primary productivity, decomposition and export of particulate organic matter
a. Wetlands accumulate and decompose organic material (hydrology modifies
chemicals, moisture, nutrients and temperature, which all influences
decomposition rates)
b. Wetlands export organic material (isolated wetlands have less export, wetland
connected to flowing water have more export
4. Nutrient cycling and availability are both significantly influences by hydrologic conditions
a. Nutrients enter and leave via hydrology, internal cycling depends on productivity
and decomposition, beaver marsh = high productivity, bog = low productivity
b. Nutrient transformations, availability to plants, and loss to atmosphere are all
influenced by hydrology, N & P are more available in anaerobic conditions (no
oxygen) or flooded soils

6. Identify techniques for studying wetland hydrology

Determine the following:

Water levels - recorders/loggers, staff gauge

Evapotranspiration - thornthwaite equation, evaporation pans, diurnal water-level fluctuation

Precipitation - rain gauges, weather station info

Surface flow - water-level following events, stream weir

Groundwater - piezometers/wells, models, online data

7. Generate hypothetical water budgets for unfamiliar wetlands

Identify inflows and outflows, make a diagram?

8. Define key soil terms and concepts

Hydric soils - wetland soils, formed under conditions of saturation, flooding or ponding long
enough during the growing season to develop anaerobic conditions in the upper part
 9. Describe the 2 main types of wetland soil

Organic soils - more than 20-35% organic material

Peat - undecomposed organic soil, identification of plant forms is possible

Muck - highly decomposed organic soil material, identification of plant forms impossible

Wetland organic soils: organic:clay content, ≥ 18% organic carbon if mineral fraction ≥ 60%
clay, ≥ 12% organic carbon in mineral fraction has no clay, proportional organic carbon
(12-18%) if mineral fraction has 0-60% clay

Mineral soil - all other soils; less than 20-35% organic material

10. Explain how organic soils differ from mineral soils

11. List soil features that characterize wetland soils

Organic - origin of plant material (mosses, graminoids (sedges, rushes and grasses), woody
debris), decomposition state/humification (slower in flooded and cold conditions, plant organic
compounds leached into water)

Mineral - redoximorphic features (characteristics that develop in mineral wetland soils that allow
for their identification, formed by reduction, translocation, and/or oxidation of iron and
manganese oxides, mediated by micro-biological process (microbes, plant cellular processes)

12. Explain redox potential and its importance in wetland soils

Redoximorphic feature development requires: sustained anaerobic conditions, sufficient soil
temp >5°C, and organic matter. reduced matrices and redox depletions, gleization/gleying - black
or gray occasionally greenish or blue gray soil color (indicates semipermanently - permanently
 flooded soils, caused by reduces iron and manganese leaching from soil, aka redox depletions),
clay depletions - clay is removed along root channels and redeposited as clay coatings on soil
particles below; oxidized rhizosphere (plants transport oxygen to roots, excess oxygen diffuses to
the soil, iron is oxidized along these small roots); redox concentrations (mottles) - orange reddish
brown (iron) or dark reddish brown/black (manganese) spots in otherwise gray (gleyed) soil
matrix, indicates variable hydrology, remain long after draining.

Redox potential and wetland soils - all soils are complex matrix of minerals/rock, soil organic
matter, clay, air, water, bacteria, roots, fungal hypha, air/pore spaces fill with water during
flooding (oxygen diffusion 10,000x slower in water, flooding -> rapidly anaerobic = reduced
soil, very thin oxidized layer remains at surface

Redox potential - measure of the electron availability in a solution, degree of reduction, wetland
soil indicator

Oxidation - uptake of oxygen, removal of hydrogen or lose electron

Reduction - losing oxygen, gaining of hydrogen or electron

OIL RIG (oxidation is loss, reduction is gain of electron)

Redox importance in wetland soils

a) Nutrient cycling - regulates availability of key nutrients for plant growth and health
b) Microbial activity - regulates microbial communities which influences productivity and
decomposition
c) Climate change - regulates carbon sequestration and greenhouse gas release to atmosphere
d) Water quality - regulates the generation and transformation of toxic compounds (pollutants,
metals and cyanobacteria)
13. Characterize wetland soils using field indicators

Check for redoximorphic features, sulfate reduction (rotten egg odor), organic matter
accumulation, color (munsell color wheel: hue value/chroma)

Texture (rub test)

Rub 1 = gritty = mineral soil

Rub 2 = greasy = mucky mineral or organic

Rub 3/4 = gritty = mucky mineral

Rub 3/4 = greasy = organic