CIVE 633 - ENVIRONMENTAL HYDROLOGY
WETLAND HYDROLOGY AND WATER QUALITY

The flow and storage volume determine the length of time that water spends in the wetland and, thus, the opportunity for interactions between waterborne substances and the wetland ecosystem.

Wetlands lose water via streamflow, groundwater recharge and evapotranspiration.

Continuous source treatment wetlands would normally be isolated from groundwater.

Constructed treatment wetlands usually have uniform bottoms, and an absence of flow pattern effects.

DEFINITION OF HYDROLOGIC TERMS

Hydraulic loading rate q (HLR); cm/d, m/d, m/yr.

q = Q / A

Mean water depth h (d): m, cm.

Wetland water volume V; m³

Nominal detention time t; days.

t = V / Q

Superficial velocity v; m/d.

Hydroperiod: Used to designate all attributes of the water regime. Also, the number of days per year that there is surface water at a given wetland.

WATER BALANCE

Over any budget period, each flow rate adds or removes a corresponding volume of water:

V_i - V_o + V_c - V_b - V_gw + V_sm + V_r - V_e = ΔV_stored

in which:

V_b= bank loss volume
V_c= catchment runoff volume
V_e= evaporated volume
V_gw = volume infiltrated to groundwater
V_i = input wastewater volume
V_o= output wastewater volume
V_r = rain volume
V_sm = snowmelt volume
ΔV_stored = change in water storage in wetland.

WETLAND WATER QUALITY

Wetlands often cause improvements in quality for flow-through waters.
Wetlands do not produce perfectly pure water.
Nutrients are typically present at low levels in natural wetlands.
P is at low levels, often below 0.05 mg/L.
Organic nitrogen is formed in wetlands as a bioproduct of biomass decomposition.
N is low in natural wetlands, from 1 to 2 mg/L.
Nitrate and nitrite nitrogen are usually absent from natural wetland waters.
Denitrification is efficient in the natural wetland environment because the necessary carbon source is present together with the anoxic conditions that favor the utilization of nitrate as an electron acceptor.
Heavy metals are not present in natural wetland waters in high concentrations.

BIOGEOCHEMICAL CYCLING

The limnologist views the wetland as a shallow lake and emphasizes the water chemistry.
The soil scientist views the wetland as a waterlogged soil and emphasizes the wetland substrate.
The engineer views the wetland as a reactor vessel and emphasizes the degradation processes.
The botanist views the wetland as a water garden and emphasizes the plants and their taxonomy.
The hydrologist views the wetland as a vegetated channel.
The ecologist is concerned with types and communities of plants and animal species.
All points have merit, and there is danger in a narrow view.
Fig. 6-17 shows a simplified view of the wetland biogeochemical cycle.

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