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Neuse Estuary Eutrophication Model: Predictions of Water Quality Improvement. By James D. Bowen UNC Charlotte. Calibration Summary. Both transport and water quality model are able to simulate observed system dynamics nutrients generally decreasing “downstream”
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Neuse Estuary Eutrophication Model: Predictions of Water Quality Improvement By James D. Bowen UNC Charlotte
Calibration Summary • Both transport and water quality model are able to simulate observed system dynamics • nutrients generally decreasing “downstream” • high nutrients may not immediately produce high chl-a
Predictions of Water Quality Improvement • Compared Four Cases: 1. Base Case 2. 70% N concentration 3. 70% P concentration 4. 70% N & P concentration • Water quality parameters examined: • surface water chl-a • bottom water DO
Another Special Feature of this Model Application Emphasis on quantifying modeling uncertainties
Uncertainty Analysis • Objective: put “error bars” on model predictions • Error sources: model error, boundary & initial conditions, parameter error • calibration performance gives estimate of model, boundary, and inital condition error • parameter error usually estimated with sensitivity analysis
Uncertainty Analysis • Standard sensitivity analysis: • vary model parameters one-by-one and measure variability in model predictions • Standard sensitivity analysis may under or over predict uncertainty • Basic problem:calibration and sensitivityanalysis done as separate, independent procedures
Uncertainty Analysis Method • Couple uncertainty analysis w/ calibration • Determine not one but many “feasible” parameter vectors • Each feasible vector produces desired system behavior • 31 of 729 were feasible • Run model w/ each feasible vector to determine specification uncertainty
Uncertainty Analysis • Prediction uncertainty = specification uncertainty + residual error • method similar to the “Regional Sensitivity Analysis” (Adams 1998) method used for Lake Okeechobee
Establishing System Behavior • Seasonal/Spatial Trends • based upon 1991 monitoring data • nutrients decreasing downstream • early mid-estuary phytoplankton bloom • later upper-estuary bloom • several pulses of high NOx conc. @ New Bern • DO decreases through season
System Behavior, cont’d • Expectations of model performance • based upon Chesapeake Bay, Massachusetts Bay, & Tar-Pam studies • nutrients w/in 50% • DO w/in 20 % (.5 - 1 mg/l) • Chl-a w/in 50%
System Behavior Definition • Compared mid-depth spatial average concentrations to behavior max & min values • New Bern and Cherry Pt. areas • Chl, DO, and NOx conc.’s • Feasibility statistic: • % of predictions within each behavior “window”
May June July Aug Chl Conc: Prediction & Behavior 80 60 New Bern Area 40 Conc. (ug/l) Cherry Pt. Area 20
May June July Aug NOx Conc: Prediction & Behavior New Bern Area 0.6 0.4 Conc. (mg/l) 0.2 Cherry Pt. Area 0.0
May June July Aug DO Conc: Prediction & Behavior 10 New Bern Area 8 Cherry Pt. Area Conc. (mg/l) 6 4
Determining behavior score and feasibility • Behavior Score = avg(% within window) • also require minimum % within window for each behavior
Specification of Variable Parameters • Key parameters and ranges taken from Adams (1998) • Focus on parameters affecting chl-a
Search for Feasible Parameter Vectors Preliminary Run (25 days) Accept Final Run (120 days) Accept #1 Accept #2 = 31 Vectors
Chl-a Predictions - 31 Behavior Producing Parameter Vectors - All Seg’s
WQ Improvement: Chl Conc. & Exceedence Frequency Reductions Percentage Reduction
Summary • WQ improvement predicted for ‘91 conditions • Predicted WQ improvement • chl: none @ New Bern, modest @ Cherry Pt. (approx. 20%) • DO: short-term improvement minor (long-term greater)
Summary, Cont’d • Uncertainty Analysis • focused on effects of parameter uncertainty • small percentage (4%) of cases exhibit desired system behavior • Chl concentration reduction “error bars” • estuary median value: 10 - 16% • Cherry Pt. median: 16 - 22%
Summary, Cont’d • Uncertainty Analysis • Chl concentration reduction “error bars” • estuary max. chl-a value: -1 - 3% • CP max. chl-a value: 0 - 18% • Reduction in % of values exceeding water quality standard (40 ug/l) “error bars” • estuary value: 0 - 23 %
What’s left to do? • Repeat analysis for other years • 1997 simulations completed next month • 1998 simulations pending additional funding • Consider longer-term sediment “clean-up” • requires full calendar of monitoring data (e.g. 1998 data)
Looking Forward: Using MODMON monitoring for modeling • simulating different years helps to quantify uncertainty due to hydrologic variability • MODMON monitoring far superior to 1991 data set • much more frequent, many more stations, includes vertical profiles, includes more parameters, includes sed’s
MODMON monitoring data: 1997 vs. 1998 • 1997 features • similar hydrologically to 1991 • no downstream boundary conditions before June • dedicated downstream elevation monitor not installed • abundance of high-quality data available to aid calibration/ verification
MODMON monitoring data: 1997 vs. 1998 • 1998 features • unusal year hydrologically with a significant fish kill • dedicated downstream elevation monitor installed • abundance of high-quality data available to aid calibration/ verification • full year of monitoring data will soon be available
More Things to Do • Investigate other reduction scenarios • % reduction larger in Spring, Summer • different % reductions (40%, 50%) • Conduct comprehensive error analysis • intelligent searches of parameter space • quantitative parameter filtering analysis to select variable parameters