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Options for Identifying

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Title: Quantifying Pollutant Loads Author: deq-ess Last modified by: Dave Fongers Created Date: 6/8/2006 7:18:29 PM Document presentation format: On-screen Show – PowerPoint PPT presentation

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Title: Options for Identifying


1
Options for Identifying Quantifying Pollutant
Loads
2
Presentation Overview
  • Goals of pollutant load estimation
  • Options for quantifying current loads or
    conditions
  • Data-driven approaches
  • Models
  • Modeling, as it relates to environmental systems
  • Types of models
  • Models typically used for load estimation
  • Data needs
  • Example Application of Simple Model

3
Why is Pollutant Load Estimation Necessary?
  • Identify relative magnitude of contributions from
    different sources
  • Determine whether locations of sources are
    critical
  • Evaluate timing of source loading
  • Target future management efforts
  • Plan restoration strategies
  • Project future loads under changing conditions
  • Develop a mechanism for quantifying potential
    improvement

4
Pollutant Load Estimation Approaches
  • Has it already been done?
  • Total Maximum Daily Loads (TMDLs)
  • Clean Lakes Studies
  • Other local and regional studies
  • If not
  • Data-driven approaches
  • Best when detailed monitoring data available
  • Models
  • Provide greater insight into impact of sources
    (temporally and spatially)
  • Readily allow for evaluation of future conditions

5
Data-driven Approaches
  • Estimate source loads using
  • Monitoring data
  • Periodic water quality concentrations and flow
    gauging data
  • Facility discharge monitoring reports
  • Literature
  • Loading rates, often by landuse (e.g.,
    lbs/acre/year)
  • Typical facility concentrations and flow

6
Is a Data-driven Approach Appropriate?
  • Monitoring data
  • Does it represent most conditions that occur (low
    flow, storms, etc.)?
  • Are spatial and source variability
    well-represented?
  • Have all parameters of interest been monitored?
  • Is there a clear path to a management strategy?

7
Load Estimates Monitoring Data
  • In simplest terms
  • load flow x concentration
  • Load duration curves
  • Flow-based presentation
  • Statistical techniques
  • Relationships between flow and concentration to
    fill in the blanks when data arent available
  • Examples include
  • Regression approach
  • FLUX

8
Load Duration Curves
  • Rank daily flow and generate flow duration curve
  • Multiply water quality concentrations by
    corresponding flow values
  • Flow curve represents water quality target

9
Regression Approach
  • Develop a regression equation by plotting flow
    vs. corresponding water quality concentration
  • Use the relationship to predict water quality
    concentration for days when flow data exist
  • Note limited applicability to data that is
    heavily storm-driven and spans orders of
    magnitude (e.g., sediment)
  • should consider log transform regression approach
  • Minimum Variance Unbiased Estimator (MVUE)
    recommended by USGS for bias correction
    (http//co.water.usgs.gov/sediment/bias.frame.html
    )

10
Regression Approach - Example
11
FLUX
  • Interactive computer program
  • Developed for U.S. Army Corps of Engineers
  • Maps flow-concentration relationship from
    available data onto entire flow record
  • Calculates total mass, streamflow, and error
    statistics
  • Can stratify data into groups based on flow
  • Six available estimation algorithms

12
FLUX Data Requirements
  • Constituent concentrations, ideally collected
    weekly to monthly for at least a year
  • Date each sample was collected
  • Corresponding flow measurements (instantaneous or
    daily mean)
  • Complete flow record (daily mean) for the period
    of interest

13
Load Estimates Literature
  • Landuse-specific loading rates (typically annual)
  • Multiply loading rate by area
  • loadall (arealu1 x loading ratelu1) (arealu2 x
    loading ratelu2)
  • Generally for landuse or watershed-wide analysis
  • Many sources Lin (2004) Beaulac and Reckhow
    (1982), etc.
  • Use with caution (need correct representation for
    your local watershed)
  • Pollution sources
  • Climate
  • Soils

14
Example Load Estimation Based on Literature Values
15
Limitations of Data-driven Approaches
  • Monitoring data
  • Reflect current/historical conditions (limited
    use for future predictions)
  • Insight limited by extent of data (usually water
    quality data)
  • Often not source-specific
  • May reflect a small range of flow conditions
  • Literature
  • Not reflective of local conditions
  • Wide variation among literature
  • Often a static value (e.g., annual)

16
If a Data-driven Approach Isnt EnoughModels are
Available
What is a Model?
  • A theoretical construct,
  • together with assignment of numerical values to
    model parameters,
  • incorporating some prior observations drawn from
    field and laboratory data,
  • and relating external inputs or forcing functions
    to system variable responses

Definition from Thomann and Mueller, 1987
17
Nuts and Bolts of a Model
Input
Model Algorithms
Output
Factor 1
Rainfall Event
System
Response
Land use
Factor 2
Soil
Pollutant Buildup
Stream
Pt. Source
Factor 3
Others
18
Is a Model Necessary? It depends what you
want to know
Probably Not
  • What are the loads associated with individual
    sources?
  • Where and when does impairment occur?
  • Is a particular source or multiple sources
    generally causing the problem?
  • Will management actions result in meeting water
    quality standards?
  • Which combination of management actions will most
    effectively meet load targets?
  • Will future conditions make impairments worse?
  • How can future growth be managed to minimize
    adverse impacts?

Probably
  • Models are used in many areas
  • TMDLs, stormwater evaluation and design,
    permitting, hazardous waste remediation,
    dredging, coastal planning, watershed management
    and planning, air studies

19
Types of Models
  • Landscape models
  • Runoff of water and materials on and through the
    land surface
  • Receiving water models
  • Flow of water through streams and into lakes and
    estuaries
  • Transport, deposition, and transformation in
    receiving waters
  • Watershed models
  • Combination of landscape and receiving water
    models
  • Site-scale models
  • Detailed representation of local processes, for
    example Best Management Practices (BMPs)

20
Types of Models
  • Landscape/Site-scale models
  • Landscape/Site-scale models
  • Receiving water models
  • Receiving water models
  • Watershed models
  • Watershed models

21
Model Basis
  • Empirical formulations
  • mathematical relationship based on observed data
    rather than theoretical relationships
  • Deterministic models
  • mathematical models designed to produce system
    responses or outputs to temporal and spatial
    inputs (process-based)

22
Review of Commonly Used Models
  • Landscape and Watershed models
  • Simple models
  • Mid-range models
  • Comprehensive watershed models
  • Field-scale models

23
Simple Models
  • Loading Rate
  • Simple Method
  • USLE / MUSLE
  • USGS Regression
  • PLOAD
  • STEPL
  • Minimal data preparation
  • Landuse, soil, slope, etc.
  • Good for long averaging periods
  • Annual or seasonal budgets
  • No calibration
  • Some testing/validation is preferable
  • Comparison of relative magnitude
  • Limitations
  • Limited to waterbodies where loadings can be
    aggregated over longer averaging periods
  • Limited to gross loadings

24
Mid-range Models
  • AGNPS
  • GWLF
  • P8
  • SWAT ( receiving water)
  • More detailed data preparation
  • Meteorological data
  • Good for seasonal/event issues
  • Minimal or no calibration
  • Testing and validation preferable
  • Application objectives
  • Storm events, daily loads
  • Limitations
  • Daily/monthly load summaries
  • Limited pollutants simulated
  • Limited in-stream simulation and comparison with
    standards

25
Comprehensive Watershed Models
  • HSPF/LSPC
  • SWMM
  • Accommodate more detailed data input
  • Short time steps and finer configuration
  • Complex algorithms need state/kinetic variables
  • Ability to evaluate various averaging periods and
    frequencies
  • Calibration is required
  • Addresses a wide range of water and water quality
    problems
  • Include both landscape and receiving water
    simulation
  • Limitations
  • More training and experience needed
  • Time-consuming (need GIS help, output analysis
    tools, etc.)

26
Source of Additional Information on Model
Selection
  • EPA 1997, Compendium of Models for TMDL
    Development and Watershed Assessment.
    EPA841-B-97-007
  • Review of loading and receiving water models
  • Ecological assessment techniques and models
  • Model selection

27
Example of Simple Model Application
  • Spreadsheet Tool for Estimating Pollutant Load
    (STEPL)
  • Employs simple algorithms to calculate nutrient
    and sediment loads from different land uses
  • Also includes estimates of load reductions that
    would result from the implementation of various
    BMPs
  • Data driven and highly empirical
  • A customized MS Excel spreadsheet model
  • Simple and easy to use

28
STEPL Users?
  • Basic understanding of hydrology, erosion, and
    pollutant loading processes
  • Knowledge (use and limitation) of environmental
    data (e.g., land use, agricultural statistics,
    and BMP efficiencies)
  • Familiarity with MS Excel and Excel Formulas

29
Process
30
STEPL Web Site
Link to on-line Data server
Link to download setup program to install STEPL
program and documents
Temporary URL http//it.tetratech-ffx.com/stepl
until moved to EPA server
31
(No Transcript)
32
STEPL Main Program
  • Run STEPL executable program to create and
    customize spreadsheet dynamically
  • Go to demonstration

33
Conclusions
  • Many tools are available to quantify pollutant
    loads
  • Approach depends on intended use of predictions
  • Simplest approaches are data-driven
  • Watershed modeling is more complex and
    time-consuming
  • provides more insight into spatial and temporal
    characteristics
  • useful for future predictions and evaluation of
    management options
  • One size doesnt fit all!
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