Pollutant Load Estimation Tool (PLET)

What is PLET?

PLET provides a user-friendly web interface to create a customized model at the watershed, field , or site scale. For the HUC 12 watershed scale data inputs are auto populated by the input data server.

PLET considers urban, cropland, pastureland, feedlot, forest and user defined land uses. The nonpoint sources include cropland, pastureland, farm animals, feedlots, urban runoff, and failing septic systems. In addition to estimating annual load reductions as a result of BMP implementation, PLET estimates nutrient and sediment loads prevented as a result of forested land protection.

PLET employs simple algorithms to compute surface runoff, nutrient loads and sediment delivery based on various land uses and best management practices. The annual nutrient loading is calculated based on the runoff volume and the pollutant concentrations in surface runoff as influenced by factors such as the land use distribution and management practices. The annual sediment load from sheet and rill erosion is calculated based on the Revised Universal Soil Loss Equation Version 2 (RUSLE2) methodology and the sediment delivery ratio.  

Input Data Server for PLET: The input data server provides initial model input data that can be used as a starting point in populating the PLET model. It provides information on land use acreages, agricultural animals, septic systems, and hydrological soil groups at the HUC12 scale. These data can be downloaded for use in other applications, or the data can be applied automatically to a PLET model as it is developed. 

Model Documentation

Access PLET!

User's Guide and Other Documents

Date	Document	Notes
October 2024	PLET User's Guide Version 2.0 (pdf) (6.32 MB, October 2024)	Current
October 2024	2024 Pollutant Load Estimation Tool (PLET) Precipitation Data Update (pdf) (344.54 KB)	Current
January 2024	Revised Universal Soil Loss Equation Version 2 (RUSLE2) Factor Update (pdf) (279.53 KB)	Current
April 2023	BMP Descriptions (pdf) (3.48 MB, April 2023) This document provides definitions for best management practice (BMPs) used in the Pollutant Load Estimation Tool (PLET).	Current
April 2022	PLET User's Guide Version 1.0 (pdf) (6.34 MB, April 2022)	Historical

Training Materials

• American Farmland Trust, Outcomes Estimation Tools Training Webinar Series, EPA Pollutant Load Estimation Tool Training: This training provides info on the tool background, model interface, and demonstration of the tool.
• PLET Training Video: For ease of navigation through this training video, you can use the bookmarked chapters below:
  • Getting Started 
  • Review of Inputs 
  • BMPs and BMP Calculator 
  • Urban BMP Calculator 
  • Total Loads

Questions and Answers

Question 1:  What are the differences between PLET, STEPL, and Region 5 Model?

Question 2:  The septic system failure rate seems low, are there other alternative data?

Question 3:  How can I add my own BMPs to PLET’s BMP list?

Question 4:  Can you help me use the BMP Calculator?

Question 5:  What are other models that can be used for load reduction calculations?

Question 6:  If I don't know exactly where all my BMPs for a particular sub-watershed are located, am I better off calculating them in serial or in parallel configuration for that sub-watershed?

Question 7:  Why is the PLET-calculated sediment loading rate (t/ac/yr) from my watershed much lower than the erosion rate (> 1 t/ac/yr) reported for my study area? Can you explain?

Question 8:  Some of the data I'm gathering to input into the PLET model is not consistent. For filter strips, I have some data coming to me as actual acres of filter strip, and some coming to me as acres affected by the filter strip. What is the best way to deal with these discrepancies in the model?

Question 9:  My general question is whether it is appropriate to use PLET to compare the loading effects of changing a particular site from one land use to another, e.g., agricultural to commercial.  I also wonder how it applies the USLE to "soil loss" from a parking lot.

Question 10: Can PLET be used to model bacteria?

Answers:

Question 1: What are the differences between PLET, STEPL, and the Region 5 Model?

Below are the major differences among the three models:

The Region 5 Model

• Calculates load at the source level
• Sources are independent (no relationship between worksheets)
• Users can not specify and update BMPs used in the model

STEPL and PLET

• Calculates load for different sources at source and watershed level
•  Sources are related in watershed
•  Users can specify and update BMP list
•  Users can use BMP calculator to estimate combined BMP efficiencies for complex BMP arrangements
•  On-line input data server for initial model setup (Caution: Do not substitute the on-line data for real local data!)

PLET

• Web-based modeling tool
• Scenarios are saved online
• Excel versioning and compatibility issues are no longer a problem
• Updated BMP Calculator tool, with improved user interface and ability to directly import efficiencies into a selected scenario
• Scenarios can be shared with other PLET users

Question 2: The septic system failure rate seems low, are there other alternative data?

Yes. The failure rate data have very high uncertainty. Users are encouraged to obtain the septic failure rate from their local health departments.

Besides the data from the ‘Input Data Server’ (National Environmental Service Center formerly National Small Flow Clearinghouse, 1992 and 1998), Electric Power Research Institute conducted a state-by-state survey on septic failure rate. Below is the summary:

State	Estimated system failure rate (in %)	Failure definition
Alabama	20	Not given
Arizona	0.5	Surfacing, backup, surface or ground water contamination
California	1-4	Surfacing, backup, surface or ground water contamination
Florida	1-2	Surfacing, backup, surface or ground water contamination
Georgia	1.7	Public hazard
Hawaii	15-35	Improper construction, overflow
Idaho	20	Backup, surface or ground water contamination
Kansas	10-15	Surfacing, nuisance conditions (for installations after 1980)
Louisiana	50	Not given
Maryland	1	Surfacing, backup, surface or ground water contamination
Massachusetts	25	Public health
Minnesota	50-70	Cesspool, surfacing, inadequate soil layer, leaking
Missouri	30-50	Backup, surface or ground water contamination
Nebraska	40	Nonconforming system, water quality
New Hampshire	<5	Surfacing, backup
New Mexico	20	Surfacing
New York	4	Backup, surface or ground water contamination
North Carolina	15-20	Not given
North Dakota	28	Backup, surfacing
Ohio	25-30	Backup, surfacing
Oklahoma	5-10	Backup, surfacing, discharge off property
Rhode Island	25	Not given
South Carolina	6-7	Not given
Texas	10-15	Surfacing, surface or ground water contamination
Utah	0.5	Surfacing, backup, exceeding discharge standards
Washington	33	Public health hazard
West Virginia	60	Backup, surface or ground water contamination
Wyoming	0.4	Backup, surfacing, ground water contamination

Question 3: How can I add my own BMPs to PLET?

To create a User defined BMP, from the BMPs Module, click on Create a User Defined BMP. This opens a dialog box where the BMP name and pollutant reduction efficiency values can be entered. After clicking Save and Close, the BMP will be saved. To add the new BMP to the scenario, click Add BMP and select the watershed and land use where the practice will be applied. Then select the practice from the drop-down list in the BMPs column. Custom BMPs are distinguished from default BMPs with the naming convention “User Defined/Custom BMP (Custom BMP Name)” where the Custom BMP Name is the name entered in the Custom BMP creation dialog box. See more information in the PLET User’s Guide.

Question 7: Why is the PLET-calculated sediment loading rate (t/ac/yr) from my watershed much lower than the erosion rate (> 1 t/ac/yr) reported for my study area? Can you explain?

The sediment output from a watershed is different from on-site erosion. For cropland in your calculation, erosion rate may be larger than 1 t/ac/yr; however, the sediment output from your watershed is much lower. The PLET model calculates sediment output using "erosion x sediment delivery ratio." If the watershed area is large,  it results in a low sediment delivery ratio.