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Tradeoffs among Ecosystem Services, Performance Certainty, and Cost-efficiency in Implementation of the Chesapeake Bay Total Maximum Daily Load

Published online by Cambridge University Press:  15 September 2016

Lisa A. Wainger*
Affiliation:
University of Maryland CES Chesapeake Biological Lab
George Van Houtven
Affiliation:
Agricultural, Resource, and Energy Economics and Policy Program, and Marion Deerhake is a senior research environmental scientist at RTI International in North Carolina
Ross Loomis
Affiliation:
Ecosystem Services Research at RTI International in North Carolina
Jay Messer
Affiliation:
RTI International in North Carolina
Robert Beach
Affiliation:
Agricultural, Resource, and Energy Economics and Policy Program at RTI International in North Carolina
Marion Deerhake
Affiliation:
Agricultural, Resource, and Energy Economics and Policy Program, and Marion Deerhake is a senior research environmental scientist at RTI International in North Carolina
*
Corresponding Author: Lisa A. WaingerChesapeake Biological LabUniversity of Maryland Center for Environmental ScienceP.O. Box 38Solomons, MD 20688 ▪ Email [email protected].

Abstract

The cost-effectiveness of total maximum daily load (TMDL) programs depends heavily on program design. We develop an optimization framework to evaluate design choices for the TMDL for the Potomac River, a Chesapeake Bay sub-basin. Scenario results suggest that policies inhibiting nutrient trading or offsets between point and nonpoint sources increase compliance costs markedly and reduce ecosystem service co-benefits relative to a least-cost solution. Key decision tradeoffs highlighted by the analysis include whether agricultural production should be exchanged for low-cost pollution abatement and other environmental benefits and whether lower compliance costs and higher co-benefits provide adequate compensation for lower certainty of water-quality outcomes.

Type
Selected Papers
Copyright
Copyright © 2013 Northeastern Agricultural and Resource Economics Association 

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