Abstract
Marine fisheries are a significant source of protein for many human populations. In some locations, however, destructive fishing practices have negatively impacted the quality of fish habitat and reduced the habitat’s ability to sustain fish stocks. Improving the management of stocks that can be potentially damaged by harvesting requires improved understanding of the spatiotemporal dynamics of the stocks, their habitats, and the behavior of the harvesters. We develop a mathematical model for both a fish stock as well as its habitat quality. Both are modeled using nonlinear, parabolic partial differential equations, and density dependence in the growth rate of the fish stock depends upon habitat quality. The objective is to find the dynamic distribution of harvest effort that maximizes the discounted net present value of the coupled fishery-habitat system. The value derives both from extraction (and sale) of the stock and the provisioning of ecosystem services by the habitat. Optimal harvesting strategies are found numerically. The results suggest that no-take marine reserves can be an important part of the optimal strategy and that their spatiotemporal configuration depends both on the vulnerability of habitat to fishing damage and on the timescale of habitat recovery when fishing ceases.
Highlights
It is not uncommon for modern fishing gear to impact the habitats of the fish being harvested
Given the collateral damage that fishing may impose on essential habitat, it is reasonable to ask whether marine reserves—areas that are closed to fishing—might be a useful part of management
We show the framework for finding the sensitivity functions and the corresponding adjoint functions needed to characterize an optimal control (Lenhart and Workman 2007; De Silva et al 2017)
Summary
It is not uncommon for modern fishing gear to impact the habitats of the fish being harvested. Building on these results, Moeller and Neubert (2013, 2015) have analyzed spatially explicit models with the object of evaluating the role of marine reserves in optimal (i.e., rent maximizing) harvesting when fishing has negative habitat effects. We derive a harvesting strategy that maximizes the net present value of the stock and explore the circumstances under which marine reserves are part of that optimal strategy.
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