Exploring benefits of spatial cooperative harvesting in a sea urchin fishery: an agent-based approach
Authored by Andre E Punt, Ray Hilborn, Nicolas L Gutierrez, Peter Halmay, Stephen Schroeter
Date Published: 2017
DOI: 10.1002/ecs2.1829
Sponsors:
United States National Oceanic and Atmospheric Administration (NOAA)
California Sea Urchin Commission
Platforms:
R
Model Documentation:
Other Narrative
Flow charts
Mathematical description
Model Code URLs:
Model code not found
Abstract
Sedentary or low-mobility organisms show a high degree of dependency
with their substrate, where its heterogeneity often determines
small-scale spatial patterns of distribution, life history traits, and
fishery yields. For sea urchins, this spatial structure is usually
shaped by food availability, habitat structure, individual movement, and
fishery dynamics. All of these have a significant impact on their
physiological and reproductive status and in particular on their gonadal
content. These patterns are of particular interest considering that the
sea urchin fishery is a roe fishery where marketability depends on gonad
yield and quality, which in turn is related to spatial and temporal
variations in associated kelp beds. Thus, better gonad quality and
yields generate higher profits for both fishers (divers) and processors.
However, competition among divers within a non-cooperative system
creates a ``race for shellfish{''} precluding higher gonad yields per
unit of effort. A spatially explicit agent-based model for the San
Diego, California red sea urchin (Strongylocentrotus franciscanus)
fishery was developed in order to assess the benefits of cooperative
harvesting by depicting spatial and temporal variations in fishery
yields. A cooperative harvesting scenario where divers consistently
target those areas with higher yields avoiding low-quality sea urchins
was compared against a non-cooperative situation where divers harvest at
random or based only on densities of sea urchins. Sea urchin population
at the end of the simulation period was 20\% higher for the most
cooperative scenario compared to the non-cooperative fishery. Further,
for the most cooperative scenario where information sharing among divers
is greatest and harvest is coordinated, sea urchin catches were at least
10\% higher and gonad yield 35\% higher than in the non-cooperative
scenario. In this model, information sharing and organized harvesting
typical of well-functioning cooperatives allowed fishers to optimize the
use of the resource in terms of higher gonad yields per unit of effort
while maintaining the productivity of the stock. This study also
highlights the importance of community-based management (i.e.,
collaborative efforts in assessment, management, and governance of
fisheries between fishers, scientists, and managers) toward improving
fisheries sustainability.
Tags
Community-based management
Population-structure
Resource-allocation
Northern california
Food
availability
Southern california
Cooperative harvesting
Sea urchins:
individual-based models
Small-scale fisheries
Spatially explicit
modeling
Scallop psychrochlamys-patagonica
Strongylocentrotus-franciscanus
Kelp
forest
Macrocystis-pyrifera
Giant-kelp