The maximum sustainable yield leads to extinction of species in most single and multispecies fisheries

Abstract Sissenwine, M. M., Mace P. M., and Lassen, H. J. 2014. Preventing Overfishing: Evolving Approaches and Emerging Challenges. – ICES Journal of Marine Science, 71: 153–156. The evolution of fishery management frameworks to prevent overfishing is the theme of the eight papers that follow in this issue of the ICES Journal of Marine Science. The current paper describes common elements of the frameworks. All the frameworks are based on the maximum sustainable yield concept. Frameworks to prevent overfishing have evolved to be increasingly prescriptive. This evolution probably reflects past abuse of flexibility which led to overfishing. The outcome has been a decline in the proportion of stocks suffering from overfishing. However, loss of flexibility may result in large foregone yields from multispecies fisheries, create a mis-match between the expectations for scientific information and the realities of scientific uncertainty, and fail to recognize ecosystem dynamics.

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A Study on an offshore Fishery Model for Maximum Sustainable Yield(MSY)

The Journal of Korean Island ◽

10.26840/jki.31.1.83 ◽

2019 ◽

Vol 31 (1) ◽

pp. 83-99 ◽

Cited By ~ 1

Author(s):

Dae-Hyon Kim

Keyword(s):

Maximum Sustainable Yield ◽

Sustainable Yield ◽

Fishery Model

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MSY needs no epitaph—but it was abused

ICES Journal of Marine Science ◽

10.1093/icesjms/fsaa224 ◽

2020 ◽

Author(s):

Daniel Pauly ◽

Rainer Froese

Keyword(s):

Maximum Sustainable Yield ◽

Sustainable Yield

Abstract The maximum sustainable yield (MSY) concept is widely considered to be outdated and misleading. In response, fisheries scientists have developed models that often diverge radically from the first operational version of the concept. We show that the original MSY concept was deeply rooted in ecology and that going back to that version would be beneficial for fisheries, not least because the various substitutes have not served us well.

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Production, Mortality, And Sustainable Yield Of Northwest Atlantic Harp Seals (Pagophilus groenlandicus)

Journal of the Fisheries Research Board of Canada ◽

10.1139/f78-195 ◽

1978 ◽

Vol 35 (9) ◽

pp. 1249-1261 ◽

Cited By ~ 10

Author(s):

G. H. Winters

Keyword(s):

Population Size ◽

Total Population ◽

Historical Data ◽

Maximum Sustainable Yield ◽

Sustainable Yield ◽

Natural Mortality ◽

Northwest Atlantic ◽

The Past ◽

Relative Contribution ◽

Pagophilus Groenlandicus

From recent and historical data the natural mortality rate of adult harp seals (Pagophilus groenlandicus) is estimated to be 0.10 which is within the range of previous estimates (0.08–0.11). New estimates of bedlamer and 0-group natural mortality rates were not significantly different from those of adult seals. Pup production estimates from survival indices agreed well with those from sequential population analyses and indicated a decline from about 350 000 animals in the early 1950s to about 310 000 animals in the early 1970s. Over the same period the 1+ population size declined from 2.5 to 1.1 million animals but has been increasing at the rate of 3%/yr since the introduction of quotas in 1972. The relative contribution of the "Front" production to total ("Front" plus Gulf) production during the past decade has fluctuated from 49 to 87%, the average of 64% being very similar to the 61% obtained previously. These fluctuations suggest some interchange between "Front" and Gulf adults and it is concluded that homing in the breeding areas is a facultative rather than obligatory aspect of seal behavior. Thus the heavier exploitation of the "Front" production is probably sufficiently diffused into the total population to avoid serious effects on "Front" production. The maximum sustainable yield of Northwest Atlantic seals harvested according to recent patterns is estimated to be 290 000 animals (80% pups) from a 1+ population size of 1.8 million animals producing 460 000 pups annually. The sustainable yield at present levels of pup production (335 000 animals) is calculated to be 220 000 animals which is substantially above the present TAC of 180 000 animals and coincides with present harvesting strategies designed to enable the seal hunt to increase slowly towards the MSY level. Key words: mortality, production, sustainable yield, population dynamics, marine mammal

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Can stock–recruitment points determine which spawning potential ratio is the best proxy for maximum sustainable yield reference points?

ICES Journal of Marine Science ◽

10.1093/icesjms/fst105 ◽

2013 ◽

Vol 70 (6) ◽

pp. 1075-1080 ◽

Cited By ~ 6

Author(s):

Christopher M. Legault ◽

Elizabeth N. Brooks

Keyword(s):

Life History ◽

Mortality Rate ◽

Maximum Sustainable Yield ◽

Reference Points ◽

Sustainable Yield ◽

Marine Science ◽

Fishing Mortality ◽

Scatter Plots ◽

Stock Recruitment ◽

Spawning Potential Ratio

Abstract Legault, C. M., and Brooks, E. N. 2013. Can stock–recruitment points determine which spawning potential ratio is the best proxy for maximum sustainable yield reference points? – ICES Journal of Marine Science, 70: 1075–1080. The approach of examining scatter plots of stock–recruitment (S–R) estimates to determine appropriate spawning potential ratio (SPR)-based proxies for FMSY was investigated through simulation. As originally proposed, the approach assumed that points above a replacement line indicate year classes that produced a surplus of spawners, while points below that line failed to achieve replacement. In practice, this has been implemented by determining Fmed, the fishing mortality rate that produces a replacement line with 50% of the points above and 50% below the line. A new variation on this approach suggests FMSY proxies can be determined by examining the distribution of S–R points that are above or below replacement lines associated with specific SPRs. Through both analytical calculations and stochastic results, we demonstrate that this approach is fundamentally flawed and that in some cases the inference is diametrically opposed to the method's intended purpose. We reject this approach as a tool for determining FMSY proxies. We recommend that the current proxy of F40% be maintained as appropriate for a typical groundfish life history.

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A stochastic Pella Tomlinson model and its maximum sustainable yield

Journal of Theoretical Biology ◽

10.1016/j.jtbi.2014.06.012 ◽

2014 ◽

Vol 360 ◽

pp. 46-53 ◽

Cited By ~ 7

Author(s):

Charles Bordet ◽

Louis-Paul Rivest

Keyword(s):

Maximum Sustainable Yield ◽

Sustainable Yield ◽

Tomlinson Model

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Spatial variation in fishing intensity and its effect on yield

Canadian Journal of Fisheries and Aquatic Sciences ◽

10.1139/f07-174 ◽

2008 ◽

Vol 65 (4) ◽

pp. 588-599 ◽

Cited By ~ 31

Author(s):

Stephen Ralston ◽

Michael R O’Farrell

Keyword(s):

Spatial Variation ◽

Local Density ◽

Life Stage ◽

Maximum Sustainable Yield ◽

Recruitment Rate ◽

Sustainable Yield ◽

Fishing Mortality ◽

Density Dependent ◽

Age Structured ◽

Effect On Yield

Fishing mortality is rarely, if ever, evenly distributed over space, yet this is a common assumption of many fisheries models. To evaluate the effect of spatial heterogeneity in fishing mortality on yield, we constructed age-structured models that allowed for differing levels of fishing in three regions within the boundaries of a stock and explored alternative assumptions about the life stage in which density-dependent compensation operates. If the fishing mortality rate (F) is not excessive (i.e., F ≤ FMSY defined for the spatially homogeneous case; MSY, maximum sustainable yield), simulations demonstrated that minor to moderate spatial variation in fishing intensity does not impact sustainable yield. However, if fishing mortality is excessive (F > FMSY), spatial variation in fishing intensity often improves yield and can actually produce yields in excess of MSY when compensation occurs after dispersal, and the density-dependent recruitment rate is a function of the local density of adults. The yield premium generated in these simulations by postdispersal density dependence is due to a low level of compensatory mortality in heavily fished areas coupled with dispersal of propagules into these areas from lightly fished adjacent regions.

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Towards an integrated forecasting system for fisheries on habitat-bound stocks

Ocean Science ◽

10.5194/os-9-261-2013 ◽

2013 ◽

Vol 9 (2) ◽

pp. 261-279 ◽

Cited By ~ 7

Author(s):

A. Christensen ◽

M. Butenschön ◽

Z. Gürkan ◽

I. J. Allen

Keyword(s):

Climatic Variability ◽

Maximum Sustainable Yield ◽

Ecosystem Dynamics ◽

Fish Stock ◽

Generic Model ◽

Sustainable Yield ◽

Model Framework ◽

The North ◽

Basin Scale ◽

Forecasting System

Abstract. First results of a coupled modelling and forecasting system for fisheries on habitat-bound stocks are being presented. The system consists currently of three mathematically, fundamentally different model subsystems coupled offline: POLCOMS providing the physical environment implemented in the domain of the north-west European shelf, the SPAM model which describes sandeel stocks in the North Sea, and the third component, the SLAM model, which connects POLCOMS and SPAM by computing the physical–biological interaction. Our major experience by the coupling model subsystems is that well-defined and generic model interfaces are very important for a successful and extendable coupled model framework. The integrated approach, simulating ecosystem dynamics from physics to fish, allows for analysis of the pathways in the ecosystem to investigate the propagation of changes in the ocean climate and to quantify the impacts on the higher trophic level, in this case the sandeel population, demonstrated here on the basis of hindcast data. The coupled forecasting system is tested for some typical scientific questions appearing in spatial fish stock management and marine spatial planning, including determination of local and basin-scale maximum sustainable yield, stock connectivity and source/sink structure. Our presented simulations indicate that sandeel stocks are currently exploited close to the maximum sustainable yield, even though periodic overfishing seems to have occurred, but large uncertainty is associated with determining stock maximum sustainable yield due to stock inherent dynamics and climatic variability. Our statistical ensemble simulations indicates that the predictive horizon set by climate interannual variability is 2–6 yr, after which only an asymptotic probability distribution of stock properties, like biomass, are predictable.

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