Comparing Dynamic and Static Time-Area Closures for Bycatch Mitigation: A Management Strategy Evaluation of a Swordfish Fishery
Time-area closures are a valuable tool for mitigating fisheries bycatch. There is increasing recognition that dynamic closures, which have boundaries that vary across space and time, can be more effective than static closures at protecting mobile species in dynamic environments. We created a managem...
| Main Authors: | , , , , , , , , |
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| Format: | Article |
| Language: | English |
| Published: |
Frontiers Media S.A.
2021-03-01
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| Series: | Frontiers in Marine Science |
| Subjects: | |
| Online Access: | https://www.frontiersin.org/articles/10.3389/fmars.2021.630607/full |
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|---|---|
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Article |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
James A. Smith James A. Smith Desiree Tommasi Desiree Tommasi Heather Welch Heather Welch Elliott L. Hazen Elliott L. Hazen Jonathan Sweeney Stephanie Brodie Stephanie Brodie Barbara Muhling Barbara Muhling Stephen M. Stohs Michael G. Jacox Michael G. Jacox |
| spellingShingle |
James A. Smith James A. Smith Desiree Tommasi Desiree Tommasi Heather Welch Heather Welch Elliott L. Hazen Elliott L. Hazen Jonathan Sweeney Stephanie Brodie Stephanie Brodie Barbara Muhling Barbara Muhling Stephen M. Stohs Michael G. Jacox Michael G. Jacox Comparing Dynamic and Static Time-Area Closures for Bycatch Mitigation: A Management Strategy Evaluation of a Swordfish Fishery Frontiers in Marine Science bycatch spatial closures dynamic ocean management EcoCast management strategy evaluation (MSE) |
| author_facet |
James A. Smith James A. Smith Desiree Tommasi Desiree Tommasi Heather Welch Heather Welch Elliott L. Hazen Elliott L. Hazen Jonathan Sweeney Stephanie Brodie Stephanie Brodie Barbara Muhling Barbara Muhling Stephen M. Stohs Michael G. Jacox Michael G. Jacox |
| author_sort |
James A. Smith |
| title |
Comparing Dynamic and Static Time-Area Closures for Bycatch Mitigation: A Management Strategy Evaluation of a Swordfish Fishery |
| title_short |
Comparing Dynamic and Static Time-Area Closures for Bycatch Mitigation: A Management Strategy Evaluation of a Swordfish Fishery |
| title_full |
Comparing Dynamic and Static Time-Area Closures for Bycatch Mitigation: A Management Strategy Evaluation of a Swordfish Fishery |
| title_fullStr |
Comparing Dynamic and Static Time-Area Closures for Bycatch Mitigation: A Management Strategy Evaluation of a Swordfish Fishery |
| title_full_unstemmed |
Comparing Dynamic and Static Time-Area Closures for Bycatch Mitigation: A Management Strategy Evaluation of a Swordfish Fishery |
| title_sort |
comparing dynamic and static time-area closures for bycatch mitigation: a management strategy evaluation of a swordfish fishery |
| publisher |
Frontiers Media S.A. |
| series |
Frontiers in Marine Science |
| issn |
2296-7745 |
| publishDate |
2021-03-01 |
| description |
Time-area closures are a valuable tool for mitigating fisheries bycatch. There is increasing recognition that dynamic closures, which have boundaries that vary across space and time, can be more effective than static closures at protecting mobile species in dynamic environments. We created a management strategy evaluation to compare static and dynamic closures in a simulated fishery based on the California drift gillnet swordfish fishery, with closures aimed at reducing bycatch of leatherback turtles. We tested eight operating models that varied swordfish and leatherback distributions, and within each evaluated the performance of three static and five dynamic closure strategies. We repeated this under 20 and 50% simulated observer coverage to alter the data available for closure creation. We found that static closures can be effective for reducing bycatch of species with more geographically associated distributions, but to avoid redistributing bycatch the static areas closed should be based on potential (not just observed) bycatch. Only dynamic closures were effective at reducing bycatch for more dynamic leatherback distributions, and they generally reduced bycatch risk more than they reduced target catch. Dynamic closures were less likely to redistribute fishing into rarely fished areas, by leaving open pockets of lower risk habitat, but these closures were often fragmented which would create practical challenges for fishers and managers and require a mobile fleet. Given our simulation’s catch rates, 20% observer coverage was sufficient to create useful closures and increasing coverage to 50% added only minor improvement in closure performance. Even strict static or dynamic closures reduced leatherback bycatch by only 30–50% per season, because the simulated leatherback distributions were broad and open areas contained considerable bycatch risk. Perfect knowledge of the leatherback distribution provided an additional 5–15% bycatch reduction over a dynamic closure with realistic predictive accuracy. This moderate level of bycatch reduction highlights the limitations of redistributing fishing effort to reduce bycatch of broadly distributed and rarely encountered species, and indicates that, for these species, spatial management may work best when used with other bycatch mitigation approaches. We recommend future research explores methods for considering model uncertainty in the spatial and temporal resolution of dynamic closures. |
| topic |
bycatch spatial closures dynamic ocean management EcoCast management strategy evaluation (MSE) |
| url |
https://www.frontiersin.org/articles/10.3389/fmars.2021.630607/full |
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doaj-a190c7ddf51c4dc087c11a51c90ab6b32021-03-19T17:44:53ZengFrontiers Media S.A.Frontiers in Marine Science2296-77452021-03-01810.3389/fmars.2021.630607630607Comparing Dynamic and Static Time-Area Closures for Bycatch Mitigation: A Management Strategy Evaluation of a Swordfish FisheryJames A. Smith0James A. Smith1Desiree Tommasi2Desiree Tommasi3Heather Welch4Heather Welch5Elliott L. Hazen6Elliott L. Hazen7Jonathan Sweeney8Stephanie Brodie9Stephanie Brodie10Barbara Muhling11Barbara Muhling12Stephen M. Stohs13Michael G. Jacox14Michael G. Jacox15Institute of Marine Sciences, University of California, Santa Cruz, Santa Cruz, CA, United StatesNOAA Southwest Fisheries Science Center, La Jolla, CA, United StatesInstitute of Marine Sciences, University of California, Santa Cruz, Santa Cruz, CA, United StatesNOAA Southwest Fisheries Science Center, La Jolla, CA, United StatesInstitute of Marine Sciences, University of California, Santa Cruz, Santa Cruz, CA, United StatesNOAA Southwest Fisheries Science Center, Monterey, CA, United StatesInstitute of Marine Sciences, University of California, Santa Cruz, Santa Cruz, CA, United StatesNOAA Southwest Fisheries Science Center, Monterey, CA, United StatesNOAA Pacific Islands Fisheries Science Center, Honolulu, HI, United StatesInstitute of Marine Sciences, University of California, Santa Cruz, Santa Cruz, CA, United StatesNOAA Southwest Fisheries Science Center, Monterey, CA, United StatesInstitute of Marine Sciences, University of California, Santa Cruz, Santa Cruz, CA, United StatesNOAA Southwest Fisheries Science Center, La Jolla, CA, United StatesNOAA Southwest Fisheries Science Center, La Jolla, CA, United StatesNOAA Southwest Fisheries Science Center, Monterey, CA, United StatesNOAA Earth System Research Laboratory, Boulder, CO, United StatesTime-area closures are a valuable tool for mitigating fisheries bycatch. There is increasing recognition that dynamic closures, which have boundaries that vary across space and time, can be more effective than static closures at protecting mobile species in dynamic environments. We created a management strategy evaluation to compare static and dynamic closures in a simulated fishery based on the California drift gillnet swordfish fishery, with closures aimed at reducing bycatch of leatherback turtles. We tested eight operating models that varied swordfish and leatherback distributions, and within each evaluated the performance of three static and five dynamic closure strategies. We repeated this under 20 and 50% simulated observer coverage to alter the data available for closure creation. We found that static closures can be effective for reducing bycatch of species with more geographically associated distributions, but to avoid redistributing bycatch the static areas closed should be based on potential (not just observed) bycatch. Only dynamic closures were effective at reducing bycatch for more dynamic leatherback distributions, and they generally reduced bycatch risk more than they reduced target catch. Dynamic closures were less likely to redistribute fishing into rarely fished areas, by leaving open pockets of lower risk habitat, but these closures were often fragmented which would create practical challenges for fishers and managers and require a mobile fleet. Given our simulation’s catch rates, 20% observer coverage was sufficient to create useful closures and increasing coverage to 50% added only minor improvement in closure performance. Even strict static or dynamic closures reduced leatherback bycatch by only 30–50% per season, because the simulated leatherback distributions were broad and open areas contained considerable bycatch risk. Perfect knowledge of the leatherback distribution provided an additional 5–15% bycatch reduction over a dynamic closure with realistic predictive accuracy. This moderate level of bycatch reduction highlights the limitations of redistributing fishing effort to reduce bycatch of broadly distributed and rarely encountered species, and indicates that, for these species, spatial management may work best when used with other bycatch mitigation approaches. We recommend future research explores methods for considering model uncertainty in the spatial and temporal resolution of dynamic closures.https://www.frontiersin.org/articles/10.3389/fmars.2021.630607/fullbycatchspatial closuresdynamic ocean managementEcoCastmanagement strategy evaluation (MSE) |