Data from: Using fuzzy logic to determine the vulnerability of marine species to climate change
AbstractMarine species are being impacted by climate change and ocean acidification, although their level of vulnerability varies due to differences in species' sensitivity, adaptive capacity and exposure to climate hazards. Due to limited data on the biological and ecological attributes of man...
| Main Authors: | , |
|---|---|
| Format: | Dataset |
| Language: | unknown |
| Published: |
Borealis
2021
|
| Subjects: | |
| Online Access: | https://search.dataone.org/view/sha256:c0c63243cdbda59f5c41d791cac4d576e9fceca937d85196964c5582c3899c41 |
| _version_ | 1833941772231770112 |
|---|---|
| author | Jones, Miranda C. Cheung, William W. L. |
| author_facet | Jones, Miranda C. Cheung, William W. L. |
| author_sort | Jones, Miranda C. |
| collection | Borealis (via DataONE) |
| description | AbstractMarine species are being impacted by climate change and ocean acidification, although their level of vulnerability varies due to differences in species' sensitivity, adaptive capacity and exposure to climate hazards. Due to limited data on the biological and ecological attributes of many marine species, as well as inherent uncertainties in the assessment process, climate change vulnerability assessments in the marine environment frequently focus on a limited number of taxa or geographic ranges. As climate change is already impacting marine biodiversity and fisheries, there is an urgent need to expand vulnerability assessment to cover a large number of species and areas. Here, we develop a modelling approach to synthesize data on species-specific estimates of exposure, and ecological and biological traits to undertake an assessment of vulnerability (sensitivity and adaptive capacity) and risk of impacts (combining exposure to hazards and vulnerability) of climate change (including ocean acidification) for global marine fishes and invertebrates. We use a fuzzy logic approach to accommodate the variability in data availability and uncertainties associated with inferring vulnerability levels from climate projections and species' traits. Applying the approach to estimate the relative vulnerability and risk of impacts of climate change in 1074 exploited marine species globally, we estimated their index of vulnerability and risk of impacts to be on average 52 ± 19 SD and 66 ± 11 SD, scaling from 1 to 100, with 100 being the most vulnerable and highest risk, respectively, under the ‘business-as-usual' greenhouse gas emission scenario (Representative Concentration Pathway 8.5). We identified 157 species to be highly vulnerable while 294 species are identified as being at high risk of impacts. Species that are most vulnerable tend to be large-bodied endemic species. This study suggests that the fuzzy logic framework can help estimate climate vulnerabilities and risks of exploited marine species using publicly and readily available information., Usage notesEstimated vulnerability and risk of impactsData table that contains species name, the estimated vulnerability index and risk of impact index under the RCP 8.5 scenario.Jones_Cheung_SDATA.csv |
| format | Dataset |
| genre | Ocean acidification |
| genre_facet | Ocean acidification |
| id | dataone:sha256:c0c63243cdbda59f5c41d791cac4d576e9fceca937d85196964c5582c3899c41 |
| institution | Open Polar |
| language | unknown |
| op_collection_id | dataone:urn:node:BOREALIS |
| publishDate | 2021 |
| publisher | Borealis |
| record_format | openpolar |
| spelling | dataone:sha256:c0c63243cdbda59f5c41d791cac4d576e9fceca937d85196964c5582c3899c41 2025-06-03T18:50:01+00:00 Data from: Using fuzzy logic to determine the vulnerability of marine species to climate change Jones, Miranda C. Cheung, William W. L. 2021-05-19T00:00:00Z https://search.dataone.org/view/sha256:c0c63243cdbda59f5c41d791cac4d576e9fceca937d85196964c5582c3899c41 unknown Borealis Marine Risk of impact Other Invertebrates Fishes Fuzzy logic ocean acidification Dataset 2021 dataone:urn:node:BOREALIS 2025-06-03T18:18:01Z AbstractMarine species are being impacted by climate change and ocean acidification, although their level of vulnerability varies due to differences in species' sensitivity, adaptive capacity and exposure to climate hazards. Due to limited data on the biological and ecological attributes of many marine species, as well as inherent uncertainties in the assessment process, climate change vulnerability assessments in the marine environment frequently focus on a limited number of taxa or geographic ranges. As climate change is already impacting marine biodiversity and fisheries, there is an urgent need to expand vulnerability assessment to cover a large number of species and areas. Here, we develop a modelling approach to synthesize data on species-specific estimates of exposure, and ecological and biological traits to undertake an assessment of vulnerability (sensitivity and adaptive capacity) and risk of impacts (combining exposure to hazards and vulnerability) of climate change (including ocean acidification) for global marine fishes and invertebrates. We use a fuzzy logic approach to accommodate the variability in data availability and uncertainties associated with inferring vulnerability levels from climate projections and species' traits. Applying the approach to estimate the relative vulnerability and risk of impacts of climate change in 1074 exploited marine species globally, we estimated their index of vulnerability and risk of impacts to be on average 52 ± 19 SD and 66 ± 11 SD, scaling from 1 to 100, with 100 being the most vulnerable and highest risk, respectively, under the ‘business-as-usual' greenhouse gas emission scenario (Representative Concentration Pathway 8.5). We identified 157 species to be highly vulnerable while 294 species are identified as being at high risk of impacts. Species that are most vulnerable tend to be large-bodied endemic species. This study suggests that the fuzzy logic framework can help estimate climate vulnerabilities and risks of exploited marine species using publicly and readily available information., Usage notesEstimated vulnerability and risk of impactsData table that contains species name, the estimated vulnerability index and risk of impact index under the RCP 8.5 scenario.Jones_Cheung_SDATA.csv Dataset Ocean acidification Borealis (via DataONE) |
| spellingShingle | Marine Risk of impact Other Invertebrates Fishes Fuzzy logic ocean acidification Jones, Miranda C. Cheung, William W. L. Data from: Using fuzzy logic to determine the vulnerability of marine species to climate change |
| title | Data from: Using fuzzy logic to determine the vulnerability of marine species to climate change |
| title_full | Data from: Using fuzzy logic to determine the vulnerability of marine species to climate change |
| title_fullStr | Data from: Using fuzzy logic to determine the vulnerability of marine species to climate change |
| title_full_unstemmed | Data from: Using fuzzy logic to determine the vulnerability of marine species to climate change |
| title_short | Data from: Using fuzzy logic to determine the vulnerability of marine species to climate change |
| title_sort | data from: using fuzzy logic to determine the vulnerability of marine species to climate change |
| topic | Marine Risk of impact Other Invertebrates Fishes Fuzzy logic ocean acidification |
| topic_facet | Marine Risk of impact Other Invertebrates Fishes Fuzzy logic ocean acidification |
| url | https://search.dataone.org/view/sha256:c0c63243cdbda59f5c41d791cac4d576e9fceca937d85196964c5582c3899c41 |