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Progressive delays in the timing of sardine migration in the southwest Indian Ocean
Phenological shifts represent one of the most robust bioindicators of climate change. While considerable multidecadal records of plant and animal phenology exist for the northern hemisphere, few noteworthy records are available for the southern hemisphere. We present one of the first phenological re...
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| Published in: | South African Journal of Science 2019-07, Vol.115 (7-8), p.61-66 |
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| container_end_page | 66 |
| container_issue | 7-8 |
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| container_title | South African Journal of Science |
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| creator | Portwig, Heinrich Grab, Stefan W. Fitchett, Jennifer M. |
| description | Phenological shifts represent one of the most robust bioindicators of climate change. While considerable multidecadal records of plant and animal phenology exist for the northern hemisphere, few noteworthy records are available for the southern hemisphere. We present one of the first phenological records of fish migration for the southern hemisphere, and one of the only phenological records for the southwest Indian Ocean. The so-called ‘sardine run’ – an annual winter migration of sardines, northeast of their summer spawning grounds on the Agulhas Bank off the coast of Durban, South Africa – has been well documented in local newspapers given the importance placed on fishing and fishing-tourism in the region. An analysis of the first arrival dates of sardines reveals a 1.3 day per decade delay over the period 1946–2012. Although this phenological shift reveals a poor association with sea surface temperatures (SST), it coincides with a poleward shift in the position of the 21 °C mean annual SST isotherm – the threshold temperature for sardine populations. The timing of sardine arrivals near Durban corresponds closely with the number of mid-latitude cyclones passing over the Durban coastline during the months of April and May. The strength of the run is strongly associated with ENSO conditions. The complex suite of factors associated with this phenological shift poses challenges in accurately modelling the future trajectory for this migratory event.Significance:The sardine run, a significant event for tourism and fisheries, is occurring progressively later in the year.The incidence of failed sardine runs has increased in frequency over the period 1946–2012.These changes in fish migration phenology coincide with a poleward shift in the position of the 21 °C mean annual SST isotherm.The strength in the sardine run is strongly associated with ENSO conditions. |
| doi_str_mv | 10.17159/sajs.2019/5887 |
| format | article |
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The complex suite of factors associated with this phenological shift poses challenges in accurately modelling the future trajectory for this migratory event.Significance:The sardine run, a significant event for tourism and fisheries, is occurring progressively later in the year.The incidence of failed sardine runs has increased in frequency over the period 1946–2012.These changes in fish migration phenology coincide with a poleward shift in the position of the 21 °C mean annual SST isotherm.The strength in the sardine run is strongly associated with ENSO conditions.</description><identifier>ISSN: 0038-2353</identifier><identifier>EISSN: 1996-7489</identifier><identifier>DOI: 10.17159/sajs.2019/5887</identifier><language>eng</language><publisher>Pretoria: Academy of Science for South Africa (ASSAf)</publisher><subject>Analysis ; Bioindicators ; Biological indicators ; Climate change ; Clupeidae ; Cyclones ; El Nino ; ENSO ; Fish migration ; Fish populations ; Fisheries ; Fishing ; Fishing (Recreation) ; Food ; Food supply ; Global temperature changes ; Indicator species ; Mid-latitude cyclones ; Northern Hemisphere ; Oceans ; Phenology ; Population ; Sardine run ; Sardines ; Sea surface temperature ; Southern Hemisphere ; Spawning ; Spawning grounds ; Tourism</subject><ispartof>South African Journal of Science, 2019-07, Vol.115 (7-8), p.61-66</ispartof><rights>COPYRIGHT 2019 African Online Scientific Information Systems (Pty) Ltd t/a AOSIS</rights><rights>2019. 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The complex suite of factors associated with this phenological shift poses challenges in accurately modelling the future trajectory for this migratory event.Significance:The sardine run, a significant event for tourism and fisheries, is occurring progressively later in the year.The incidence of failed sardine runs has increased in frequency over the period 1946–2012.These changes in fish migration phenology coincide with a poleward shift in the position of the 21 °C mean annual SST isotherm.The strength in the sardine run is strongly associated with ENSO conditions.</description><subject>Analysis</subject><subject>Bioindicators</subject><subject>Biological indicators</subject><subject>Climate change</subject><subject>Clupeidae</subject><subject>Cyclones</subject><subject>El Nino</subject><subject>ENSO</subject><subject>Fish migration</subject><subject>Fish populations</subject><subject>Fisheries</subject><subject>Fishing</subject><subject>Fishing 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| ispartof | South African Journal of Science, 2019-07, Vol.115 (7-8), p.61-66 |
| issn | 0038-2353 1996-7489 |
| language | eng |
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| source | Publicly Available Content Database |
| subjects | Analysis Bioindicators Biological indicators Climate change Clupeidae Cyclones El Nino ENSO Fish migration Fish populations Fisheries Fishing Fishing (Recreation) Food Food supply Global temperature changes Indicator species Mid-latitude cyclones Northern Hemisphere Oceans Phenology Population Sardine run Sardines Sea surface temperature Southern Hemisphere Spawning Spawning grounds Tourism |
| title | Progressive delays in the timing of sardine migration in the southwest Indian Ocean |
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