Impact of “The Blob” and “El Niño” in the SW Baja California Peninsula: Plankton and Environmental Variability of Bahia Magdalena

Jiménez-Quiroz, María del Carmen; Cervantes‐Duarte, Rafael; Funes-Rodrı́guez, René; Barón-Campis, Sofía A.; García-Romero, Felipe; Hernández‐Trujillo, Sergio; Hernández‐Becerril, David U.; González‐Armas, Rogelio; Martell‐Dubois, Raúl; Cerdeira‐Estrada, Sergio; Fernández-Méndez, José I.; González-Ania, Luis Vicente; Vásquez-Ortiz, Mario; Barrón-Barraza, Francisco Javier

doi:10.3389/fmars.2019.00025

Cited by 26 publications

(31 citation statements)

References 45 publications

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“…Our hydrographic analysis for nearshore waters in nBC clearly shows that, after removing the mean annual cycle, SST anomalies were approximately 2.0°C warmer under the 2014‐HW conditions, decreased through the 2015 upwelling season, and finally, reached values > 2.5°C when El Niño was already present in the coastal zone (Figures 5a and 5b; Table 1). These results are comparable to those previously reported for the southern section of the CCS (e.g., Durazo et al., 2017; Jiménez‐Quiroz et al., 2019; Kahru et al., 2018; Rudnick et al., 2017; Zaba & Rudnick, 2016). Zaba and Rudnick (2016) and Gentemann et al.…”

Section: Discussionsupporting

confidence: 92%

“…closely linked to the strong stratification promoted by the warm waters during the 2014-HW and El Niño (Figures 4c, 5g, and 5h;Gómez-Ocampo et al, 2017, 2018Gonzalez-Silvera et al, 2020), as well as reduced upwelling in spring-summer of 2015 ( Figure 4b; Jiménez-Quiroz et al, 2019;Robinson, 2016). Both conditions inhibited the regular upward flux of nutrients to the euphotic zone (Figures 4d, 5e, and 5f; Gonzalez- Silvera et al, 2020;Jacox & Edwards, 2011;Jacox et al, , 2018Marañon et al, 2014Marañon et al, , 2018.…”

Section: Total Chl-a Anomalies During the 2014-2015 Periodmentioning

confidence: 89%

“…By the end of 2015, a strong El Niño developed in the eastern equatorial Pacific and a pulse of warm water moved along the coast in the northeastern Pacific, producing extremely high SSTs along the coast of the CCS (Di Lorenzo & Mantua, 2016; Jacox et al., 2016; Rudnick et al., 2017). The highest positive temperature anomalies in the Baja California coast were observed in September 2015, followed by a steep decline to neutral conditions in spring 2016 (Durazo et al., 2017; Gómez‐Ocampo et al., 2017; Jiménez‐Quiroz et al., 2019), raising thus great uncertainty on the potential impacts on the chemical, biological, and oceanographic conditions of coastal waters in the southern boundary of the CCS. Here, we describe and discuss the changes in hydrographic conditions, nutrient concentrations, total chlorophyll‐ a (Chl‐ a ) and size‐structure of the phytoplankton community associated with warmer waters brought to the coastal zone of northern Baja California (nBC) during the sequential occurrence of the 2014‐HW and El Niño over the 2014–2015 period.…”

Section: Introductionmentioning

confidence: 99%

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Impacts of the 2014–2015 Warm‐Water Anomalies on Nutrients, Chlorophyll‐a and Hydrographic Conditions in the Coastal Zone of Northern Baja California

et al. 2020

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Located in the southern section of the California Current System (CCS), the coastal zone off the Baja California peninsula is an upwelling system that sustains a rich, diverse, and highly productive ecosystem. Such highprimary production is largely due to wind-driven coastal upwelling taking place mostly during the spring and early summer seasons (Linacre et al., 2010a). Besides, this region is considered an oceanographic transition zone, where the cold and low-salinity water of the California Current meets seasonally with warmer and saltier waters of tropical/subtropical origin (Durazo, 2015; Durazo et al., 2010; Kurczyn et al., 2019). Given that most of the biological and hydrographic variability in this region occurs at the seasonal and inter-annual time scales, it is valuable to understand how the system functioning is impacted by any other phenomena that increase or decrease variability at these time scales.

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Section: Discussionsupporting

confidence: 92%

Section: Total Chl-a Anomalies During the 2014-2015 Periodmentioning

confidence: 89%

Section: Introductionmentioning

confidence: 99%

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Impacts of the 2014–2015 Warm‐Water Anomalies on Nutrients, Chlorophyll‐a and Hydrographic Conditions in the Coastal Zone of Northern Baja California

et al. 2020

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“…Many of these investigations [14,25,26,28] reported the effect of these warm anomalies on sea surface temperature and phytoplankton biomass from the SCC southern region using information obtained from remote sensors. However, off the Baja California Peninsula, only the work of Linacre et al [30] and Jiménez-Quiróz et al [31] reported results regarding phytoplankton biomass and its taxonomic composition in consideration of field data from the entire water column; however, their work was based on a reduced number of cruises and a short period of time.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Cold and Warm Anomalies on Phytoplankton Pigment Composition in Waters off the Northern Baja California Peninsula (México): 2007–2016

González-Silvera

Santamaría-del-Ángel

Camacho-Ibar

et al. 2020

JMSE

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In this study, we report the response of phytoplankton community composition to cold and warm interannual events affecting the waters off the Baja California Peninsula from 2007 to 2016 based on data obtained from a single marine station (31.75oN/116.96oW). Included variables were satellite chlorophyll a, sea surface temperature (MODIS/Aqua), upwelling intensity, and field data (phytoplankton pigments, inorganic nutrients, light penetration). Phytoplankton pigments were determined by high performance liquid chromatography, and CHEMTAX software was used to determine the relative contributions of the main taxonomic groups to chlorophyll a. Our results confirm the decrease in phytoplankton biomass due to the influence of the recent Pacific Warm Anomaly (2014) and El Niño 2015-2016. However, this decrease was especially marked at the surface. When data from the entire water column was considered, this decrease was not significant, because at the subsurface Chla did not decrease as much. Nevertheless, significant changes in community composition occurred in the entire water column with Cyanobacteria (including Prochlorococcus) and Prymnesiophytes being dominant at the surface, while Chlorophytes and Prasinophytes made a strong contribution at the subsurface. Analysis of the spatial distribution of SST and satellite chlorophyll a made it possible to infer the spatial extension of these anomalies at a regional scale.

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“…Anthropocene marine heatwaves are becoming increasingly intense, more frequent and longer lasting due to climate change (Oliver et al 2018;Holbrook et al 2019). These anomalous heat stress events can have severe implications for a range of marine biota, e.g., influencing shifts in zooplankton communities, declines in key groups such as krill (Jiménez-Quiroz et al 2019;Evans et al 2020;Işkın et al 2020), die-offs and reproductive failures of sea-birds (Cavole et al 2016;Jones et al 2018;Piatt et al 2020), marine mammal strandings (Cavole et al 2016), and mass coral bleaching and mortality events (Hughes et al 2018). While surveying in situ ecosystem responses to climate change disturbances are essential to assess impact, it is also very costly.…”

Section: Introductionmentioning

confidence: 99%

Fine-tuning heat stress algorithms to optimise global predictions of mass coral bleaching

Lachs

Bythell

East

et al. 2021

Preprint

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Increasingly severe marine heatwaves under climate change threaten the persistence of many marine ecosystems. Mass coral bleaching events, caused by periods of anomalously warm sea surface temperatures (SST), have led to catastrophic levels of coral mortality globally. Remotely monitoring and forecasting such biotic responses to heat stress is key for effective marine ecosystem management. The Degree Heating Week (DHW) metric, designed to monitor coral bleaching risk, reflects the duration and intensity of heat stress events, and is computed by accumulating SST anomalies (HotSpot) relative to a stress threshold over a 12-week moving window. Despite significant improvements in the underlying SST datasets, corresponding revisions of the HotSpot threshold and accumulation window are still lacking. Here, we fine-tune the operational DHW algorithm to optimise coral bleaching predictions using the 5km satellite-based SSTs (CoralTemp v3.1) and a global coral bleaching dataset (37,871 observations, National Oceanic and Atmospheric Administration). After developing 234 test DHW algorithms with different combinations of HotSpot threshold and accumulation window, we compared their bleaching-prediction ability using spatiotemporal Bayesian hierarchical models and sensitivity-specificity analyses. Peak DHW performance was reached using HotSpot thresholds less than or equal to Maximum Monthly Mean SST and accumulation windows of 4 - 8 weeks. This new configuration correctly predicted up to an additional 310 bleaching observations compared to the operational DHW algorithm, an improved hit rate of 7.9 %. Given the detrimental impacts of marine heatwaves across ecosystems, heat stress algorithms could also be fine-tuned for other biological systems, improving scientific accuracy, and enabling ecosystem governance.

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Impact of “The Blob” and “El Niño” in the SW Baja California Peninsula: Plankton and Environmental Variability of Bahia Magdalena

Cited by 26 publications

References 45 publications

Impacts of the 2014–2015 Warm‐Water Anomalies on Nutrients, Chlorophyll‐a and Hydrographic Conditions in the Coastal Zone of Northern Baja California

Impacts of the 2014–2015 Warm‐Water Anomalies on Nutrients, Chlorophyll‐a and Hydrographic Conditions in the Coastal Zone of Northern Baja California

The Effect of Cold and Warm Anomalies on Phytoplankton Pigment Composition in Waters off the Northern Baja California Peninsula (México): 2007–2016

Fine-tuning heat stress algorithms to optimise global predictions of mass coral bleaching

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