Abstract
AbstractBiological hotspots along the West Antarctic Peninsula (WAP) are characterized by high phytoplankton productivity and biomass as well as spatially focused penguin foraging activity. While unique physical concentrating processes were identified in one of these hotspots, understanding the mechanisms driving the blooms at these locations is of high importance. Factors posited to explain the blooms include the upwelling of macronutrient‐ and micronutrient‐enriched modified Upper Circumpolar Deep Water (mUCDW) and the depth of the mixed layer influencing overall light availability for phytoplankton. Using shipboard trace‐metal clean incubation experiments in three different coastal biological hotspots spanning a north‐south gradient along the WAP, we tested the Canyon Hypothesis (upwelling) for enhanced phytoplankton growth. Diatoms dominated the Southern region, while the Northern region was characterized by a combination of diatoms and cryptophytes. There was ample concentration of macronutrients at the surface and no phytoplankton growth response was detected with the addition of nutrient‐enriched mUCDW water or iron solution to surface waters. For all treatments, addition of mUCDW showed no enhancement in phytoplankton growth, suggesting that local upwelling of nutrient‐enriched deep water in these hotspots was not the main driver of high phytoplankton biomass. Furthermore, the dynamics in the photoprotective pigments were consistent with the light levels used during these incubations showing that phytoplankton are able to photoacclimate rapidly to higher irradiances and that in situ cells are low light adapted. Light availability appears to be the critical variable for the development of hotspot phytoplankton blooms, which in turn supports the highly productive regional food web.
Highlights
Major penguin rookeries (Fraser and Trivelpiece 1996; Erdmann et al 2011)
Though cryptophytes increased in abundance in each treatment, overall biomass measured by total chlorophyll a (Chl a) (Tchl) decreased significantly (p < 0.001) in all light treatments (Fig. 5)
Given variable intracellular concentrations of total chlorophyll, observed chlorophyll decreases at Palmer Deep canyon (PD) can be partially due to the change in community composition from large diatoms to smaller-celled cryptophytes since the biomass gradient is controlled by cell size (Garibotti et al 2003b)
Summary
Major penguin rookeries (Fraser and Trivelpiece 1996; Erdmann et al 2011). Rapid changes in atmospheric and oceanic temperatures over the past six decades have had significant effects on the WAP ecosystem (Ducklow et al 2012). A very recent and detailed study of dissolved iron (Fe) distributions around the vicinity of Palmer Deep indicates that the Fe supplying the regional euphotic zone comes from relatively shallow sediments surrounding the canyon, delivered by mixing in the upper 100 m, suggesting that glacial meltwater and upwelling of mUCDW are relatively unimportant Fe sources (Sherrell et al 2018). This evidence counters the Canyon Hypothesis, that local canyon driven upwelling is required to supply this critical micronutrient to the surface layer (Sherrell et al 2018). Previous studies in coastal waters of the WAP have shown that inshore regions, including the three “biological hotspots” of the Canyon Hypothesis, do not show signs of Fe-limited primary production (Hopkinson et al 2007; Annett et al 2015; Carvalho et al 2016)
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