Abstract
The structure of marine phytoplankton communities in the North Atlantic Ocean varies considerably on seasonal, interannual, and longer timescales in response to environmental change. However, the causes of ecological variability on interannual and longer timescales remain uncertain. Here, using a half-century of observations, we compare changes in atmospheric forcing (surface wind speed and heat fluxes) and ocean surface properties (sea surface temperature, mixed layer depth, thermal stratification, and turbulent kinetic energy) with variability in total phytoplankton biomass and the abundances of diatoms and dinoflagellates, as measured by the Continuous Plankton Recorder survey. On seasonal timescales, there is a clear connection between observed changes in the physical environment and the phytoplankton assemblages. Strong turbulence, deep mixed layers, and weak stratification decrease diatom abundance in the subpolar gyre, but increase diatoms in the subtropical gyre, a pattern broadly consistent with growth limitation of phytoplankton in high and low latitudes by light and nutrients, respectively. In contrast, dinoflagellates prosper in stratified, weakly turbulent conditions in sampled portions of the subpolar and subtropical gyres. On interannual to multidecadal timescales, however, the links between observed ecological and physical changes are much weaker. The physical mechanisms that differentiate the fates of diatoms and dinoflagellates on seasonal timescales do not appear to control their longer-term variability, perhaps because year-to-year variability in the phytoplankton assemblages is greater than in the physical drivers. This suggests that other biological (e.g., zooplankton grazing, chaos in the plankton) or physical mechanisms (e.g., changes in ocean circulation) may play important regulatory roles.
Highlights
The structure of marine phytoplankton communities in the North Atlantic Ocean varies considerably on seasonal, interannual, and longer timescales in response to environmental change
The Continuous Plankton Recorder (CPR) survey has sampled greater than 100 common diatom and dinoflagellate species over the North Atlantic subpolar and northern subtropical gyres since 1958, and provides an internally consistent and unparalleled view of surface ecological variability (Richardson et al 2006)
Seasonal environmental change and biological responses Our analysis confirms a cornerstone of biological oceanography: clear and widespread connections between seasonal cycles of key environmental drivers and seasonal cycles of total phytoplankton biomass and the abundance of diatoms and dinoflagellates in the North Atlantic (Margalef 1978; Taylor et al 1993; Barton et al 2013)
Summary
The structure of marine phytoplankton communities in the North Atlantic Ocean varies considerably on seasonal, interannual, and longer timescales in response to environmental change. The primary physical drivers that are believed to shape phytoplankton community structure include wind forcing and surface buoyancy fluxes from the atmosphere, which alter the physical environment (turbulent kinetic energy [TKE] in the mixed layer, sea surface temperature [SST], mixed layer depth [MLD], and upper water column stratification) These key physical drivers potentially impact the light and nutrients experienced by phytoplankton in the ocean surface (Sverdrup 1953; Follows and Dutkiewicz 2002) and the interactions and imbalances between predators and prey (Behrenfeld 2010; Behrenfeld and Boss 2014). The goal of our analysis is to evaluate and assess the statistical links between each phytoplankton metric (PCI, abundance of diatom and dinoflagellates) and likely physical drivers for different timescales across the northern subtropical and subpolar North Atlantic Ocean
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