Environmental drivers of under-ice phytoplankton bloom dynamics in the Arctic Ocean

Mathieu Ardyna,Gauthier Verin,C J Mundy,Kevin R Arrigo,Jean-Éric Tremblay,Marcel Nicolaus,Pierre-Luc Grondin,Eva Alou-Font,Philipp Assmy,Hervé Claustre,Laurent Oziel,Patrick Raimbault,Michel Gosselin,Joséphine Ras,Marcel Babin,Gert Van Dijken,Matthew M Mills,Léo Lacour

doi:10.1525/elementa.430

Abstract

The decline of sea-ice thickness, area, and volume due to the transition from multi-year to first-year sea ice has improved the under-ice light environment for pelagic Arctic ecosystems. One unexpected and direct consequence of this transition, the proliferation of under-ice phytoplankton blooms (UIBs), challenges the paradigm that waters beneath the ice pack harbor little planktonic life. Little is known about the diversity and spatial distribution of UIBs in the Arctic Ocean, or the environmental drivers behind their timing, magnitude, and taxonomic composition. Here, we compiled a unique and comprehensive dataset from seven major research projects in the Arctic Ocean (11 expeditions, covering the spring sea-ice-covered period to summer ice-free conditions) to identify the environmental drivers responsible for initiating and shaping the magnitude and assemblage structure of UIBs. The temporal dynamics behind UIB formation are related to the ways that snow and sea-ice conditions impact the under-ice light field. In particular, the onset of snowmelt significantly increased under-ice light availability (&gt;0.1–0.2 mol photons m–2 d–1), marking the concomitant termination of the sea-ice algal bloom and initiation of UIBs. At the pan-Arctic scale, bloom magnitude (expressed as maximum chlorophyll a concentration) was predicted best by winter water Si(OH)4 and PO43– concentrations, as well as Si(OH)4:NO3– and PO43–:NO3– drawdown ratios, but not NO3– concentration. Two main phytoplankton assemblages dominated UIBs (diatoms or Phaeocystis), driven primarily by the winter nitrate:silicate (NO3–:Si(OH)4) ratio and the under-ice light climate. Phaeocystis co-dominated in low Si(OH)4 (i.e., NO3:Si(OH)4 molar ratios &gt;1) waters, while diatoms contributed the bulk of UIB biomass when Si(OH)4 was high (i.e., NO3:Si(OH)4 molar ratios &lt;1). The implications of such differences in UIB composition could have important ramifications for Arctic biogeochemical cycles, and ultimately impact carbon flow to higher trophic levels and the deep ocean.

Highlights

The Arctic Ocean (AO) is changing profoundly, with drastic reductions in both sea-ice area and thickness (Kwok, 2018; Stroeve and Notz, 2018)
We define a underice blooms (UIBs) as a phytoplankton bloom that starts and develops beneath a significant concentration of sea ice. These blooms are distinct from sea-ice algae that become detached from the bottom sea ice (Mundy et al, 2014) and from blooms at the sea-ice edge that are advected under the sea ice (Johnsen et al, 2018)
Sea-ice, light, hydrography and nutrient conditions All of the sea ice sampled in this study was first year sea ice

Summary

Introduction

The Arctic Ocean (AO) is changing profoundly, with drastic reductions in both sea-ice area and thickness (Kwok, 2018; Stroeve and Notz, 2018). Sea-ice melt is beginning earlier in the year while freeze-up is delayed; more solar radiation is reaching the upper ocean than it has in the past (Nicolaus et al, 2012; Arndt and Nicolaus, 2014; Katlein et al, 2019). Such modifications result in a substantially thinner sea-ice cover that is more prone to deformation. ‖ Département de biologie et Q uébec-Océan, Université Laval, Québec, Québec, CA. ** Institut des sciences de la mer de Rimouski, Université du Québec à Rimouski, Rimouski, Québec, CA. The main ecological drivers behind the initiation, structure and productivity of UIBs and their spatial distribution and interannual variability remain to be assessed at a pan-Arctic scale

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