Abstract
Abstract. As environmental conditions evolve with rapidly increasing atmospheric CO2, biological communities will change as species reorient their distributions, adapt, or alter their abundance. In the surface ocean, dissolved inorganic carbon (DIC) has been increasing over the past several decades as anthropogenic CO2 dissolves into seawater, causing acidification (decreases in pH and carbonate ion concentration). Calcifying phytoplankton, such as coccolithophores, are thought to be especially vulnerable to ocean acidification. How coccolithophores will respond to increasing carbon input has been a subject of much speculation and inspired numerous laboratory and mesocosm experiments, but how they are currently responding in situ is less well documented. In this study, we use coccolithophore (haptophyte) pigment data collected at the Bermuda Atlantic Time-series Study (BATS) site together with satellite estimates (1998–2014) of surface chlorophyll and particulate inorganic carbon (PIC) as a proxy for coccolithophore abundance to show that coccolithophore populations in the North Atlantic subtropical gyre have been increasing significantly over the past 2 decades. Over 1990–2012, we observe a 37 % increase in euphotic zone-integrated coccolithophore pigment abundance at BATS, though we note that this is sensitive to the period being analyzed. We further demonstrate that variability in coccolithophore chlorophyll a here is positively correlated with variability in nitrate and DIC (and especially the bicarbonate ion) in the upper 30 m of the water column. Previous studies have suggested that coccolithophore photosynthesis may benefit from increasing CO2, but calcification may eventually be hindered by low pHT (< 7.7). Given that DIC has been increasing at BATS by ∼ 1.4 µmol kg−1 yr−1 over the period of 1991–2012, we speculate that coccolithophore photosynthesis and perhaps calcification may have increased in response to anthropogenic CO2 input.
Highlights
Coccolithophores are the most abundant type of calcifying phytoplankton in the ocean
Belonging to the phytoplankton group known as haptophytes, coccolithophores generate a substantial fraction of the primary production in many diverse marine environments from cold, sub-polar waters to warm, tropical waters (Thierstein and Young, 2004)
Based on the relative concentrations of 19 -but to 19 -hex measured at Bermuda Atlantic Time-series Study (BATS), we subtracted out the phytoplankton pigment contribution that contains both 19 -hex and 19 -but, as in Letelier et al (1993), and multiply the remaining 19 -hex concentration by a 19 -hex to chlorophyll a (Chl a) ratio found in calcifying haptophytes (Letelier et al, 1993)
Summary
Coccolithophores are the most abundant type of calcifying phytoplankton in the ocean. Belonging to the phytoplankton group known as haptophytes, coccolithophores generate a substantial fraction of the primary production in many diverse marine environments from cold, sub-polar waters to warm, tropical waters (Thierstein and Young, 2004). Coccolithophores produce calcium carbonate (CaCO3) shells that sink to the deep ocean forming chalk deposits and are important for global biogeochemical cycling of carbon and climate feedbacks. Coccolithophores comprise the base of many marine food webs and are widespread throughout the world ocean (Boyd et al, 2015). Changes in coccolithophore abundance could have far-reaching effects from the ecosystem level to global carbon cycling (Boyd et al, 2015).
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