Abstract
The subarctic Pacific is one of the major high-nitrate, low-chlorophyll (HNLC) regions where marine productivity is greatly limited by the supply of iron (Fe) in the region. There is a distinct seasonal difference in the chlorophyll concentrations of the east and west sides of the subarctic Pacific because of the differences in their driving mechanisms. In the western subarctic Pacific, two chlorophyll concentration peaks occur: the peak in spring and early summer is dominated by diatoms, while the peak in late summer and autumn is dominated by small phytoplankton. In the eastern subarctic Pacific, a single chlorophyll concentration peak occurs in late summer, while small phytoplankton dominate throughout the year. In this study, two one-dimensional (1D) physical–biological models with Fe cycles were applied to Ocean Station K2 (Stn. K2) in the western subarctic Pacific and Ocean Station Papa (Stn. Papa) in the eastern subarctic Pacific. These models were used to study the role of Fe limitation in regulating the seasonal differences in phytoplankton populations by reproducing the seasonal variability in ocean properties in each region. The results were reasonably comparable with observational data, i.e., cruise and Biogeochemical-Argo data, showing that the difference in bioavailable Fe (BFe) between Stn. K2 and Stn. Papa played a dominant role in controlling the respective seasonal variabilities of diatom and small phytoplankton growth. At Stn. Papa, there was less BFe, and the Fe limitation of diatom growth was two times as strong as that at Stn. K2; however, the difference in the Fe limitation of small phytoplankton growth between these two regions was relatively small. At Stn. K2, the decrease in BFe during summer reduced the growth rate of diatoms, which led to a rapid reduction in diatom biomass. Simultaneously, the decrease in BFe had little impact on small phytoplankton growth, which helped maintain the relatively high small phytoplankton biomass until autumn. The experiments that stimulated a further increase in atmospheric Fe deposition also showed that the responses of phytoplankton primary production in the eastern subarctic Pacific were stronger than those in the western subarctic Pacific but contributed little to primary production, as the Fe limitation of phytoplankton growth was replaced by macronutrient limitation.
Highlights
Marine phytoplankton have been found to be a key component in marine ecosystems and the global carbon cycle (Fasham, 2003)
The model results showed that the lower level of bioavailable Fe (BFe) in the eastern subarctic Pacific resulted in a Fe limitation on diatom growth that was two times as strong as that in the western subarctic Pacific
The weaker Fe limitation in the western subarctic Pacific subsequently caused the diatom growth rate to be 86% higher than that in the eastern subarctic Pacific, with diatom blooms occurring in spring and early summer
Summary
Marine phytoplankton have been found to be a key component in marine ecosystems and the global carbon cycle (Fasham, 2003). The strong winter mixing at each station entrains nitrate and silicate into the mixed layer, resulting in an increase in their concentrations in the winter Both the western and the eastern subarctic Pacific are characterized as high-nitrate, low-chlorophyll (HNLC) regions. The seasonal variability of chlorophyll is weak (0.2–0.6 mg m−3), but concentrations are slightly higher in late summer (Mochizuki et al, 2002; Pena and Varela, 2007; Matsumoto et al, 2014) The mechanisms underlying these marine ecosystems on the two sides of the subarctic Pacific have been actively investigated, and they have been found to be related to the differences in Fe bioavailability in explored in several studies (Banse and English, 1999; Harrison et al, 1999; Fujii et al, 2007; Nishioka et al, 2021)
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