Cascading effects augment the direct impact of CO2 on phytoplankton growth in a biogeochemical model

IF 4.7 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Elementa-Science of the Anthropocene Pub Date : 2022-01-01 DOI:10.1525/elementa.2021.00104

Miriam Seifert, C. Nissen, B. Rost, J. Hauck

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引用次数: 4

Abstract

Atmospheric and oceanic CO2 concentrations are rising at an unprecedented rate. Laboratory studies indicate a positive effect of rising CO2 on phytoplankton growth until an optimum is reached, after which the negative impact of accompanying acidification dominates. Here, we implemented carbonate system sensitivities of phytoplankton growth into our global biogeochemical model FESOM-REcoM and accounted explicitly for coccolithophores as the group most sensitive to CO2. In idealized simulations in which solely the atmospheric CO2 mixing ratio was modified, changes in competitive fitness and biomass are not only caused by the direct effects of CO2, but also by indirect effects via nutrient and light limitation as well as grazing. These cascading effects can both amplify or dampen phytoplankton responses to changing ocean pCO2 levels. For example, coccolithophore growth is negatively affected both directly by future pCO2 and indirectly by changes in light limitation, but these effects are compensated by a weakened nutrient limitation resulting from the decrease in small-phytoplankton biomass. In the Southern Ocean, future pCO2 decreases small-phytoplankton biomass and hereby the preferred prey of zooplankton, which reduces the grazing pressure on diatoms and allows them to proliferate more strongly. In simulations that encompass CO2-driven warming and acidification, our model reveals that recent observed changes in North Atlantic coccolithophore biomass are driven primarily by warming and not by CO2. Our results highlight that CO2 can change the effects of other environmental drivers on phytoplankton growth, and that cascading effects may play an important role in projections of future net primary production.

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在生物地球化学模型中，级联效应增加了二氧化碳对浮游植物生长的直接影响

大气和海洋的二氧化碳浓度正以前所未有的速度上升。实验室研究表明，在达到最佳水平之前，二氧化碳的上升对浮游植物的生长有积极影响，在此之后，随之而来的酸化的负面影响占主导地位。在这里，我们将浮游植物生长的碳酸盐系统敏感性引入到我们的全球生物地球化学模型FESOM-REcoM中，并明确地将颗石藻作为对CO2最敏感的一类。在仅修改大气CO2混合比的理想化模拟中，竞争适应度和生物量的变化不仅是由CO2的直接影响引起的，而且还受到营养和光照限制以及放牧的间接影响。这些级联效应可以放大或抑制浮游植物对海洋二氧化碳分压水平变化的反应。例如，球石藻的生长受到未来二氧化碳分压的直接负面影响，也受到光照限制变化的间接负面影响，但这些影响被小型浮游植物生物量减少导致的营养限制减弱所补偿。在南大洋，未来的二氧化碳分压减少了小型浮游植物的生物量，从而减少了浮游动物的首选猎物，这减少了硅藻的放牧压力，使它们能够更强烈地增殖。在包含二氧化碳驱动的变暖和酸化的模拟中，我们的模型显示，最近观测到的北大西洋球石藻生物量的变化主要是由变暖驱动的，而不是由二氧化碳驱动的。我们的研究结果强调，二氧化碳可以改变其他环境驱动因素对浮游植物生长的影响，并且级联效应可能在未来净初级产量的预测中发挥重要作用。

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来源期刊

Elementa-Science of the Anthropocene Earth and Planetary Sciences-Atmospheric Science

CiteScore

6.90

自引率

5.10%

发文量

审稿时长

16 weeks

期刊介绍： A new open-access scientific journal, Elementa: Science of the Anthropocene publishes original research reporting on new knowledge of the Earth’s physical, chemical, and biological systems; interactions between human and natural systems; and steps that can be taken to mitigate and adapt to global change. Elementa reports on fundamental advancements in research organized initially into six knowledge domains, embracing the concept that basic knowledge can foster sustainable solutions for society. Elementa is published on an open-access, public-good basis—available freely and immediately to the world.