Carbon Dioxide Removal via Macroalgae Open-ocean Mariculture and Sinking: An Earth System Modeling Study

Jiajun Wu, D. Keller, A. Oschlies
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引用次数: 17

Abstract

Abstract. In this study we investigate open-ocean macroalgae mariculture and sinking (MOS) as ocean-based carbon dioxide removal (CDR) method. Embedding a macroalgae model into an Earth system model, we simulate macroalgae mariculture in the open-ocean surface layer followed by fast sinking of the carbon-rich macroalgal biomass to the deep seafloor (depth > 3,000 m). We also test the combination of MOS with artificial upwelling (AU), which fertilizes the macroalgae by pumping nutrient-rich deeper water to the surface. The simulations are done under RCP4.5 a moderate emission pathway. When deployed globally between years 2020 and 2100, the simulated CDR potential of MOS is 270 PgC, which is further boosted by AU to 447 PgC. More than half of MOS-sequestered carbon retains in the ocean after cessation at year 2100 until year 3000. The major side effect of MOS on pelagic ecosystems is the reduction of phytoplankton net primary production (PNPP) due to the nutrient competition and canopy shading by macroalgae. MOS shrinks the mid layer oxygen minimum zones (OMZs) by reducing the organic matter export to, and remineralization in, subsurface and intermediate waters, while it creates new OMZs on the seafloor by oxygen consumption from remineralization of sunken biomass. MOS also impacts the global carbon cycle, reduces the atmospheric and terrestrial carbon reservoir when enhancing the ocean carbon reservoir. MOS also enriches the dissolved inorganic carbon in the deep ocean. Effects are mostly reversible after cessation of MOS, though recovery is not complete by year 3000. In a sensitivity experiment without remineralization of sunk MOS biomass, the entire MOS-captured carbon is permanently stored in the ocean, but the lack of remineralized nutrients causes a long-term nutrient decline in the surface layers and thus reduces PNPP. Our results suggest that MOS has a considerable potential as an ocean-based CDR method. However, MOS has inherent side effects on marine ecosystems and biogeochemistry, which will require a careful evaluation beyond this first idealized modeling study.
通过大型藻类开放海洋养殖和下沉去除二氧化碳:地球系统建模研究
摘要在本研究中,我们研究了开放海洋大型海藻的海水养殖和下沉(MOS)作为海洋二氧化碳去除(CDR)的方法。将大型藻类模型嵌入到地球系统模型中,我们模拟了大型藻类在开放海洋表层的海水养殖,然后将富含碳的大型藻类生物量快速下沉到深海海底(深度约3000米)。我们还测试了MOS与人工上升流(AU)的结合,后者通过将富含营养的深层水泵到表面来给大型藻类施肥。模拟在RCP4.5中等排放路径下进行。当在2020年至2100年间全球部署时,MOS的模拟CDR潜力为270 PgC, AU进一步将其提高到447 PgC。在2100年停止后,超过一半的mos固碳在海洋中保留到3000年。MOS对中上层生态系统的主要副作用是浮游植物净初级生产量(PNPP)的减少,这是由于营养竞争和大型藻类的遮荫作用。MOS通过减少有机物向地下和中层水体的输出和再矿化来缩小中层氧最小带(OMZs),同时通过下沉生物量再矿化的氧气消耗在海底创造新的OMZs。MOS还影响全球碳循环,在增加海洋碳库的同时减少了大气和陆地碳库。MOS还丰富了深海中溶解的无机碳。在停止服用MOS后,效果大多是可逆的,尽管到3000年恢复不完全。在没有再矿化的沉没MOS生物量敏感性实验中,整个MOS捕获的碳被永久储存在海洋中,但缺乏再矿化的营养物质导致表层营养物质长期下降,从而降低了PNPP。我们的结果表明,MOS作为一种基于海洋的CDR方法具有相当大的潜力。然而,MOS对海洋生态系统和生物地球化学有固有的副作用,这需要在第一次理想化的建模研究之外进行仔细的评估。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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