Simulating potential impacts of bottom trawling on the biological carbon pump: a case study in the Benguela Upwelling System

IF 3.4 2区生物学 Q1 MARINE & FRESHWATER BIOLOGY Frontiers in Marine Science Pub Date : 2024-11-05 DOI:10.3389/fmars.2024.1387121

Claire Siddiqui, Tim Rixen, Niko Lahajnar, Tarron Lamont, Anja K. van der Plas

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Abstract

Bottom-trawl fishery is known to cause major disturbances to marine sediments as the dragging of trawl gears across the seabed fosters sediment resuspension, which can lead to organic particle remineralization and release of benthic CO2 and nutrients into bottom waters. However, its effects on carbon cycling and biological productivity, especially in highly productive regions like the Benguela Upwelling System (BUS), are less well studied. Here, we simulated carbon (C) and nutrient pathways from the trawled coastal seabed to overlying water masses that are being upwelled into the sunlit surface within the BUS, using shipboard data on sea surface and water column characteristics and published benthic CO2 emission estimates from bottom-trawled sediments. The latter reports 4.35 and 0.64 Tg C year-1 to be released from the seabed into upwelling source waters after bottom trawling in the northern (NBUS) and southern (SBUS) subsystems, respectively. Based on these values, we estimated a corresponding nitrate (N) input of 1.39 and 0.47 µmol kg-1 year-1, enhancing source water nitrate concentrations by ~5% and ~2%. Trawl-induced nitrate input into the sunlit surface could support a new production of 3.14 and 0.47 Tg C year-1 in the NBUS and SBUS, respectively, recapturing only 2/3 of CO2 released after bottom trawling into biomass, mainly due to differences in stoichiometric C:N ratios between the sediment (~9) and surface biomass (Redfield, 6.6). The remaining benthic CO2 can thereby lead to an increase in surface CO2 concentration and its partial pressure (pCO2), impeding CO2 uptake of the biological carbon pump in the BUS by 1.3 Tg C year-1, of which 1 Tg C year-1 is emitted to the atmosphere across the northern subsystem. Our results demonstrate the extent to which bottom trawling may affect the CO2 storage potential of coastal sediments on a basin-wide level, highlighting the need to better resolve small-scale sediment characteristics and C:N ratios to refine trawl-induced benthic carbon and nutrient effluxes within the BUS.

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模拟底拖网捕捞对生物碳泵的潜在影响：本格拉上升流系统案例研究

众所周知，底拖网渔业对海洋沉积物造成了严重干扰，因为拖网渔具在海底拖曳会造成沉积物悬浮，从而导致有机颗粒再矿化，并将底栖生物的二氧化碳和营养物质释放到底层水域。然而，其对碳循环和生物生产力的影响，尤其是对本格拉上升流系统（BUS）等高产地区的影响，还没有得到很好的研究。在这里，我们利用有关海面和水体特征的船载数据，以及已发表的底拖网沉积物底栖二氧化碳排放估算值，模拟了从拖网沿岸海床到上覆水体的碳和营养盐的路径，这些上覆水体在 BUS 内被上涌到阳光照射的海面。后者报告称，在北部（NBUS）和南部（SBUS）子系统进行底拖网捕捞后，从海底释放到上涌源水中的二氧化碳分别为 4.35 和 0.64 兆吨/年。根据这些数值，我们估计相应的硝酸盐（N）输入量分别为 1.39 和 0.47 µmol kg-1 year-1，使源水硝酸盐浓度分别增加约 5% 和 2%。拖网诱导的硝酸盐输入到日照表层可支持 NBUS 和 SBUS 每年分别产生 3.14 和 0.47 Tg C，仅将底拖网捕捞后释放的 CO2 的 2/3 重新捕获为生物量，这主要是由于沉积物（约 9）和表层生物量（Redfield，6.6）之间的 C:N 化学计量比的差异。因此，剩余的底栖生物二氧化碳会导致地表二氧化碳浓度及其分压（pCO2）的增加，从而阻碍 BUS 生物碳泵对二氧化碳的吸收，每年增加 1.3 Tg C，其中 1 Tg C 每年排放到整个北部子系统的大气中。我们的研究结果表明，底拖网捕捞可能会在一定程度上影响整个海盆沿岸沉积物的 CO2 储存潜力，突出表明需要更好地解析小尺度沉积物特征和 C:N 比值，以完善底拖网捕捞引起的 BUS 底栖生物碳和营养物质外流。

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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来源期刊

Frontiers in Marine Science Agricultural and Biological Sciences-Aquatic Science

CiteScore

5.10

自引率

16.20%

发文量

2443

审稿时长

14 weeks

期刊介绍： Frontiers in Marine Science publishes rigorously peer-reviewed research that advances our understanding of all aspects of the environment, biology, ecosystem functioning and human interactions with the oceans. Field Chief Editor Carlos M. Duarte at King Abdullah University of Science and Technology Thuwal is supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, policy makers and the public worldwide. With the human population predicted to reach 9 billion people by 2050, it is clear that traditional land resources will not suffice to meet the demand for food or energy, required to support high-quality livelihoods. As a result, the oceans are emerging as a source of untapped assets, with new innovative industries, such as aquaculture, marine biotechnology, marine energy and deep-sea mining growing rapidly under a new era characterized by rapid growth of a blue, ocean-based economy. The sustainability of the blue economy is closely dependent on our knowledge about how to mitigate the impacts of the multiple pressures on the ocean ecosystem associated with the increased scale and diversification of industry operations in the ocean and global human pressures on the environment. Therefore, Frontiers in Marine Science particularly welcomes the communication of research outcomes addressing ocean-based solutions for the emerging challenges, including improved forecasting and observational capacities, understanding biodiversity and ecosystem problems, locally and globally, effective management strategies to maintain ocean health, and an improved capacity to sustainably derive resources from the oceans.