海底火山与热液活动对水体锶和锂同位素特征的影响（TONGA）

IF 2.8 2区生物学 Q1 MARINE & FRESHWATER BIOLOGY

Frontiers in Marine Science Pub Date : 2024-11-04 DOI:10.3389/fmars.2024.1304930

Valérie Chavagnac, Christine Destrigneville, Cédric Boulart, Vincent Taillandier, Nathalie Vigier, Cecile Guieu, Sophie Bonnet

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引用次数: 0

摘要

在 TONGA 巡航（2019 年）期间，收集了海水样本，以评估火山爆发和海底热液系统对水体的影响。为此，对两个地点进行了调查，第一个地点直接位于新拉特艾基岛（2019 年 10 月喷发）的影响范围内，第二个地点则显示出正在进行的海底热液活动。这两个地点的总锶（TSr）和锂（TLi）浓度分别介于 94.4 至 152.3 µmol/L 和 13.2 至 203.5 µmol/L 之间。综合来看，水体中所有样本的 TSr 和 TLi 浓度都高于低营养水。火山爆发和海底热液活动（如火山灰、微粒、气体凝结物）都会向水体输送大量的 TSr 和 TLi。TSr 与 TLi 的分布呈现负斜率或正斜率的线性趋势。在两个地点的水体中都观察到了负相关，即直接受火山喷发影响的地点和有热液活动的火山附近地点。在受海底热液影响的地点，观察到 TSr 与 TLi 呈正相关，这与与黑烟有关的热液羽流一致。87Sr/86Sr 比率介于 0.709147 和 0.709210 之间，δ7Li 值介于 +10.1 和 +37.6 之间。虽然测得的 87Sr/86Sr 比值中有 92% 与寡营养水体的平均值一致，但一旦与 δ7Li 值结合起来，只有 20% 的比值仍在这一范围内。δ7Li值的范围很广，从海面一直下降到大约 140 mbsl，然后在更深处上升，同时根据溶解的无机碳浓度确定不同的线性趋势。δ7Li 值的变化反映了热液作用、矿物与海水的相互作用以及潜在的生物与环境的相互作用。在这项研究的特定地质环境中，热液活动和火山活动都在起作用，要区分这两种活动对水体的影响，就需要综合利用锶和锂示踪剂的元素和同位素特征。

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Impact of submarine volcanic versus hydrothermal activity onto the strontium and lithium isotopic signatures of the water column (TONGA)

During the TONGA cruise (2019), seawater samples were collected to assess the effect of volcanic eruption versus submarine hydrothermal system on the water column. For this purpose, two locations were investigated, the first one located directly under the influence of the New Late’iki island (eruption in October 2019), and the second one showing ongoing submarine hydrothermal activity. At both locations, the total strontium (TSr) and lithium (TLi) concentrations vary between 94.4 and 152.3 µmol/L and 13.2 and 203.5 µmol/L, respectively. When combined, TSr and TLi concentrations of all samples in the water column are higher than those of the oligotrophic water. Both volcanic eruption and submarine hydrothermal activity (e.g. volcanic ashes, particles, gas condensate) can deliver substantial amount of TSr and TLi to the water column. The distribution of TSr versus TLi evidences linear trends either with a negative or positive slope. The negative correlation is observed in the water column at both sites, directly under the influence of the eruption and in the vicinity of the volcano with hydrothermal activity. The positive TSr versus TLi correlation is observed at site under submarine hydrothermal influence and is in line with black smokers related hydrothermal plumes. The 87Sr/86Sr ratios vary between 0.709147 and 0.709210 and δ7Li values vary between +10.1 and +37.6 ‰. While 92% of the measured 87Sr/86Sr ratios are in line with the mean value of oligotrophic waters, once combined with the δ7Li values, only 20% of them remains within this field. The wide range of δ7Li values decreases from sea-surface down to ~140 mbsl, before increasing at greater depth, while defining different linear trend according to the dissolved inorganic carbon concentrations. The variability of δ7Li values reflect hydrothermal contribution, mineral–seawater interaction and potentially biology–environment interaction. In the particular geological setting of the study, where both hydrothermal and volcanic activities were at play, disentangling both contributions on water column implies a combined use of elemental and isotopic signatures of Sr and Li tracers.

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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.