1984-2017年秘鲁大陆架微量元素铁的时空变化

IF 3.8 3区 地球科学 Q1 OCEANOGRAPHY
Yuanyuan Gu , Mark James Hopwood , Martha Gledhill , Insa Rapp , Kathrin Wuttig , Eric Pieter Achterberg
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引用次数: 0

摘要

受最小含氧带(OMZ)沉积物输入的影响,水体中的溶解铁(dFe)浓度很高,约为 10-100 nmol L-1。然而,由于研究海洋痕量金属动态时普遍依赖于快照横断面,因此对 dFe 浓度的时间变化界定不清。自 20 世纪 80 年代以来,多次巡航活动对秘鲁大陆架的铁动态进行了研究,特别是南纬 9-17 度之间,那里的大陆架宽阔、生产力极高,已知其底栖生物的 dFe 流出量是全球测得的最高值之一。这一广泛的长期数据集使我们能够研究 dFe 浓度的年际变化及其对厄尔尼诺-南方涛动(ENSO)事件的响应。通过合并 1984-2017 年间 11 次巡航的数据,我们能够评估一个主要 OMZ 的 dFe 年际时间尺度动态。dFe 平均浓度对厄尔尼诺/南方涛动变化敏感的区域仅限于深度在 50-150 米之间的次表层,特别是在距离海岸线 50 公里以内的狭长沿海区域。在厄尔尼诺现象期间,次表层 dFe 浓度一般较低(0.7-15.4 nmol L-1),而在寒冷的厄尔尼诺/南方涛动阶段,dFe 浓度相对较高,变化范围更大(1.1-52.1 nmol L-1)。风速与表层/次表层 dFe 之间的反比关系非常明显。在次表层,这可能是由于当有利于上涌的风放松时,dFe 沿等压线的离岸传输增强,这与之前概述的理论相符。表层(40 米)dFe 的变化可能与稀释和/或氧化效应有关,这取决于风驱动的水柱混合强度。上升流将富含宏量营养元素的海水带入了透光层,但其强度对上层 dFe 浓度的影响有限,这可能是由于受到了沿岸地转流的影响。研究发现,秘鲁北部近海区域表层叶绿素-a(Chl-a)的年际变化与 dFe 浓度相关。这与生物测定实验和气候残留硝酸盐浓度相一致,两者都表明在秘鲁北部陆架内外浮游植物的生长受到近铁的限制。总之,我们的工作强调了在世界上经济最重要的渔业地区之一,物理因素对铁供应量短期变化的重要驱动作用,并表明尽管 dFe 浓度存在明显的时空变化,但厄尔尼诺/南方涛动阶段对 dFe 供应量有影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Spatial and temporal variations in the micronutrient Fe across the Peruvian shelf from 1984 to 2017

High dissolved iron (dFe) concentrations of the order of 10–100 nmol L−1 are a feature of waters influenced by sedimentary inputs in oxygen minimum zones (OMZ). However, the temporal development of dFe concentrations is poorly defined due to a general reliance on snapshot cross-shelf sections to study marine trace metal dynamics. Multiple cruise campaigns since the 1980s have investigated Fe dynamics over the Peruvian shelf, particularly between 9° S and 17°S where the shelf is broad, extremely productive and known to feature benthic dFe effluxes which are amongst the highest measured globally. This extensive long-term dataset uniquely allows us to study the interannual variability in dFe concentrations and their response to El Niño–Southern Oscillation (ENSO) events. By combining data from 11 cruises during the period 1984–2017 we are able to evaluate dFe dynamics on interannual timescales in a major OMZ. The region where average dFe concentrations are sensitive to variations in ENSO is confined to a subsurface layer at depths between 50 and 150 m, particularly in the narrow coastal region within 50 km of the coastline. Subsurface dFe concentrations were generally low during El Niño events (0.7–15.4 nmol L−1) and relatively high with a wider range of variability during the cold ENSO phase (1.1–52.1 nmol L−1). Inverse relationships between wind speed and surface/subsurface dFe were evident. In the subsurface layer, this may be attributable to enhanced dFe offshore transport along isopycnals when upwelling-favorable winds relax in accordance with previously outlined theories. Surface layer (<40 m) dFe variability was likely associated with a dilution and/or oxidation effect depending on the strength of wind driven water column mixing. Upwelling brings macronutrient-rich water into the euphotic zone, but its intensity had a limited impact on upper layer dFe concentrations possibly due to the influence of an onshore geostrophic flow. Interannual variability in surface chlorophyll-a (Chl-a) was found to correlate with dFe concentration in the offshore zone of northern Peru. This is consistent with bioassay experiments and climatological residual nitrate concentrations which both indicate proximal Fe limitation of phytoplankton growth over and beyond the northern Peruvian shelf. Overall, our work highlights the importance of physical factors driving short-term variations in Fe availability in one of the world’s most economically important fishery regions and suggests that, despite pronounced spatial and temporal variability in dFe concentrations, the ENSO phase has an impact on dFe availability.

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来源期刊
Progress in Oceanography
Progress in Oceanography 地学-海洋学
CiteScore
7.20
自引率
4.90%
发文量
138
审稿时长
3 months
期刊介绍: Progress in Oceanography publishes the longer, more comprehensive papers that most oceanographers feel are necessary, on occasion, to do justice to their work. Contributions are generally either a review of an aspect of oceanography or a treatise on an expanding oceanographic subject. The articles cover the entire spectrum of disciplines within the science of oceanography. Occasionally volumes are devoted to collections of papers and conference proceedings of exceptional interest. Essential reading for all oceanographers.
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