托阿尔西洋缺氧事件(TOAE)期间的异质海洋反应:风暴的潜在作用

IF 4 1区 地球科学 Q1 GEOGRAPHY, PHYSICAL Global and Planetary Change Pub Date : 2024-07-28 DOI:10.1016/j.gloplacha.2024.104533
Yuzhu Ge , Zhong Han , Thomas J. Algeo , David B. Kemp , Luya Wu
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引用次数: 0

摘要

托阿克洋缺氧事件(TOAE;∼183 Ma)是早侏罗世一次重要的高热和脱氧事件。然而,TOAE 海洋记录在营养水平、初级生产力、氧化还原条件和有机富集方面存在空间异质性。古地理、气候或水深的局部变化无法解释这种对全球超暖化的非均匀反应。迄今为止,TOAE 期间风暴活动加剧的特点,以及风暴活动在控制海洋对这一事件的反应方面可能发挥的作用,在很大程度上被忽视了。对来自多种海洋环境的 TOAE 研究的回顾表明,风暴强度与古海洋学条件有关,如营养物质供应、初级生产力、氧化还原条件和富含有机物的沉积。在中古纬度地点,TOAE 期间相对较弱的风暴活动会引起短期的水体含氧量增加,海洋环境的主要特征是缺氧(甚至缺氧)、水柱分层、初级生产力增加(由陆地径流和缺氧环境中的 P 再生推动)以及富含有机物的沉积。在低古纬度地点,TOAE 风暴活动相对较强,造成的海洋环境特点是缺氧至亚缺氧条件、水柱分层减弱、初级生产力下降(可能是由于有限的钙再生和上涌)、沉积有机物含量低以及局部鲕粒丰度高。所有古纬度的 TOAE 海洋地点都表现出:i) 海平面上升和大陆风化通量增强,这与水文循环加剧有关;ii) 双鞭毛藻活动减少,蓝藻活动增加;iii) δ15N值偏低(主要为-1‰至+3‰),这与重氮固氮作用增强有关。TOAE 海洋系统响应的空间异质性很难与陆地通量增加与海洋富营养化、初级生产力提高和富含有机物的沉积物有关的情景相协调。因此,我们假设风暴活动的强度会影响 TOAE 海洋系统,这一因素至少可以部分解释中纬度与低纬度、开放海洋环境与受限海洋环境的不同环境变化模式。重要的是,风暴活动的增加可通过垂直水柱混合作用引起跃层加深,从而促进:i)由于最小含氧区的缩小,有机物的好氧降解作用增强(沉积物有机物含量低);ii)从深海进入光照区的营养物质上涌减少(上层海洋营养贫乏);iii)固氮蓝藻(低δ15N)和钙化(类卵石形成)的大量繁殖。因此,风暴性与pycnocline深度之间的相互作用可能是影响TOAE期间海洋环境变化的一个重要因素。这些发现对目前正在经历气候变暖和热带风暴活动加剧的现代海洋具有启示意义。
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Heterogeneous marine response during the Toarcian Oceanic Anoxic Event (TOAE): The potential role of storminess

The Toarcian Oceanic Anoxic Event (TOAE; ∼183 Ma) represents an important hyperthermal and deoxygenation event in the Early Jurassic. However, TOAE marine records are spatially heterogeneous with regard to nutrient levels, primary productivity, redox conditions and organic enrichment. This non-uniform response to global hyperwarming is not readily accounted for by local variations in paleogeography, climate, or water depth. Largely overlooked to date is the intensified storm activity that characterized the TOAE, and the role that this may have played in controlling marine responses to that event. A review of TOAE studies from multiple marine environments suggests that storm intensity covaried with paleoceanographic conditions, such as nutrient availability, primary productivity, redox conditions, and organic-rich sedimentation. At mid-paleolatitude sites, relatively weak storm activity during the TOAE induced short-term watermass oxygenation, and marine settings were mainly characterized by enhanced anoxia (even euxinia), water-column stratification, increased primary productivity (fueled by terrestrial runoff and P regeneration in euxinic settings), and organic-rich sedimentation. At low-paleolatitude sites, TOAE storm activity was relatively strong, and contributed to marine environments characterized by oxic to suboxic conditions, reduced water-column stratification, decreased primary productivity (possibly due to limited P regeneration and upwelling), low sedimentary organic content, and locally high oolite abundance. TOAE marine sites at all paleolatitudes exhibit: i) sea-level rise and enhanced continental weathering fluxes linked to an intensified hydrological cycle; ii) reduced dinoflagellate and increased cyanobacterial activity; and iii) low δ15N values (mainly −1‰ to +3‰) linked to enhanced diazotrophic nitrogen fixation. The spatial heterogeneity of the response of TOAE marine systems is difficult to reconcile with scenarios linking increased terrestrial flux to marine eutrophication, primary productivity increase and organic-rich sedimentation. Consequently, we hypothesize that the intensity of storm activity influenced TOAE marine systems, and that this factor can, at least partially, account for heterogeneous patterns of environmental changes at middle versus low paleolatitudes and open versus restricted marine settings. Importantly, increased storm activity can induce pycnocline deepening via vertical water-column mixing, thereby promoting: i) enhanced aerobic degradation of organic matter (low sediment organic matter content) due to a reduced oxygen-minimum zone; ii) less nutrient upwelling from deep waters into the photic zone (nutrient-depleted upper ocean), and iii) blooms of nitrogen-fixing cyanobacteria (low δ15N) and calcification (ooid formation). Thus, the interaction between storminess and pycnocline depth is a potentially important factor affecting marine environmental changes during TOAE. These findings have implications for modern oceans now experiencing climatic warming and intensified tropical storm activity.

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来源期刊
Global and Planetary Change
Global and Planetary Change 地学天文-地球科学综合
CiteScore
7.40
自引率
10.30%
发文量
226
审稿时长
63 days
期刊介绍: The objective of the journal Global and Planetary Change is to provide a multi-disciplinary overview of the processes taking place in the Earth System and involved in planetary change over time. The journal focuses on records of the past and current state of the earth system, and future scenarios , and their link to global environmental change. Regional or process-oriented studies are welcome if they discuss global implications. Topics include, but are not limited to, changes in the dynamics and composition of the atmosphere, oceans and cryosphere, as well as climate change, sea level variation, observations/modelling of Earth processes from deep to (near-)surface and their coupling, global ecology, biogeography and the resilience/thresholds in ecosystems. Key criteria for the consideration of manuscripts are (a) the relevance for the global scientific community and/or (b) the wider implications for global scale problems, preferably combined with (c) having a significance beyond a single discipline. A clear focus on key processes associated with planetary scale change is strongly encouraged. Manuscripts can be submitted as either research contributions or as a review article. Every effort should be made towards the presentation of research outcomes in an understandable way for a broad readership.
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