Collaborative Research: Impact of Mesoscale Processes on Iron Supply and Phytoplankton Dynamics in the Ross Sea

合作研究：中尺度过程对罗斯海铁供应和浮游植物动力学的影响

• 批准号: 0944174
• 负责人: Peter Sedwick
• 金额: $ 70.4万
• 依托单位: Old Dominion University Research Foundation
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-07-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0944174&HistoricalAwards=false
• 关键词: Collaborative; Research; Impact; Mesoscale; Processes

The Ross Sea continental shelf is one of the most productive areas in the Southern Ocean, and may comprise a significant, but unaccounted for, oceanic CO2 sink, largely driven by phytoplankton production. The processes that control the magnitude of primary production in this region are not well understood, but data suggest that iron limitation is a factor. Field observations and model simulations indicate four potential sources of dissolved iron to surface waters of the Ross Sea: (1) circumpolar deep water intruding from the shelf edge; (2) sediments on shallow banks and nearshore areas; (3) melting sea ice around the perimeter of the polynya; and (4) glacial meltwater from the Ross Ice Shelf. The principal investigators hypothesize that hydrodynamic transport via mesoscale currents, fronts, and eddies facilitate the supply of dissolved iron from these four sources to the surface waters of the Ross Sea polynya. These hypotheses will be tested through a combination of in situ observations and numerical modeling, complemented by satellite remote sensing. In situ observations will be obtained during a month-long cruise in the austral summer. The field data will be incorporated into model simulations, which allow quantification of the relative contributions of the various hypothesized iron supply mechanisms, and assessment of their impact on primary production. The research will provide new insights and a mechanistic understanding of the complex oceanographic phenomena that regulate iron supply, primary production, and biogeochemical cycling. The research will thus form the basis for predictions about how this system may change in a warming climate. The broader impacts include training of graduate and undergraduate students, international collaboration, and partnership with several ongoing outreach programs that address scientific research in the Southern Ocean. The research also will contribute to the goals of the international research programs ICED (Integrated Climate and Ecosystem Dynamics) and GEOTRACES (Biogeochemical cycling and trace elements in the marine environment).

罗斯海大陆架是南大洋最具生产力的地区之一，可能包括一个重要的，但未说明的海洋二氧化碳汇，主要由浮游植物生产驱动。 控制该地区初级生产规模的过程尚不清楚，但数据表明，铁的限制是一个因素。实地观测和模型模拟表明，罗斯海表层沃茨中溶解铁有四个潜在来源：（1）从陆架边缘侵入的环极深水;（2）浅岸和近岸地区的沉积物;（3）冰间湖周边融化的海冰;（4）罗斯冰架的冰川融水。 主要研究人员假设，通过中尺度流，锋和漩涡的水动力运输促进溶解铁从这四个来源的罗斯海冰间湖的表面沃茨的供应。这些假设将通过现场观测和数值模拟相结合的方式加以检验，并辅之以卫星遥感。将在南半球夏季为期一个月的航行中进行实地观测。 实地数据将被纳入模型模拟，从而可以量化各种假设的铁供应机制的相对贡献，并评估其对初级生产的影响。这项研究将为调节铁供应，初级生产和地球化学循环的复杂海洋学现象提供新的见解和机械理解。因此，这项研究将成为预测该系统在气候变暖中可能如何变化的基础。 更广泛的影响包括研究生和本科生的培训，国际合作，以及与几个正在进行的外展计划，解决在南大洋的科学研究的伙伴关系。该研究还将有助于实现国际研究计划ICED（综合气候和生态系统动力学）和GEOTRACES（海洋环境中的生物地球化学循环和微量元素）的目标。