The sensitivity of the equatorial pacific ODZ to particulate organic matter remineralization in a climate model under pre-industrial conditions

IF 3.1 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
Paul Lerner , Anastasia Romanou , David Nicholson , Maxwell Kelley , Reto Ruedy , Gary Russell
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引用次数: 0

Abstract

Marine oxygen plays a fundamental role in regulating the transfer of organic carbon and nutrients to their dissolved inorganic forms, serving as the terminal electron acceptor for heterotrophic respiration. Oxygen can become limiting to these processes in coastal and open-ocean oxygen deficient zones (ODZs). The maintenance of ODZs depends on the balance between physical processes such as ventilation and biogeochemical processes such as remineralization. These two processes act in opposing directions on ODZs, with ventilation responsible for transporting oxygen from the surface, where it is near saturation with the partial pressure of O2 in the atmosphere, to deeper oxygen-depleted layers, and remineralization acting to consume oxygen through biogeochemical processes such as microbial degradation throughout the water column. Remineralization is represented in all CMIP6 models, but the actual parameterizations, as well as their magnitude, are widely varying.

In this study, we examine the sensitivity to remineralization of the equatorial Pacific ODZ (O2 <60μmol/kg) in a model; the NASA GISS Ocean Biogeochemical Model (NOBM-G) embedded in the NASA-GISS coupled atmosphere-ocean model. We find that increasing the remineralization rate shoals the ODZ onset depth (i.e. the regionally averaged upper bound of the ODZ), and decreases ODZ volume and regional-averaged thickness. Changes in biological consumption and vertical convergence of oxygen are identified as the primary contributors to changes in ODZ onset depth. ODZ thickness is mainly influenced by the shoaling of the bottom boundary of the ODZ, which decreases with maximum remineralization rate due to decreasing oxygen consumption and increasing horizontal oxygen convergence in deep waters. On the other hand, vertically-averaged ODZ area has a more complex, non-monotonic relationship with maximum remineralization rate. While these findings suggest an important role for remineralization in determining the shape of the ODZ in our model, the relative importance of remineralization vs. other physical parameterizations remains to be established. While our results reflect the structure of our ocean biogeochemical model, the relationship of remineralization to ODZ characteristics in other models should be examined to better inform model inter-comparisons.

赤道太平洋 ODZ 在工业化前条件下对气候模型中颗粒有机物再矿化的敏感性
海洋氧气在调节有机碳和营养物质向其溶解的无机形式转移的过程中起着重要作 用,是异养呼吸的终端电子受体。在沿岸和公海缺氧区(ODZs),氧气会限制这些过程的进行。缺氧区的维持取决于通风等物理过程和再矿化等生物地球化学过程之间的平衡。这两个过程在 ODZ 上的作用方向是相反的,通风过程负责将氧气从表层输送到更深的缺氧层,表层的氧气与大气中的氧气分压接近饱和,而再矿化过程则通过生物地球化学过程(如整个水体中的微生物降解)消耗氧气。在本研究中,我们在一个模型中考察了赤道太平洋 ODZ(O2<60μmol/kg)对再矿化作用的敏感性;该模型是嵌入 NASA-GISS 大气-海洋耦合模式的 NASA 海洋生物地球化学模式(NOBM-G)。我们发现,提高再矿化率会减小 ODZ 的起始深度(即 ODZ 的区域平均上限),并减小 ODZ 的体积和区域平均厚度。生物消耗和氧气垂直汇聚的变化被认为是导致 ODZ 起始深度变化的主要因素。ODZ 厚度主要受 ODZ 底部边界滩化的影响,由于深海耗氧量减少和水平氧辐合增加,ODZ 厚度随最大再矿化率的增加而减少。另一方面,垂直平均 ODZ 面积与最大再矿化率之间的关系更为复杂,不呈单调关系。虽然这些发现表明,在我们的模型中,再矿化在决定 ODZ 的形状方面起着重要作用,但再矿化与其它物理参数的相对重要性仍有待确定。虽然我们的结果反映了我们的海洋生物地球化学模式的结构,但应研究其它模式中再矿化与 ODZ 特征的关系,以便更好地为模式间的比较提供信息。
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来源期刊
Ocean Modelling
Ocean Modelling 地学-海洋学
CiteScore
5.50
自引率
9.40%
发文量
86
审稿时长
19.6 weeks
期刊介绍: The main objective of Ocean Modelling is to provide rapid communication between those interested in ocean modelling, whether through direct observation, or through analytical, numerical or laboratory models, and including interactions between physical and biogeochemical or biological phenomena. Because of the intimate links between ocean and atmosphere, involvement of scientists interested in influences of either medium on the other is welcome. The journal has a wide scope and includes ocean-atmosphere interaction in various forms as well as pure ocean results. In addition to primary peer-reviewed papers, the journal provides review papers, preliminary communications, and discussions.
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