Modelling Mediterranean ocean biogeochemistry of the Last Glacial Maximum

IF 3.8 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Climate of The Past Pub Date : 2024-08-12 DOI:10.5194/cp-20-1785-2024
Katharina D. Six, Uwe Mikolajewicz, Gerhard Schmiedl
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Abstract

Abstract. We present results of simulations performed with a physical–biogeochemical ocean model of the Mediterranean Sea for the Last Glacial Maximum (LGM) and analyse the differences in physical and biochemical states between the historical period and the LGM. Long-term simulations with an Earth system model based on ice sheet reconstructions provide the necessary atmospheric forcing data, oceanic boundary conditions at the entrance to the Mediterranean Sea, and river discharge to the entire basin. Our regional model accounts for changes in bathymetry due to ice sheet volume changes, reduction in atmospheric CO2 concentration, and an adjusted aeolian dust and iron deposition. The physical ocean state of the Mediterranean during the LGM shows a reduced baroclinic water exchange at the Strait of Gibraltar, a more sluggish zonal overturning circulation, and the relocation of intermediate and deep-water-formation areas – all in line with estimates from palaeo-sediment records or previous modelling efforts. Most striking features of the biogeochemical realm are a reduction in the net primary production, an accumulation of nutrients below the euphotic zone, and an increase in the organic matter deposition at the seafloor. This seeming contradiction of increased organic matter deposition and decreased net primary production challenges our view of possible changes in surface biological processes during the LGM. We attribute the origin of a reduced net primary production to the interplay of increased stability of the upper water column, changed zonal water transport at intermediate depths, and lower water temperatures, which slow down all biological processes during the LGM. Cold water temperatures also affect the remineralisation rates of organic material, which explains the simulated increase in the organic matter deposition, which is in good agreement with sediment proxy records. In addition, we discuss changes in an artificial tracer which captures the surface ocean temperature signal during organic matter production. A shifted seasonality of the biological production in the LGM leads to a difference in the recording of the climate signal by this artificial tracer of up to 1 K. This could be of relevance for the interpretation of proxy records like, e.g., alkenones. Our study not only provides the first consistent insights into the biogeochemistry of the glacial Mediterranean Sea but will also serve as the starting point for transient simulations of the last deglaciation.
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最后冰川极盛时期地中海海洋生物地球化学建模
摘要我们介绍了用地中海物理-生物地球化学海洋模型模拟末次冰川极盛时期(LGM)的结果,并分析了历史时期与末次冰川极盛时期物理和生物化学状态的差异。基于冰盖重建的地球系统模型的长期模拟提供了必要的大气强迫数据、地中海入口处的海洋边界条件以及整个流域的河流排放量。我们的区域模型考虑了冰盖体积变化引起的水深变化、大气中二氧化碳浓度的降低以及经调整的风化尘和铁沉积。地中海在远古至近代的物理海洋状态显示,直布罗陀海峡的气压水交换减少,带状翻转环流更加缓慢,中层和深层水形成区发生迁移--所有这些都与古沉积物记录或之前建模工作的估计相吻合。生物地球化学领域最显著的特征是净初级生产量的减少、极光带以下营养物质的积累以及海底有机物沉积的增加。有机物沉积增加与净初级生产量下降这一对看似矛盾的现象,挑战了我们对远古时期地表生物过程可能发生的变化的看法。我们认为,净初级生产量减少的原因是上层水柱的稳定性增强、中层深度的带状水流变化以及水温降低等因素的相互作用。低水温也会影响有机物的再矿化率,这也是模拟的有机物沉积增加的原因,与沉积物代用记录非常吻合。此外,我们还讨论了人工示踪剂的变化,该示踪剂可捕捉有机质生成过程中的海洋表层温度信号。在远古至近代,生物生产的季节性变化导致这种人工示踪剂记录的气候信号相差达 1 K,这可能与烯酮等代用记录的解释有关。我们的研究不仅首次为冰川期地中海的生物地球化学提供了一致的见解,还将成为末次冰川期瞬态模拟的起点。
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来源期刊
Climate of The Past
Climate of The Past 地学-气象与大气科学
CiteScore
7.40
自引率
14.00%
发文量
120
审稿时长
4-8 weeks
期刊介绍: Climate of the Past (CP) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on the climate history of the Earth. CP covers all temporal scales of climate change and variability, from geological time through to multidecadal studies of the last century. Studies focusing mainly on present and future climate are not within scope. The main subject areas are the following: reconstructions of past climate based on instrumental and historical data as well as proxy data from marine and terrestrial (including ice) archives; development and validation of new proxies, improvements of the precision and accuracy of proxy data; theoretical and empirical studies of processes in and feedback mechanisms between all climate system components in relation to past climate change on all space scales and timescales; simulation of past climate and model-based interpretation of palaeoclimate data for a better understanding of present and future climate variability and climate change.
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