Oceanographic regional climate projections for the Baltic Sea until 2100

H. Meier, C. Dieterich, M. Gröger, C. Dutheil, F. Börgel, K. Safonova, O. B. Christensen, E. Kjellström
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引用次数: 20

Abstract

Abstract. The Baltic Sea, located in northern Europe, is a semi-enclosed, shallow and tideless sea with seasonal sea-ice cover in its northern sub-basins. Its long water residence time contributes to oxygen depletion in the bottom water of its southern sub-basins. In this study, recently performed scenario simulations for the Baltic Sea including marine biogeochemistry were analysed and compared with earlier published projections. Specifically, dynamical downscaling using a regionally coupled atmosphere–ocean climate model was used to regionalise four global Earth system models. However, as the regional climate model does not include components representing terrestrial and marine biogeochemistry, an additional catchment and a coupled physical–biogeochemical model for the Baltic Sea were included. The scenario simulations take the impact of various global sea level rise scenarios into account. According to the projections, compared to the present climate, higher water temperatures, a shallower mixed layer with a sharper thermocline during summer, less sea-ice cover and greater mixing in the northern Baltic Sea during winter can be expected. Both the frequency and the duration of marine heat waves will increase significantly, in particular in the coastal zone of the southern Baltic Sea (except in regions with frequent upwellings). Nonetheless, due to the uncertainties in the projections regarding regional winds, the water cycle and the global sea level rise, robust and statistically significant salinity changes could not be identified. The impact of a changing climate on biogeochemical cycling is predicted to be considerable but still smaller than that of plausible nutrient input changes. Implementing the proposed Baltic Sea Action Plan, a nutrient input abatement plan for the entire catchment area, would result in a significantly improved ecological status of the Baltic Sea, including reductions in the size of the hypoxic area also in a future climate, which in turn would increase the resilience of the Baltic Sea against anticipated climate change. While our findings regarding changes in heat-cycle variables mainly confirm earlier scenario simulations, they differ substantially from earlier projections of salinity and biogeochemical cycles, due to differences in experimental setups and in input scenarios for bioavailable nutrients.
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波罗的海至2100年的海洋区域气候预估
摘要波罗的海位于欧洲北部,是一个半封闭、浅而无潮的海,其北部子盆地有季节性的海冰覆盖。其在水中停留时间长,导致其南部子盆地底部水体缺氧。在这项研究中,分析了最近对波罗的海进行的情景模拟,包括海洋生物地球化学,并将其与早期发表的预测进行了比较。具体而言,利用区域耦合大气-海洋气候模式的动力降尺度对四个全球地球系统模式进行了区域化。然而,由于区域气候模型不包括代表陆地和海洋生物地球化学的成分,因此包括了波罗的海的额外集水区和耦合的物理-生物地球化学模型。情景模拟考虑了各种全球海平面上升情景的影响。根据预估,与目前的气候相比,预计水温会更高,夏季混合层较浅,温跃层更陡,冬季波罗的海北部海冰覆盖较少,混合程度更高。海洋热浪的频率和持续时间都将显著增加,特别是在波罗的海南部沿海地区(上升流频繁的地区除外)。尽管如此,由于关于区域风、水循环和全球海平面上升的预估存在不确定性,因此无法确定强劲且具有统计意义的盐度变化。气候变化对生物地球化学循环的影响预计是相当大的,但仍小于合理的养分输入变化的影响。实施拟议的波罗的海行动计划(一项针对整个集水区的营养投入减少计划)将显著改善波罗的海的生态状况,包括在未来气候中减少缺氧区域的面积,这反过来将增加波罗的海对预期气候变化的适应能力。虽然我们关于热循环变量变化的研究结果主要证实了早期情景模拟,但由于实验设置和生物可利用养分输入情景的差异,它们与早期盐度和生物地球化学循环的预测存在很大差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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