Recent variations in oceanic transports across the Greenland–Scotland Ridge

State of the Planet Pub Date : 2023-09-27 DOI:10.5194/sp-1-osr7-14-2023

Michael Mayer, Takamasa Tsubouchi, Susanna Winkelbauer, Karin Margretha H. Larsen, Barbara Berx, Andreas Macrander, Doroteaciro Iovino, Steingrímur Jónsson, Richard Renshaw

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Abstract

Abstract. Oceanic exchanges across the Greenland–Scotland Ridge (GSR) play a crucial role in shaping the Arctic climate and linking with the Atlantic meridional overturning circulation. Most considered ocean reanalyses underestimate the observed 1993–2020 mean net inflow of warm and saline Atlantic Water of 8.0 ± 0.5 Sv by up to 15 %, with reanalyses at 0.25∘ resolution additionally exhibiting larger biases in the single inflow branches compared to higher-resolution products. The underestimation of Atlantic Water inflow translates into a low bias in mean oceanic heat flux at the GSR of 5 %–22 % in reanalyses compared to the observed value of 280 ± 18 TW. Interannual variations in reanalysis transports correlate reasonably well with observed transports in most branches crossing the GSR. Observations and reanalyses with data assimilation show a marked reduction in oceanic heat flux across the GSR of 4 %–9 % (compared to 1993–2020 means) during a biennial (2-year-long) period centered on 2018, a record low for several products. The anomaly was associated with a temporary reduction in geostrophic Atlantic Water inflow through the Faroe–Shetland branch and was augmented by anomalously cool temperatures of Atlantic Water arriving at the GSR. The latter is linked to a recent strengthening of the North Atlantic subpolar gyre and illustrates the interplay of interannual and decadal changes in modulating transports at the GSR.

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横跨格陵兰-苏格兰脊的海洋运输的近期变化

摘要横跨格陵兰-苏格兰脊(GSR)的海洋交换在形成北极气候和连接大西洋经向翻转环流方面起着至关重要的作用。大多数被考虑的海洋再分析将观测到的1993-2020年大西洋暖水和咸水的平均净流入(8.0±0.5 Sv)低估了15%，在0.25°分辨率下的再分析也显示出与高分辨率产品相比，单一流入分支的偏差更大。与观测值280±18 TW相比，再分析中大西洋水流入的低估导致GSR处平均海洋热通量的低偏差为5% - 22%。再分析输运的年际变化与穿越GSR的大多数分支观测到的输运有相当好的相关性。观测和资料同化再分析表明，在以2018年为中心的两年(2年)期间，整个GSR的海洋热通量显著减少了4% - 9%(与1993-2020年平均值相比)，这是若干产品的历史最低点。该异常与通过法罗-设得兰分支的地转大西洋水流入的暂时减少有关，并因大西洋水到达GSR的异常低温而增强。后者与最近北大西洋次极环流的加强有关，并说明了GSR调制输送的年际和年代际变化的相互作用。

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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State of the Planet

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