103 / 2024-09-08 15:54:00
Stretched polar vortex increases mid-latitude climate variability during the Last Glacial Maximum
polar vortex, mid-latitude climate, winter temperature, climate variability, LGM glacial climate
Session 53 - Geological analogues for future warm ocean and climate
Abstract Accepted
Stretched polar vortex increases mid-latitude climate variability during the Last Glacial Maximum
Yurui Zhang1, Hans Renssen2, Heikki Seppä3, Zhen Li1, Xingrui Li1
1 State Key Laboratory of Marine Environmental Science, College of Ocean & Earth Sciences, Xiamen University, Xiamen, China
2 Department of Natural Sciences and Environmental Health, University of South-Eastern Norway, Bø, Norway
3 Department of Geosciences and Geography, University of Helsinki, Helsinki, Finland
Correspondence to: Yurui Zhang (yuruizhang@xmu.edu.cn)
Abstract. The Arctic stratospheric polar vortex (PV) is a key driver of winter weather, and has been found playing role in winter climate variability and its predictability in Eurasia and North America on inter-annual and decadal time scales. However, to what extent this relationship also plays a role in driving climate variability on glacial-interglacial time scales is still unknown. Here, by systematically analysing PV changes in four sets of PMIP4 simulations for the last glacial maximum (LGM) and the pre-industrial (PI), we explore how the PV changed during the glacial climate and how it influenced climate variability. Our results show that under LGM conditions, the PV stretched toward the Laurentide ice sheet, which resulted in a less stable ellipse shape that increased the possibility of cold air outbreaks into mid-latitudes. During the LGM, this stretched PV pushed cold Arctic air further equatorward, increasing winter climate variability over the more (southward) southern mid-latitudes. In particular, this strengthened winter cooling over the mid-latitudes beyond the coverage of the Laurentide ice sheet (unlike summer). PV-induced temperature variability also explains the inter-model spread, as removing the PV variation from the model results reduces the inter-model spread by up to 5 ℃ over mid-latitude Eurasia. These results highlight the critical role of PV in connecting the polar region and mid-latitudes on glacial-interglacial time scales. These connections are reminiscent of intra-seasonal stratosphere–troposphere coupling.
Keywords: polar vortex, mid-latitude climate, winter temperature, climate variability, LGM glacial climate
Yurui Zhang1, Hans Renssen2, Heikki Seppä3, Zhen Li1, Xingrui Li1
1 State Key Laboratory of Marine Environmental Science, College of Ocean & Earth Sciences, Xiamen University, Xiamen, China
2 Department of Natural Sciences and Environmental Health, University of South-Eastern Norway, Bø, Norway
3 Department of Geosciences and Geography, University of Helsinki, Helsinki, Finland
Correspondence to: Yurui Zhang (yuruizhang@xmu.edu.cn)
Abstract. The Arctic stratospheric polar vortex (PV) is a key driver of winter weather, and has been found playing role in winter climate variability and its predictability in Eurasia and North America on inter-annual and decadal time scales. However, to what extent this relationship also plays a role in driving climate variability on glacial-interglacial time scales is still unknown. Here, by systematically analysing PV changes in four sets of PMIP4 simulations for the last glacial maximum (LGM) and the pre-industrial (PI), we explore how the PV changed during the glacial climate and how it influenced climate variability. Our results show that under LGM conditions, the PV stretched toward the Laurentide ice sheet, which resulted in a less stable ellipse shape that increased the possibility of cold air outbreaks into mid-latitudes. During the LGM, this stretched PV pushed cold Arctic air further equatorward, increasing winter climate variability over the more (southward) southern mid-latitudes. In particular, this strengthened winter cooling over the mid-latitudes beyond the coverage of the Laurentide ice sheet (unlike summer). PV-induced temperature variability also explains the inter-model spread, as removing the PV variation from the model results reduces the inter-model spread by up to 5 ℃ over mid-latitude Eurasia. These results highlight the critical role of PV in connecting the polar region and mid-latitudes on glacial-interglacial time scales. These connections are reminiscent of intra-seasonal stratosphere–troposphere coupling.
Keywords: polar vortex, mid-latitude climate, winter temperature, climate variability, LGM glacial climate