<p>The Mid-Brunhes Transition (MBT) signifies a pivotal shift in glacial–interglacial cycles with intensified interglacial warming, yet its underlying mechanisms remain elusive. Targeting the most sensitive component of oceanic heat uptake, the southern-sourced sub-surface waters, the post-MBT ocean heat dynamics are investigated using reconstructed deep and bottom thermocline temperatures from the Western Equatorial Pacific. Our results show that, since the MBT, the deep thermocline temperature has been gradually declining in association with cooling within the (sub)tropical Pacific upper ocean circulation. In contrast, the bottom thermocline temperature shows a pronounced rising trend independent of the calibration-derived uncertainties in its absolute estimates. Such post-MBT bottom thermocline warming is consistent with an enhanced advection of southern-sourced subsurface waters, as indicated by strengthened Southern Ocean meridional thermal gradients and concurrent warming in the southern subtropics. It is thus suggested that enhanced equatorward transport of southern-sourced subsurface waters, as a cross-hemispheric heat-redistribution pathway, may have elevated the background thermal state of post-MBT interglacials, highlighting the potential role of tropical-Southern Ocean connection in shaping climate trajectories.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Equatorward upper-ocean heat transport from the Southern Ocean boosted interglacial warming

  • Ce Yang,
  • Haowen Dang,
  • Jian Xu,
  • Xiaolin Ma,
  • Xingxing Wang,
  • Yu Ren,
  • Hongrui Zhang,
  • Chen Li,
  • Peng Zhang,
  • Haijing Chen,
  • Franck Bassinot,
  • Yair Rosenthal,
  • Zhimin Jian

摘要

The Mid-Brunhes Transition (MBT) signifies a pivotal shift in glacial–interglacial cycles with intensified interglacial warming, yet its underlying mechanisms remain elusive. Targeting the most sensitive component of oceanic heat uptake, the southern-sourced sub-surface waters, the post-MBT ocean heat dynamics are investigated using reconstructed deep and bottom thermocline temperatures from the Western Equatorial Pacific. Our results show that, since the MBT, the deep thermocline temperature has been gradually declining in association with cooling within the (sub)tropical Pacific upper ocean circulation. In contrast, the bottom thermocline temperature shows a pronounced rising trend independent of the calibration-derived uncertainties in its absolute estimates. Such post-MBT bottom thermocline warming is consistent with an enhanced advection of southern-sourced subsurface waters, as indicated by strengthened Southern Ocean meridional thermal gradients and concurrent warming in the southern subtropics. It is thus suggested that enhanced equatorward transport of southern-sourced subsurface waters, as a cross-hemispheric heat-redistribution pathway, may have elevated the background thermal state of post-MBT interglacials, highlighting the potential role of tropical-Southern Ocean connection in shaping climate trajectories.