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Stratospheric water vapor affecting atmospheric circulation

Author

Listed:
  • Edward Charlesworth

    (Research Center Jülich)

  • Felix Plöger

    (Research Center Jülich
    University of Wuppertal)

  • Thomas Birner

    (Ludwig Maximilians University of Munich)

  • Rasul Baikhadzhaev

    (Research Center Jülich)

  • Marta Abalos

    (Universidad Complutense de Madrid)

  • Nathan Luke Abraham

    (University of Cambridge
    University of Cambridge)

  • Hideharu Akiyoshi

    (National Institute for Environmental Studies)

  • Slimane Bekki

    (Laboratoire de Météorologie Dynamique (LMD/IPSL))

  • Fraser Dennison

    (Commonwealth Scientific and Industrial Research Organization (CSIRO) Environment)

  • Patrick Jöckel

    (Deutsches Zentrum für Luft- und Raumfahrt (DLR))

  • James Keeble

    (University of Cambridge
    University of Cambridge)

  • Doug Kinnison

    (National Center for Atmospheric Research)

  • Olaf Morgenstern

    (National Institute of Water and Atmospheric Research)

  • David Plummer

    (Environment and Climate Change Canada)

  • Eugene Rozanov

    (Davos World Radiation Center)

  • Sarah Strode

    (Morgan State University
    NASA Goddard Space Flight Center)

  • Guang Zeng

    (National Institute of Water and Atmospheric Research)

  • Tatiana Egorova

    (Davos World Radiation Center)

  • Martin Riese

    (Research Center Jülich)

Abstract

Water vapor plays an important role in many aspects of the climate system, by affecting radiation, cloud formation, atmospheric chemistry and dynamics. Even the low stratospheric water vapor content provides an important climate feedback, but current climate models show a substantial moist bias in the lowermost stratosphere. Here we report crucial sensitivity of the atmospheric circulation in the stratosphere and troposphere to the abundance of water vapor in the lowermost stratosphere. We show from a mechanistic climate model experiment and inter-model variability that lowermost stratospheric water vapor decreases local temperatures, and thereby causes an upward and poleward shift of subtropical jets, a strengthening of the stratospheric circulation, a poleward shift of the tropospheric eddy-driven jet and regional climate impacts. The mechanistic model experiment in combination with atmospheric observations further shows that the prevailing moist bias in current models is likely caused by the transport scheme, and can be alleviated by employing a less diffusive Lagrangian scheme. The related effects on atmospheric circulation are of similar magnitude as climate change effects. Hence, lowermost stratospheric water vapor exerts a first order effect on atmospheric circulation and improving its representation in models offers promising prospects for future research.

Suggested Citation

  • Edward Charlesworth & Felix Plöger & Thomas Birner & Rasul Baikhadzhaev & Marta Abalos & Nathan Luke Abraham & Hideharu Akiyoshi & Slimane Bekki & Fraser Dennison & Patrick Jöckel & James Keeble & Dou, 2023. "Stratospheric water vapor affecting atmospheric circulation," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-39559-2
    DOI: 10.1038/s41467-023-39559-2
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