Landais A., Agosta C., Vimeux Françoise, Magand O., Solis C., Cauquoin A., Dutrievoz N., Risi C., Santos C. L. D., Fourré E., Cattani O., Jossoud O., Minster B., Prié F., Casado M., Dommergue A., Bertrand Y., Werner M. (2024). Abrupt excursions in water vapor isotopic variability at the Pointe Benedicte observatory on Amsterdam Island. Atmospheric Chemistry and Physics, 24 (8), p. 4611-4634. ISSN 1680-7316.
Titre du document
Abrupt excursions in water vapor isotopic variability at the Pointe Benedicte observatory on Amsterdam Island
Année de publication
2024
Auteurs
Landais A., Agosta C., Vimeux Françoise, Magand O., Solis C., Cauquoin A., Dutrievoz N., Risi C., Santos C. L. D., Fourré E., Cattani O., Jossoud O., Minster B., Prié F., Casado M., Dommergue A., Bertrand Y., Werner M.
Source
Atmospheric Chemistry and Physics, 2024,
24 (8), p. 4611-4634 ISSN 1680-7316
In order to complement the picture of the atmospheric water cycle in the Southern Ocean, we have continuously monitored water vapor isotopes since January 2020 on Amsterdam Island in the Indian Ocean. We present here the first 2-year long water vapor isotopic record at this site. We show that the water vapor isotopic composition largely follows the water vapor mixing ratio, as expected in marine boundary layers. However, we detect 11 periods of a few days where there is a strong loss of correlation between water vapor delta 18 O and water vapor mixing ratio as well as abrupt negative excursions of water vapor delta 18 O . These excursions often occur toward the end of precipitation events. Six of these events show a decrease in gaseous elemental mercury, suggesting subsidence of air from a higher altitude.Our study aims to further explore the mechanism driving these negative excursions in water vapor delta 18 O . We used two different models to provide a data-model comparison over this 2-year period. While the European Centre Hamburg model (ECHAM6-wiso) at 0.9 degrees was able to reproduce most of the sharp negative water vapor delta 18 O excursions, hence validating the physics process and isotopic implementation in this model, the Laboratoire de Meteorologie Dynamique Zoom model (LMDZ-iso) at 2 degrees (3 degrees) resolution was only able to reproduce seven (one) of the negative excursions, highlighting the possible influence of the model resolution for the study of such abrupt isotopic events. Based on our detailed model-data comparison, we conclude that the most plausible explanations for such isotopic excursions are rain-vapor interactions associated with subsidence at the rear of a precipitation event.
Plan de classement
Sciences du milieu [021]
Description Géographique
OCEAN INDIEN ; TAAF
Localisation
Fonds IRD [F B010090552]
Identifiant IRD
fdi:010090552
