%0 Thesis
%9 THE : Thèses
%A Sturm, K.
%T Regional atmospheric modelling of the stable water isotope cycle
%C Saint Martin d'Hères (FRA) ; Montpellier
%D 2005
%L fdi:010044897
%G ENG
%I Univ. Joseph Fourier ; IRD
%K ISOTOPE ; CIRCULATION ATMOSPHERIQUE ; CLIMAT ; MODELISATION ; PROPRIETE PHYSIQUE ; EAU ; PRECIPITATION ; VARIATION SAISONNIERE
%K CHANGEMENT CLIMATIQUE ; MOUSSON ; MODEL REMO
%K AMERIQUE DU SUD
%P 160  multigr.
%U https://www.documentation.ird.fr/hor/fdi:010044897
%> https://horizon.documentation.ird.fr/exl-doc/pleins_textes/divers16-09/010044897.pdf
%W Horizon (IRD)
%X Climate change has recently become a major concerning among scientists and the general public. A better knowledge of past climates helps forecasting the future evolution of climate. Stable water isotopes stand as an outstanding paleo-climate proxy. Physical properties of heavy stable water isotopes (H218O, HDO) cause fractionation processes related to temperature and degree of distillation. If the isotopic signal is correctly inverted, past climate change can be inferred from isotopic archives. Andean ice-cores offer a unique records of tropical climate and its variability through time. However, the interpretation of the isotopic signal is difficult because of complex atmospheric dynamic over South America. For this purpose, we developed a module handling the stable water isotope fractionation processes within the regional circulation model REMO and applied it to South America. The manuscript outlines the major milestones of the present PhD. We first introduce the research toic in the wider scope of climate change; the description of the stable water isotope enabled regional circulation model REMOiso; an initial validation of REMOiso over Europe; an investigation of the seasonal variations of precipitation, atmospheric circulation and isotopic signal over South America; and at last the recording of the south American monsoon system (SAMS) by stable water isotope diagnostics.
%B Université Joseph Fourier
%8 
%$ 062MECEAU02 ; 062MECEAU05