Publication details

European warm-season temperature and hydroclimate since 850 CE

Authors

LJUNGQVIST F.C. SEIM A. KRUSIC P.J. GONZALEZ-ROUCO J.F. WERNER J.P. COOK E.R. ZORITA E. LUTERBACHER J. XOPLAKI E. DESTOUNI G. GARCIA-BUSTAINANTE E. AGUILAR C.A.M. SEFTIGEN K. WANG J.L. GAGEN M.H. ESPER J. SOLOMINA O. FLEITMANN D. BÜNTGEN Ulf

Year of publication 2019
Type Article in Periodical
Magazine / Source Environmental Research Letters
MU Faculty or unit

Faculty of Science

Citation
Web https://iopscience.iop.org/article/10.1088/1748-9326/ab2c7e
Doi http://dx.doi.org/10.1088/1748-9326/ab2c7e
Keywords climate variability; climate model simulations; gridded climate reconstructions; hydroclimate; Europe; past millennium; tree-ring data
Description The long-term relationship between temperature and hydroclimate has remained uncertain due to the short length of instrumental measurements and inconsistent results from climate model simulations. This lack of understanding is particularly critical with regard to projected drought and flood risks. Here we assess warm-season co-variability patterns between temperature and hydroclimate over Europe back to 850 CE using instrumental measurements, tree-ring based reconstructions, and climate model simulations. We find that the temperature-hydroclimate relationship in both the instrumental and reconstructed data turns more positive at lower frequencies, but less so in model simulations, with a dipole emerging between positive (warm and wet) and negative (warm and dry) associations in northern and southern Europe, respectively. Compared to instrumental data, models reveal a more negative co-variability across all timescales, while reconstructions exhibit a more positive co-variability. Despite the observed differences in the temperature-hydroclimate co-variability patterns in instrumental, reconstructed and model simulated data, we find that all data types share relatively similar phase-relationships between temperature and hydroclimate, indicating the common influence of external forcing. The co-variability between temperature and soil moisture in the model simulations is overestimated, implying a possible overestimation of temperature-driven future drought risks.

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