TY  - JOUR
A1  - Bougeois, Laurie
A1  - Dupont-Nivet, Guillaume
A1  - de Rafelis, Marc
A1  - Tindall, Julia C.
A1  - Proust, Jean-Noel
A1  - Reichart, Gert-Jan
A1  - de Nooijer, Lennart J.
A1  - Guo, Zhaojie
A1  - Ormukov, Cholponbelk
T1  - Asian monsoons and aridification response to Paleogene sea retreat and Neogene westerly shielding indicated by seasonality in Paratethys oysters
JF  - Earth and planetary science letters
N2  - Asian climate patterns, characterised by highly seasonal monsoons and continentality, are thought to originate in the Eocene epoch (56 to 34 million years ago - Ma) in response to global climate, Tibetan Plateau uplift and the disappearance of the giant Proto-Paratethys sea formerly extending over Eurasia. The influence of this sea on Asian climate has hitherto not been constrained by proxy records despite being recognised as a major driver by climate models. We report here strongly seasonal records preserved in annual lamina of Eocene oysters from the Proto-Paratethys with sedimentological and numerical data showing that monsoons were not dampened by the sea and that aridification was modulated by westerly moisture sourced from the sea. Hot and arid summers despite the presence of the sea suggest a strong anticyclonic zone at Central Asian latitudes and an orographic effect from the emerging Tibetan Plateau. Westerly moisture precipitating during cold and wetter winters appear to have decreased in two steps. First in response to the late Eocene (34-37 Ma) sea retreat; second by the orogeny of the Tian Shan and Pamir ranges shielding the westerlies after 25 Ma. Paleogene sea retreat and Neogene westerly shielding thus provide two successive mechanisms forcing coeval Asian desertification and biotic crises.
KW  - Eocene monsoon
KW  - aridification
KW  - Paratethys sea
KW  - Central Asia
KW  - seasonality
KW  - bivalves
Y1  - 2018
U6  - https://doi.org/10.1016/j.epsl.2017.12.036
SN  - 0012-821X
SN  - 1385-013X
VL  - 485
SP  - 99
EP  - 110
PB  - Elsevier
CY  - Amsterdam
ER  - 
TY  - GEN
A1  - Kormann, C.
A1  - Francke, Till
A1  - Renner, M.
A1  - Bronstert, Axel
T1  - Attribution of high resolution streamflow trends in Western Austria
BT  - an approach based on climate and discharge station data
N2  - The results of streamflow trend studies are often characterized by mostly insignificant trends and inexplicable spatial patterns. In our study region, Western Austria, this applies especially for trends of annually averaged runoff. However, analysing the altitudinal aspect, we found that there is a trend gradient from higher-altitude to lower-altitude stations, i.e. a pattern of mostly positive annual trends at higher stations and negative ones at lower stations. At midaltitudes, the trends are mostly insignificant. Here we hypothesize that the streamflow trends are caused by the following two main processes: on the one hand, melting glaciers produce excess runoff at higher-altitude watersheds. On the other hand, rising temperatures potentially alter hydrological conditions in terms of less snowfall, higher infiltration, enhanced evapotranspiration, etc., which in turn results in decreasing streamflow trends at lower-altitude watersheds. However, these patterns are masked at mid-altitudes because the resulting positive and negative trends balance each other. To support these hypotheses, we attempted to attribute the detected trends to specific causes. For this purpose, we analysed trends of filtered daily streamflow data, as the causes for these changes might be restricted to a smaller temporal scale than the annual one. This allowed for the explicit determination of the exact days of year (DOYs) when certain streamflow trends emerge, which were then linked with the corresponding DOYs of the trends and characteristic dates of other observed variables, e.g. the average DOY when temperature crosses the freezing point in spring. Based on these analyses, an empirical statistical model was derived that was able to simulate daily streamflow trends sufficiently well. Analyses of subdaily streamflow changes provided additional insights. Finally, the present study supports many modelling approaches in the literature which found out that the main drivers of alpine streamflow changes are increased glacial melt, earlier snowmelt and lower snow accumulation in wintertime.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 260 
KW  - time-series
KW  - alpine
KW  - snow
KW  - variability
KW  - switzerland
KW  - impacts
KW  - regimes
KW  - temperature
KW  - seasonality
KW  - catchments
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-96560
SP  - 1225
EP  - 1245
ER  - 
TY  - JOUR
A1  - Kormann, C.
A1  - Francke, Till
A1  - Renner, M.
A1  - Bronstert, Axel
T1  - Attribution of high resolution streamflow trends in Western Austria
BT  - an approach based on climate and discharge station data
JF  - Hydrology and earth system sciences
N2  - The results of streamflow trend studies are often characterized by mostly insignificant trends and inexplicable spatial patterns. In our study region, Western Austria, this applies especially for trends of annually averaged runoff. However, analysing the altitudinal aspect, we found that there is a trend gradient from higher-altitude to lower-altitude stations, i.e. a pattern of mostly positive annual trends at higher stations and negative ones at lower stations. At midaltitudes, the trends are mostly insignificant. Here we hypothesize that the streamflow trends are caused by the following two main processes: on the one hand, melting glaciers produce excess runoff at higher-altitude watersheds. On the other hand, rising temperatures potentially alter hydrological conditions in terms of less snowfall, higher infiltration, enhanced evapotranspiration, etc., which in turn results in decreasing streamflow trends at lower-altitude watersheds. However, these patterns are masked at mid-altitudes because the resulting positive and negative trends balance each other. To support these hypotheses, we attempted to attribute the detected trends to specific causes. For this purpose, we analysed trends of filtered daily streamflow data, as the causes for these changes might be restricted to a smaller temporal scale than the annual one. This allowed for the explicit determination of the exact days of year (DOYs) when certain streamflow trends emerge, which were then linked with the corresponding DOYs of the trends and characteristic dates of other observed variables, e.g. the average DOY when temperature crosses the freezing point in spring. Based on these analyses, an empirical statistical model was derived that was able to simulate daily streamflow trends sufficiently well. Analyses of subdaily streamflow changes provided additional insights. Finally, the present study supports many modelling approaches in the literature which found out that the main drivers of alpine streamflow changes are increased glacial melt, earlier snowmelt and lower snow accumulation in wintertime.
KW  - alpine
KW  - catchments
KW  - impacts
KW  - regimes
KW  - seasonality
KW  - snow
KW  - switzerland
KW  - temperature
KW  - time-series
KW  - variability
Y1  - 2015
U6  - https://doi.org/10.5194/hess-19-1225-2015
SN  - 1607-7938
SN  - 1027-5606
VL  - 19
SP  - 1225
EP  - 1245
PB  - EGU
CY  - Katlenburg-Lindau
ER  -