53519
2018
2018
eng
1562
1584
23
3
123
article
American Geophysical Union
Washington
1
2018-01-19
2018-01-19
--
Do changing weather types explain observed climatic trends in the rhine basin?
For attributing hydrological changes to anthropogenic climate change, catchment models are driven by climate model output. A widespread approach to bridge the spatial gap between global climate and hydrological catchment models is to use a weather generator conditioned on weather patterns (WPs). This approach assumes that changes in local climate are characterized by between-type changes of patterns. In this study we test this assumption by analyzing a previously developed WP classification for the Rhine basin, which is based on dynamic and thermodynamic variables. We quantify changes in pattern characteristics and associated climatic properties. The amount of between- and within-type changes is investigated by comparing observed trends to trends resulting solely from WP occurrence. To overcome uncertainties in trend detection resulting from the selected time period, all possible periods in 1901-2010 with a minimum length of 31 years are analyzed. Increasing frequency is found for some patterns associated with high precipitation, although the trend sign highly depends on the considered period. Trends and interannual variations of WP frequencies are related to the long-term variability of large-scale circulation modes. Long-term WP internal warming is evident for summer patterns and enhanced warming for spring/autumn patterns since the 1970s. Observed trends in temperature and partly in precipitation are mainly associated with frequency changes of specific WPs, but some amount of within-type changes remains. The classification can be used for downscaling of past changes considering this limitation, but the inclusion of thermodynamic variables into the classification impedes the downscaling of future climate projections.
Journal of geophysical of geophysical research-atmosheres
an analysis of within- and between-type changes
10.1002/2017JD026654
2169-897X
2169-8996
wos:2018
WOS:000426074000006
Murawski, A (reprint author), GFZ German Res Ctr Geosci, Potsdam, Germany.; Murawski, A (reprint author), Vienna Univ Technol, Inst Hydraul Engn & Water Resources Management, Vienna, Austria.; Murawski, A (reprint author), Univ Potsdam, Inst Earth & Environm Sci, Potsdam, Germany., murawski@gfz-potsdam.de
Climate KIC
2022-01-19T12:47:40+00:00
sword
importub
filename=package.tar
e068589236d15130686fd4745be3f088
Aline Murawski
Sergiy Vorogushyn
Gerd Bürger
Lars Gerlitz
Bruno Merz
eng
uncontrolled
attribution
eng
uncontrolled
weather pattern
eng
uncontrolled
trend analysis
eng
uncontrolled
downscaling
eng
uncontrolled
hypothetical trend
Geowissenschaften
Institut für Geowissenschaften
Referiert
Import
Green Open-Access
44833
2016
2016
eng
4283
4306
24
20
article
Copernicus
Göttingen
1
--
--
--
Can local climate variability be explained by weather patterns? A multi-station evaluation for the Rhine basin
To understand past flood changes in the Rhine catchment and in particular the role of anthropogenic climate change in extreme flows, an attribution study relying on a proper GCM (general circulation model) downscaling is needed. A downscaling based on conditioning a stochastic weather generator on weather patterns is a promising approach. This approach assumes a strong link between weather patterns and local climate, and sufficient GCM skill in reproducing weather pattern climatology. These presuppositions are unprecedentedly evaluated here using 111 years of daily climate data from 490 stations in the Rhine basin and comprehensively testing the number of classification parameters and GCM weather pattern characteristics. A classification based on a combination of mean sea level pressure, temperature, and humidity from the ERA20C reanalysis of atmospheric fields over central Europe with 40 weather types was found to be the most appropriate for stratifying six local climate variables. The corresponding skill is quite diverse though, ranging from good for radiation to poor for precipitation. Especially for the latter it was apparent that pressure fields alone cannot sufficiently stratify local variability. To test the skill of the latest generation of GCMs from the CMIP5 ensemble in reproducing the frequency, seasonality, and persistence of the derived weather patterns, output from 15 GCMs is evaluated. Most GCMs are able to capture these characteristics well, but some models showed consistent deviations in all three evaluation criteria and should be excluded from further attribution analysis.
Hydrology and earth system sciences : HESS
10.5194/hess-20-4283-2016
1027-5606
1607-7938
wos2016:2019
WOS:000386773200001
Murawski, A (reprint author), GFZ German Res Ctr Geosci, Potsdam, Germany., murawski@gfz-potsdam.de
Climate KIC
importub
2020-03-22T13:29:01+00:00
filename=package.tar
23f4f2c949e07a627be1bda5e316e43c
Aline Murawski
Gerd Bürger
Sergiy Vorogushyn
Bruno Merz
Institut für Geowissenschaften
Referiert
Institut für Erd- und Umweltwissenschaften
Import
41015
2016
2019
eng
24
525
postprint
1
2019-01-17
2019-01-17
--
Can local climate variability be explained by weather patterns?
To understand past flood changes in the Rhine catchment and in particular the role of anthropogenic climate change in extreme flows, an attribution study relying on a proper GCM (general circulation model) downscaling is needed. A downscaling based on conditioning a stochastic weather generator on weather patterns is a promising approach. This approach assumes a strong link between weather patterns and local climate, and sufficient GCM skill in reproducing weather pattern climatology. These presuppositions are unprecedentedly evaluated here using 111 years of daily climate data from 490 stations in the Rhine basin and comprehensively testing the number of classification parameters and GCM weather pattern characteristics. A classification based on a combination of mean sea level pressure, temperature, and humidity from the ERA20C reanalysis of atmospheric fields over central Europe with 40 weather types was found to be the most appropriate for stratifying six local climate variables. The corresponding skill is quite diverse though, ranging from good for radiation to poor for precipitation. Especially for the latter it was apparent that pressure fields alone cannot sufficiently stratify local variability. To test the skill of the latest generation of GCMs from the CMIP5 ensemble in reproducing the frequency, seasonality, and persistence of the derived weather patterns, output from 15 GCMs is evaluated. Most GCMs are able to capture these characteristics well, but some models showed consistent deviations in all three evaluation criteria and should be excluded from further attribution analysis.
Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
a multi-station evaluation for the Rhine basin
10.25932/publishup-41015
urn:nbn:de:kobv:517-opus4-410155
1866-8372
online registration
Hydrology and Earth System Sciences 20 (2016), pp. 4283-4306 DOI 10.5194/hess-20-4283-2016
CC-BY - Namensnennung 4.0 International
Aline Murawski
Gerd Bürger
Sergiy Vorogushyn
Bruno Merz
Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
525
eng
uncontrolled
athmospheric circulation patterns
eng
uncontrolled
stochastic rainfall model
eng
uncontrolled
within-type variability
eng
uncontrolled
river Rhine
eng
uncontrolled
precipitation
eng
uncontrolled
temperature
eng
uncontrolled
trends
eng
uncontrolled
classification
eng
uncontrolled
Europe
eng
uncontrolled
scenarios
Geowissenschaften
open_access
Mathematisch-Naturwissenschaftliche Fakultät
Referiert
Open Access
Copernicus
Universität Potsdam
https://publishup.uni-potsdam.de/files/41015/pmnr525.pdf
41272
2017
2018
eng
112
doctoralthesis
1
--
--
2018-06-15
Trends in precipitation over Germany and the Rhine basin related to changes in weather patterns
Zeitliche Veränderungen im Niederschlag über Deutschland und dem
Rheineinzugsgebiet in Zusammenhang mit Wetterlagen
Niederschlag als eine der wichtigsten meteorologischen Größen für Landwirtschaft, Wasserversorgung und menschliches Wohlbefinden hat schon immer erhöhte Aufmerksamkeit erfahren. Niederschlagsmangel kann verheerende Auswirkungen haben, wie z.B. Missernten und Wasserknappheit. Übermäßige Niederschläge andererseits bergen jedoch ebenfalls Gefahren in Form von Hochwasser oder Sturzfluten und wiederum Missernten. Daher wurde viel Arbeit in die Detektion von Niederschlagsänderungen und deren zugrundeliegende Prozesse gesteckt. Insbesondere angesichts von Klimawandel und unter Berücksichtigung des Zusammenhangs zwischen Temperatur und atmosphärischer Wasserhaltekapazität, ist großer Bedarf an Forschung zum Verständnis der Auswirkungen von Klimawandel auf Niederschlagsänderungen gegeben.
Die vorliegende Arbeit hat das Ziel, vergangene Veränderungen in Niederschlag und anderen meteorologischen Variablen zu verstehen. Für verschiedene Zeiträume wurden Tendenzen gefunden und mit entsprechenden Veränderungen in der großskaligen atmosphärischen Zirkulation in Zusammenhang gebracht. Die Ergebnisse dieser Arbeit können als Grundlage für die Attributierung von Hochwasserveränderungen zu Klimawandel genutzt werden. Die Annahmen für die Maßstabsverkleinerung („Downscaling“) der Daten von großskaligen Zirkulationsmodellen auf die lokale Skala wurden hier getestet und verifziert.
In einem ersten Schritt wurden Niederschlagsveränderungen in Deutschland analysiert. Dabei lag der Fokus nicht nur auf Niederschlagssummen, sondern auch auf Eigenschaften der statistischen Verteilung, Übergangswahrscheinlichkeiten als Maß für Trocken- und Niederschlagsperioden und Extremniederschlagsereignissen. Den räumlichen Fokus auf das Rheineinzugsgebiet, das größte Flusseinzugsgebiet Deutschlands und einer der Hauptwasserwege Europas, verlagernd, wurden nachgewiesene Veränderungen in Niederschlag und anderen meteorologischen Größen in Bezug zu einer „optimierten“ Wetterlagenklassifikation analysiert. Die Wetterlagenklassifikation wurde unter der Maßgabe entwickelt, die Varianz des lokalen Klimas bestmöglich zu erklären. Die letzte hier behandelte Frage dreht sich darum, ob die beobachteten Veränderungen im lokalen Klima eher Häufigkeitsänderungen der Wetterlagen zuzuordnen sind oder einer Veränderung der Wetterlagen selbst. Eine gebräuchliche Annahme für einen Downscaling-Ansatz mit Hilfe von Wetterlagen und einem stochastischen Wettergenerator ist, dass Klimawandel sich allein durch eine Veränderung der Häufigkeit von Wetterlagen ausdrückt, die Eigenschaften der Wetterlagen dabei jedoch konstant bleiben. Diese Annahme wurde überprüft und die Fähigkeit der neuesten Generation von Zirkulationsmodellen, diese Wetterlagen zu reproduzieren, getestet.
Niederschlagsveränderungen in Deutschland im Zeitraum 1951–2006 lassen sich zusammenfassen als negativ im Sommer und positiv in allen anderen Jahreszeiten. Verschiedene Niederschlagscharakteristika bestätigen die Tendenz in den Niederschlagssummen: während mittlere und extreme Niederschlagstageswerte im Winter zugenommen haben, sind auch zusammenhängende Niederschlagsperioden länger geworden (ausgedrückt als eine gestiegene Wahrscheinlichkeit für einen Tag mit Niederschlag gefolgt von einem weiteren nassen Tag). Im Sommer wurde das Gegenteil beobachtet: gesunkene Niederschlagssummen, untermauert von verringerten Mittel- und Extremwerten und längeren Trockenperioden. Abseits dieser allgemeinen Zusammenfassung für das gesamte Gebiet Deutschlands, ist die räumliche Verteilung von Niederschlagsveränderungen deutlich heterogener. Vermehrter Niederschlag im Winter wurde hauptsächlich im Nordwesten und Südosten Deutschlands beobachtet, während im Frühling die stärksten Veränderungen im Westen und im Herbst im Süden aufgetreten sind. Das saisonale Bild wiederum löst sich für die zugehörigen Monate auf, z.B. setzt sich der Anstieg im Herbstniederschlag aus deutlich vermehrtem Niederschlag im Südwesten im Oktober und im Südosten im November zusammen. Diese Ergebnisse betonen die starken räumlichen Zusammenhänge der Niederschlagsänderungen.
Der nächste Schritt hinsichtlich einer Zuordnung von Niederschlagsveränderungen zu Änderungen in großskaligen Zirkulationsmustern, war die Ableitung einer Wetterlagenklassifikation, die die betrachteten lokalen Klimavariablen hinreichend stratifizieren kann. Fokussierend auf Temperatur, Globalstrahlung und Luftfeuchte zusätzlich zu Niederschlag, wurde eine Klassifikation basierend auf Luftdruck, Temperatur und spezifischer Luftfeuchtigkeit als am besten geeignet erachtet, die Varianz der lokalen Variablen zu erklären. Eine vergleichsweise hohe Anzahl von 40 Wetterlagen wurde ausgewählt, die es erlaubt, typische Druckmuster durch die zusätzlich verwendete Temperaturinformation einzelnen Jahreszeiten zuzuordnen. Während die Fähigkeit, Varianz im Niederschlag zu erklären, relativ gering ist, ist diese deutlich besser für Globalstrahlung und natürlich Temperatur. Die meisten der aktuellen Zirkulationsmodelle des CMIP5-Ensembles sind in der Lage, die Wetterlagen hinsichtlich Häufigkeit, Saisonalität und Persistenz hinreichend gut zu reproduzieren.
Schließlich wurden dieWetterlagen bezüglich Veränderungen in ihrer Häufigkeit, Saisonalität und Persistenz, sowie der Wetterlagen-spezifischen Niederschläge und Temperatur, untersucht. Um Unsicherheiten durch die Wahl eines bestimmten Analysezeitraums auszuschließen, wurden alle möglichen Zeiträume mit mindestens 31 Jahren im Zeitraum 1901–2010 untersucht. Dadurch konnte die Annahme eines konstanten Zusammenhangs zwischen Wetterlagen und lokalem Wetter gründlich überprüft werden. Es wurde herausgefunden, dass diese Annahme nur zum Teil haltbar ist. Während Veränderungen in der Temperatur hauptsächlich auf Veränderungen in der Wetterlagenhäufigkeit zurückzuführen sind, wurde für Niederschlag ein erheblicher Teil von Veränderungen innerhalb einzelner Wetterlagen gefunden. Das Ausmaß und sogar das Vorzeichen der Veränderungen hängt hochgradig vom untersuchten Zeitraum ab. Die Häufigkeit einiger Wetterlagen steht in direkter Beziehung zur langfristigen Variabilität großskaliger Zirkulationsmuster.
Niederschlagsveränderungen variieren nicht nur räumlich, sondern auch zeitlich – Aussagen über Tendenzen sind nur in Bezug zum jeweils untersuchten Zeitraum gültig. Während ein Teil der Veränderungen auf Änderungen der großskaligen Zirkulation zurückzuführen ist, gibt es auch deutliche Veränderungen innerhalb einzelner Wetterlagen. Die Ergebnisse betonen die Notwendigkeit für einen sorgfältigen Nachweis von Veränderungen möglichst verschiedene Zeiträume zu untersuchen und mahnen zur Vorsicht bei der Anwendung von Downscaling-Ansätzen mit Hilfe von Wetterlagen, da diese die Auswirkungen von Klimaveränderungen durch das Vernachlässigen von Wetterlagen-internen Veränderungen falsch einschätzen könnten.
Precipitation as the central meteorological feature for agriculture, water security, and human well-being amongst others, has gained special attention ever since. Lack of precipitation may have devastating effects such as crop failure and water scarcity. Abundance of precipitation, on the other hand, may as well result in hazardous events such as flooding and again crop failure. Thus, great effort has been spent on tracking changes in precipitation and relating them to underlying processes. Particularly in the face of global warming and given the link between temperature and atmospheric water holding capacity, research is needed to understand the effect of climate change on precipitation.
The present work aims at understanding past changes in precipitation and other meteorological variables. Trends were detected for various time periods and related to associated changes in large-scale atmospheric circulation. The results derived in this thesis may be used as the foundation for attributing changes in floods to climate change. Assumptions needed for the downscaling of large-scale circulation model output to local climate stations are tested and verified here.
In a first step, changes in precipitation over Germany were detected, focussing not only on precipitation totals, but also on properties of the statistical distribution, transition probabilities as a measure for wet/dry spells, and extreme precipitation events.
Shifting the spatial focus to the Rhine catchment as one of the major water lifelines of Europe and the largest river basin in Germany, detected trends in precipitation and other meteorological variables were analysed in relation to states of an ``optimal'' weather pattern classification. The weather pattern classification was developed seeking the best skill in explaining the variance of local climate variables.
The last question addressed whether observed changes in local climate variables are attributable to changes in the frequency of weather patterns or rather to changes within the patterns itself. A common assumption for a downscaling approach using weather patterns and a stochastic weather generator is that climate change is expressed only as a changed occurrence of patterns with the pattern properties remaining constant. This assumption was validated and the ability of the latest generation of general circulation models to reproduce the weather patterns was evaluated.
% Paper 1
Precipitation changes in Germany in the period 1951-2006 can be summarised briefly as negative in summer and positive in all other seasons. Different precipitation characteristics confirm the trends in total precipitation: while winter mean and extreme precipitation have increased, wet spells tend to be longer as well (expressed as increased probability for a wet day followed by another wet day). For summer the opposite was observed: reduced total precipitation, supported by decreasing mean and extreme precipitation and reflected in an increasing length of dry spells.
Apart from this general summary for the whole of Germany, the spatial distribution within the country is much more differentiated. Increases in winter precipitation are most pronounced in the north-west and south-east of Germany, while precipitation increases are highest in the west for spring and in the south for autumn. Decreasing summer precipitation was observed in most regions of Germany, with particular focus on the south and west.
The seasonal picture, however, was again differently represented in the contributing months, e.g.\ increasing autumn precipitation in the south of Germany is formed by strong trends in the south-west in October and in the south-east in November. These results emphasise the high spatial and temporal organisation of precipitation changes.
% Paper 2
The next step towards attributing precipitation trends to changes in large-scale atmospheric patterns was the derivation of a weather pattern classification that sufficiently stratifies the local climate variables under investigation. Focussing on temperature, radiation, and humidity in addition to precipitation, a classification based on mean sea level pressure, near-surface temperature, and specific humidity was found to have the best skill in explaining the variance of the local variables. A rather high number of 40 patterns was selected, allowing typical pressure patterns being assigned to specific seasons by the associated temperature patterns. While the skill in explaining precipitation variance is rather low, better skill was achieved for radiation and, of course, temperature.
Most of the recent GCMs from the CMIP5 ensemble were found to reproduce these weather patterns sufficiently well in terms of frequency, seasonality, and persistence.
% Paper 3
Finally, the weather patterns were analysed for trends in pattern frequency, seasonality, persistence, and trends in pattern-specific precipitation and temperature. To overcome uncertainties in trend detection resulting from the selected time period, all possible periods in 1901-2010 with a minimum length of 31 years were considered. Thus, the assumption of a constant link between patterns and local weather was tested rigorously. This assumption was found to hold true only partly. While changes in temperature are mainly attributable to changes in pattern frequency, for precipitation a substantial amount of change was detected within individual patterns.
Magnitude and even sign of trends depend highly on the selected time period. The frequency of certain patterns is related to the long-term variability of large-scale circulation modes.
Changes in precipitation were found to be heterogeneous not only in space, but also in time - statements on trends are only valid for the specific time period under investigation. While some part of the trends can be attributed to changes in the large-scale circulation, distinct changes were found within single weather patterns as well.
The results emphasise the need to analyse multiple periods for thorough trend detection wherever possible and add some note of caution to the application of downscaling approaches based on weather patterns, as they might misinterpret the effect of climate change due to neglecting within-type trends.
urn:nbn:de:kobv:517-opus4-412725
online registration
Dissertation, Universität Potsdam, 2018
RC 20438, UT 8970
CC-BY - Namensnennung 4.0 International
Aline Murawski
eng
uncontrolled
precipitation
eng
uncontrolled
weather pattern
eng
uncontrolled
trend analyses
deu
uncontrolled
Niederschlag
deu
uncontrolled
Wetterlagen
deu
uncontrolled
Trendanalysen
Geowissenschaften
open_access
Institut für Geowissenschaften
Institut für Erd- und Umweltwissenschaften
Universität Potsdam
Universität Potsdam
https://publishup.uni-potsdam.de/files/41272/murawski_diss.pdf
41846
2018
2018
eng
16
postprint
1
2018-11-12
2018-11-12
--
Seasonal drought prediction for semiarid northeastern Brazil
A set of seasonal drought forecast models was assessed and verified for the Jaguaribe River in semiarid northeastern Brazil. Meteorological seasonal forecasts were provided by the operational forecasting system used at FUNCEME (Ceará’s research foundation for meteorology)and by the European Centre for Medium-Range Weather Forecasts (ECMWF). Three downscaling approaches (empirical quantile mapping, extended downscaling and weather pattern classification) were tested and combined with the models in hindcast mode for the period 1981 to 2014. The forecast issue time was January and the forecast period was January to June. Hydrological drought indices were obtained by fitting a multivariate linear regression to observations. In short, it was possible to obtain forecasts for (a) monthly precipitation,(b) meteorological drought indices, and (c) hydrological drought indices. The skill of the forecasting systems was evaluated with regard to root mean square error (RMSE), the Brier skill score (BSS) and the relative operating characteristic skill score (ROCSS). The tested forecasting products showed similar performance in the analyzed metrics. Forecasts of monthly precipitation had little or no skill considering RMSE and mostly no skill with BSS. A similar picture was seen when forecasting meteorological drought indices: low skill regarding RMSE and BSS and significant skill when discriminating hit rate and false alarm rate given by the ROCSS (forecasting drought events of, e.g., SPEI1 showed a ROCSS of around 0.5). Regarding the temporal variation of the forecast skill of the meteorological indices, it was greatest for April, when compared to the remaining months of the rainy season, while the skill of reservoir volume forecasts decreased with lead time. This work showed that a multi-model ensemble can forecast drought events of timescales relevant to water managers in northeastern Brazil with skill. But no or little skill could be found in the forecasts of monthly precipitation or drought indices of lower scales, like SPI1. Both this work and those here revisited showed that major steps forward are needed in forecasting the rainy season in northeastern Brazil.
Hydrology and Earth System Sciences
verification of six hydro-meteorological forecast products
urn:nbn:de:kobv:517-opus4-418461
online registration
Hydrology and earth system sciences 22 (2018) Nr.9, S.5041-5056 DOI:10.5194/hess-22-5041-2018
<a href="http://publishup.uni-potsdam.de/opus4-ubp/frontdoor/index/index/docId/41845">Bibliographieeintrag der Originalveröffentlichung/Quelle</a>
CC-BY - Namensnennung 4.0 International
José Miguel Martins Delgado
Sebastian Voss
Gerd Bürger
Klaus Josef Vormoor
Aline Murawski
José Marcelo Rodrigues Pereira
Eduardo Martins
Francisco Vasconcelos Júnior
Till Francke
Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
476
eng
uncontrolled
Hydrological drought
eng
uncontrolled
River-Basin
eng
uncontrolled
Model
eng
uncontrolled
Patterns
eng
uncontrolled
Precipitation
eng
uncontrolled
Variability
eng
uncontrolled
Nordeste
Geowissenschaften
open_access
Mathematisch-Naturwissenschaftliche Fakultät
Referiert
Open Access
Universität Potsdam
https://publishup.uni-potsdam.de/files/41846/pmnr476.online.pdf
41845
2018
2018
eng
5041
5056
16
9
22
article
Copernicus Publ.
Göttingen
1
2018-09-28
2018-09-28
--
Seasonal drought prediction for semiarid northeastern Brazil
A set of seasonal drought forecast models was assessed and verified for the Jaguaribe River in semiarid northeastern Brazil. Meteorological seasonal forecasts were provided by the operational forecasting system used at FUNCEME (Ceará’s research foundation for meteorology)and by the European Centre for Medium-Range Weather Forecasts (ECMWF). Three downscaling approaches (empirical quantile mapping, extended downscaling and weather pattern classification) were tested and combined with the models in hindcast mode for the period 1981 to 2014. The forecast issue time was January and the forecast period was January to June. Hydrological drought indices were obtained by fitting a multivariate linear regression to observations. In short, it was possible to obtain forecasts for (a) monthly precipitation,(b) meteorological drought indices, and (c) hydrological drought indices. The skill of the forecasting systems was evaluated with regard to root mean square error (RMSE), the Brier skill score (BSS) and the relative operating characteristic skill score (ROCSS). The tested forecasting products showed similar performance in the analyzed metrics. Forecasts of monthly precipitation had little or no skill considering RMSE and mostly no skill with BSS. A similar picture was seen when forecasting meteorological drought indices: low skill regarding RMSE and BSS and significant skill when discriminating hit rate and false alarm rate given by the ROCSS (forecasting drought events of, e.g., SPEI1 showed a ROCSS of around 0.5). Regarding the temporal variation of the forecast skill of the meteorological indices, it was greatest for April, when compared to the remaining months of the rainy season, while the skill of reservoir volume forecasts decreased with lead time. This work showed that a multi-model ensemble can forecast drought events of timescales relevant to water managers in northeastern Brazil with skill. But no or little skill could be found in the forecasts of monthly precipitation or drought indices of lower scales, like SPI1. Both this work and those here revisited showed that major steps forward are needed in forecasting the rainy season in northeastern Brazil.
Hydrology and Earth System Sciences
verification of six hydro-meteorological forecast products
10.5194/hess-22-5041-2018
1027-5606
1607-7938
online registration
PA 2018_64
Publikationsfonds der Universität Potsdam
<a href="http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-418461">Zweitveröffentlichung in der Schriftenreihe Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe ; 476</a>
1428.00
CC-BY - Namensnennung 4.0 International
José Miguel Martins Delgado
Sebastian Voss
Gerd Bürger
Klaus Josef Vormoor
Aline Murawski
José Marcelo Rodrigues Pereira
Eduardo Martins
Francisco Vasconcelos Júnior
Till Francke
eng
uncontrolled
Hydrological drought
eng
uncontrolled
River-Basin
eng
uncontrolled
Model
eng
uncontrolled
Patterns
eng
uncontrolled
Precipitation
eng
uncontrolled
Variability
eng
uncontrolled
Nordeste
Geowissenschaften
open_access
Mathematisch-Naturwissenschaftliche Fakultät
Referiert
Publikationsfonds der Universität Potsdam
Open Access