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4. Lessons from the 2018-2019 European droughts : a collective need for unifying drought risk management

Author

Blauhut, Veit, Stoelzle, Michael, Ahopelto, Lauri, Brunner, Manuela I., Teutschbein, Claudia, Wendt, Doris E., Akstinas, Vytautas, Bakke, Sigrid J., Barker, Lucy J., Bartošová, Lenka, Briede, Agrita, Cammalleri, Carmelo, Kalin, Ksenija Cindrić, De Stefano, Lucia, Fendeková, Miriam, Finger, David C., Huysmans, Marijke, Ivanov, Mirjana, Jaagus, Jaak, Jakubínský, JiÅ™í, Krakovska, Svitlana, Laaha, Gregor, Lakatos, Monika, Manevski, Kiril, Neumann Andersen, Mathias, Nikolova, Nina, Osuch, Marzena, Van Oel, Pieter, Radeva, Kalina, Romanowicz, Renata J., Toth, Elena, Trnka, Mirek, Urošev, Marko, Urquijo Reguera, Julia, Sauquet, Eric, Stevkov, Aleksandra, Tallaksen, Lena M., Trofimova, Iryna, Van Loon, Anne F., Van Vliet, Michelle T.H., Vidal, Jean Philippe, Wanders, Niko, Werner, Micha, Willems, Patrick, Zivković, Nenad, Hydrologie, Landdegradatie en aardobservatie, Blauhut V., Stoelzle M., Ahopelto L., Brunner M.I., Teutschbein C., Wendt D.E., Akstinas V., Bakke S.J., Barker L.J., Bartosova L., Briede A., Cammalleri C., Kalin K.C., De Stefano L., Fendekova M., Finger D.C., Huysmans M., Ivanov M., Jaagus J., Jakubinsky J., Krakovska S., Laaha G., Lakatos M., Manevski K., Neumann Andersen M., Nikolova N., Osuch M., Van Oel P., Radeva K., Romanowicz R.J., Toth E., Trnka M., Urosev M., Urquijo Reguera J., Sauquet E., Stevkov A., Tallaksen L.M., Trofimova I., Van Loon A.F., Van Vliet M.T.H., Vidal J.-P., Wanders N., Werner M., Willems P., Zivkovic N., University of Freiburg, Department of Built Environment, Uppsala University, University of Birmingham, Lithuanian Energy Institute, University of Oslo, Centre for Ecology and Hydrology, Czech Academy of Sciences, University of Latvia, European Commission Joint Research Centre Institute, Croatian Meteorological and Hydrological Service, Complutense University, Comenius University in Bratislava, Reykjavík University, Vrije Universiteit Brussel, Institute of Hydrometeorology and Seismology of Montenegro, University of Tartu, Ukrainian Hydrometeorological Institute, University of Natural Resources and Life Sciences, Vienna, Hungarian Meteorological Service, Aarhus University, Sofia University St. Kliment Ohridski, Institute of Geophysics of the Polish Academy of Sciences, Wageningen University and Research Centre, Universita di Bologna, Serbian Academy of Sciences and Arts, Technical University of Madrid, INRAE, National Hydrometeorological Service, Vrije Universiteit Amsterdam, Utrecht University, IHE Delft Institute for Water Education, KU Leuven, University of Belgrade, Aalto-yliopisto, Aalto University, Hydrology and Hydraulic Engineering, Water and Climate Risk, Hydrologie, and Landdegradatie en aardobservatie

Subjects
IMPACTS, drought, risk, management, strategy, stakeholders, Europe, Hidrología, media_common.quotation_subject, WATER-RESOURCES, CIRCULATION, Vulnerability, Earth and Planetary Sciences(all), Oceanografi, hydrologi och vattenresurser, METEOROLOGICAL DROUGHT, EVENTS, Oceanography, Hydrology and Water Resources, Short summary: Recent drought events caused enormous damage in Europe. We therefore questioned the existence and effect of current drought management strategies on the actual impacts and how drought is perceived by relevant stakeholders. Over 700 participants from 28 European countries provided insights into drought hazard and impact perception and current management strategies. The study concludes with an urgent need to collectively combat drought risk via a European macro-level drought governance approach, 11. Sustainability, Meteorology & Atmospheric Sciences, Life Science, Geosciences, Multidisciplinary, Environmental planning, media_common, Science & Technology, WIMEK, Corporate governance, Geology, Directive, Hazard, 6. Clean water, Water Resources Management, Water resources, Geography, Harm, 13. Climate action, Physical Sciences, Water Resources, General Earth and Planetary Sciences, Water Systems and Global Change, Psychological resilience, Hydrology, SDG 6 - Clean Water and Sanitation, Diversity (business)
Abstract

Funding Information: This open-access publication was funded by the University of Freiburg. Funding Information: Financial support. The project is supported by the Wassernetzwerk Baden-Württemberg (Water Research Network of the State Baden-Württemberg), which is funded by the Ministerium für Wissenschaft, Forschung und Kunst Baden-Württemberg (Ministry of Science, Research and the Arts of the State Baden-Württemberg) (grant no. AZ. 7532.21/2.1.6) and Maa-ja vesitekniikan tuki ry foundation. Doris E. Wendt acknowledges her support as part of the NERC-funded Groundwater Drought Initiative (NE/R004994/1). Lucy J. Barker was supported by the Natural Environment Research Council (NE/R016429/1) as part of the UK-SCAPE programme delivering National Capability. The contributions of Mirek Trnka, Lenka Bartošová, and Jaak Jaagus have been supported by SustES – Adaptation strategies for sustainable ecosystem services and food security under adverse environmental conditions (CZ.02.1.01/0.0/0.0/16_019/0000797). Publisher Copyright: © 2022 Veit Blauhut et al. Drought events and their impacts vary spatially and temporally due to diverse pedo-climatic and hydrologic conditions, as well as variations in exposure and vulnerability, such as demographics and response actions. While hazard severity and frequency of past drought events have been studied in detail, little is known about the effect of drought management strategies on the actual impacts and how the hazard is perceived by relevant stakeholders. In a continental study, we characterised and assessed the impacts and the perceptions of two recent drought events (2018 and 2019) in Europe and examined the relationship between management strategies and drought perception, hazard, and impact. The study was based on a pan-European survey involving national representatives from 28 countries and relevant stakeholders responding to a standard questionnaire. The survey focused on collecting information on stakeholders' perceptions of drought, impacts on water resources and beyond, water availability, and current drought management strategies on national and regional scales. The survey results were compared with the actual drought hazard information registered by the European Drought Observatory (EDO) for 2018 and 2019. The results highlighted high diversity in drought perception across different countries and in values of the implemented drought management strategies to alleviate impacts by increasing national and sub-national awareness and resilience. The study identifies an urgent need to further reduce drought impacts by constructing and implementing a European macro-level drought governance approach, such as a directive, which would strengthen national drought management and mitigate damage to human and natural assets.

Published
2022
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15. The use of unmanned aerial vehicles in flood hazard assessment.

Author

Karamuz, Emilia, Romanowicz, Renata J., and Doroszkiewicz, Joanna

Subjects
RISK assessment, FLOOD risk, WEATHER, FLOOD routing, FLOODS, REMOTE-sensing images, DRONE aircraft, ARTIFICIAL satellites
Abstract

Flood inundation models are central components of any flood risk analysis system because they transform the bulk discharge outputs from flood‐frequency analyses or rainfall‐runoff models into distributed predictions of flood hazard in terms of water depth, inundation extent, and flow velocity. The accuracy of flood hazard maps depends on the availability of distributed observations of inundation outlines. Unfortunately, the acquisition of aerial photographs or satellite images is costly and in addition, their temporal resolution is strongly limited by weather conditions. Remote sensing based on unmanned aerial vehicles (UAV) is becoming increasingly popular due its flexibility and quickly decreasing costs. In particular, UAV can provide precise up to date georeferenced information about the location of a river shorelines, channel geometry, and vegetation. This information is particularly useful for the calibration and validation of distributed flood routing models. The application of cheap, well georeferenced UAV images of river shorelines is an unprecedented source of distributed observations. The aim of this article is to present a procedure for the updating of boundary conditions of the hydrodynamic model, based on UAV‐born data. The approach proposed is also a very effective means of on‐line updating of flood risk maps and their verification. [ABSTRACT FROM AUTHOR]

Published
2020
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16. The critical role of uncertainty in projections of hydrological Extremes.

Author

Meresa, Hadush K. and Romanowicz, Renata J.

Abstract

This paper aims to quantify the uncertainty in the projections of future hydrological extremes in the BialaTarnowska River basin, south Poland. We follow a multi-model approach based on several climate projections obtained from the EUROCORDEX initiative, raw and downscaled realizations of catchment precipitation and temperature, and flow simulations derived using the hydrological HBV model. The projections cover the 21st century. Three sources of uncertainty were considered: one related to the hydrological model parameters uncertainty, the second related to climate projection ensemble spread and the third related to the distribution fit. The uncertainty of projected extreme indices related to hydrological model parameters was conditioned on flow observations from the reference period using the Generalised Likelihood Uncertainty Estimation approach, with separate weighting for high and low flow extremes. Flood quantiles were estimated using Generalize Extreme Value (GEV) distribution at different return periods and were based on two different lengths of the flow time series. The sensitivity analysis based on ANOVA shows that the uncertainty introduced by the HBV model parameters can be larger than the climate model variability and distribution fit uncertainty for the low-flow extremes whilst for the high-flow extremes higher uncertainty is observed from climate models than from hydrological parameter and distribution fit uncertainties. This implies that ignoring one of the three uncertainty sources may cause great risk to future hydrological extreme adaptations and water resource planning and management. [ABSTRACT FROM AUTHOR]

Published
2016
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17. Performance of ensemble streamflow forecasts under varied hydrometeorological conditions.

Author

Benninga, Harm-Jan F., Booij, Martijn J., Romanowicz, Renata J., and Rientjes, Tom H. M.

Abstract

The paper presents a methodology to give insight in the performance of ensemble streamflow forecasting systems. We developed an ensemble forecasting system for the Biała Tarnowska, a mountainous river catchment in southern Poland, and analysed the performance for lead times from 1 day to 10 days for low, medium and high streamflow and related runoff generating processes. Precipitation and temperature forecasts from the European Centre for Medium-Range Weather Forecasts serve as input to a deterministic lumped hydrological (HBV) model. Due to inconsistent bias, the best streamflow forecasts were obtained without pre- and post-processing of the meteorological and streamflow forecasts. Best forecast skill, relative to alternative forecasts based on historical measurements of precipitation and temperature, is shown for high streamflow and for snow accumulation low streamflow events. Forecasts of medium streamflow events and low streamflow events generated by precipitation deficit show less skill. To improve the performance of the forecasting system for high streamflow events, in particular the meteorological forecasts require improvement. For low streamflow forecasts, the hydrological model should be improved. The study recommends improving the reliability of the ensemble streamflow forecasts by including the uncertainties in hydrological model parameters and initial conditions, and by improving the dispersion of the meteorological input forecasts. [ABSTRACT FROM AUTHOR]

Published
2016
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18. Hydrology needed to manage droughts: the 2015 European case.

Author

Van Lanen, Henny A.J., Laaha, Gregor, Kingston, Daniel G., Gauster, Tobias, Ionita, Monica, Vidal, Jean‐Philippe, Vlnas, Radek, Tallaksen, Lena M., Stahl, Kerstin, Hannaford, Jamie, Delus, Claire, Fendekova, Miriam, Mediero, Luis, Prudhomme, Christel, Rets, Ekaterina, Romanowicz, Renata J., Gailliez, Sébastien, Wong, Wai Kwok, Adler, Mary‐Jeanne, and Blauhut, Veit

Subjects
DROUGHTS, SOIL moisture, RAINFALL, EVAPOTRANSPIRATION, VEGETATION & climate, CROP yields
Abstract

The author discusses drought which is considered as costliest natural hazard that is related to weather and it lead to deficiency among soil moisture as a hydrological drought. Topics discussed include effect of drought on Europe which occurred in 2015 due to lack of rainfall and high evapotranspiration, similarity shown by vegetation to the pattern of standardized precipitation evapotranspiration index (SPEI) and decrease in crop yields due to drought in soil water.

Published
2016
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19. Trends in projections of standardized precipitation indices in a future climate in Poland.

Author

Osuch, Marzena, Romanowicz, Renata J., Lawrence, Deborah, and Wong, Wai K.

Subjects
CLIMATE change, METEOROLOGICAL precipitation, ATMOSPHERIC models, GRID cells, BIAS correction (Topology)
Abstract

Possible future climate change effects on dryness conditions in Poland are estimated for six climate projections using the standardized precipitation index (SPI). The time series of precipitation represent six different climate model runs under the selected emission scenario for the period 1971-2099. Monthly precipitation values were used to estimate the SPI for multiple timescales (1, 3, 6, 12, and 24 months) for a spatial resolution of 25 km for the whole country. Trends in the SPI were analysed using the Mann- Kendall test with Sen's slope estimator for each grid cell for each climate model projection and aggregation scale, and results obtained for uncorrected precipitation and bias corrected precipitation were compared. Bias correction was achieved using a distribution-based quantile mapping (QM) method in which the climate model precipitation series were adjusted relative to gridded precipitation data for Poland. The results show that the spatial pattern of the trend depends on the climate model, the timescale considered and on the bias correction. The effect of change on the projected trend due to bias correction is small compared to the variability among climate models. We also summarize the mechanisms underlying the influence of bias correction on trends in precipitation and the SPI using a simple example of a linear bias correction procedure. In both cases, the bias correction by QM does not change the direction of changes but can change the slope of trend, and the influence of bias correction on SPI is much reduced. We also have noticed that the results for the same global climate model, driving different regional climate model, are characterized by a similar pattern of changes, although this behaviour is not seen at all timescales and seasons. [ABSTRACT FROM AUTHOR]

Published
2016
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20. The influence of parametric uncertainty on the relationships between HBV model parameters and climatic characteristics.

Author

Osuch, Marzena, Romanowicz, Renata J., and Booij, Martijn J.

Subjects
*HYDROLOGIC models, *RUNOFF models, *CLIMATE change, *PEARSON correlation (Statistics), *WATERSHEDS
Abstract

An HBV rainfall–runoff model was applied to test the influence of climatic characteristics on model parameter values. The methodology consisted of the calibration and cross-validation of the HBV model on a series of 5-year periods for four selected catchments (Axe, Kamp, Wieprz and Wimmera). The model parameters were optimized using the SCEM-UA method which allowed for their uncertainty also to be assessed. Nine climatic indices were selected for the analysis of their influence on model parameters, and divided into water-related and temperature-related indices. This allowed the dependence of HBV model parameters on climate characteristics to be explored following their response to climate change conditioned on the catchment’s physical characteristics. The Pearson correlation coefficient and weighted Pearson correlation coefficient were used to test the dependence. Most parameters showed a statistically significant dependence on several climatic indices in all catchments. The study shows that the results of the correlation analysis with and without parametric uncertainty taken into account differ significantly. [ABSTRACT FROM AUTHOR]

Published
2015
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21. A data based mechanistic approach to nonlinear flood routing and adaptive flood level forecasting

Author

Romanowicz, Renata J., Young, Peter C., Beven, Keith J., and Pappenberger, Florian

Subjects
*WATER levels, *FLOOD forecasting, *FLOODPLAINS, *FLOODPLAIN management
Abstract

Abstract: Operational flood forecasting requires accurate forecasts with a suitable lead time, in order to be able to issue appropriate warnings and take appropriate emergency actions. Recent improvements in both flood plain characterization and computational capabilities have made the use of distributed flood inundation models more common. However, problems remain with the application of such models. There are still uncertainties associated with the identifiability of parameters; with the computational burden of calculating distributed estimates of predictive uncertainty; and with the adaptive use of such models for operational, real-time flood inundation forecasting. Moreover, the application of distributed models is complex, costly and requires high degrees of skill. This paper presents an alternative to distributed inundation models for real-time flood forecasting that provides fast and accurate, medium to short-term forecasts. The Data Based Mechanistic (DBM) methodology exploits a State Dependent Parameter (SDP) modelling approach to derive a nonlinear dependence between the water levels measured at gauging stations along the river. The transformation of water levels depends on the relative geometry of the channel cross-sections, without the need to apply rating curve transformations to the discharge. The relationship obtained is used to transform water levels as an input to a linear, on-line, real-time and adaptive stochastic DBM model. The approach provides an estimate of the prediction uncertainties, including allowing for heterescadasticity of the multi-step-ahead forecasting errors. The approach is illustrated using an 80km reach of the River Severn, in the UK. [Copyright &y& Elsevier]

Published
2008
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22. Data assimilation and adaptive forecasting of water levels in the river Severn catchment, United Kingdom.

Author

Romanowicz, Renata J., Young, Peter C., and Beven, Keith J.

Abstract

This paper describes data assimilation (DA) and adaptive forecasting techniques for flood forecasting and their application to forecasting water levels at various locations along a 120 km reach of the river Severn, United Kingdom. The methodology exploits the top-down, data-based mechanistic (DBM) approach to the modeling of environmental processes, concentrating on the identification and estimation of those 'dominant modes' of dynamic behavior that are most important for flood prediction. In particular, hydrological processes active in the catchment are modeled using the state-dependent parameter (SDP) method of estimating a nonlinear, effective rainfall transformation together with a linear stochastic transfer function (STF) method for characterizing both the effective rainfall-river level behavior and the river level routing processes. The complete model consists of these lumped parameter, linear and nonlinear stochastic, dynamic elements connected in a quasi-distributed manner that represents the physical structure of the catchment. The adaptive forecasting system then utilizes a state-space form of the complete catchment model, including allowance for heteroscedasticity in the errors, as the basis for data assimilation and forecasting using a Kalman filter forecasting engine. Here the predicted model states (water levels) and adaptive parameters are updated recursively in response to input data received in real time from sensors in the catchment. Direct water level forecasting is considered, rather than flow, because this removes the need to transform the level measurement through the rating curve and tends to decrease the forecasting errors. [ABSTRACT FROM AUTHOR]

Published
2006
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23. Temperature Changes and Their Impact on Drought Conditions in Winter and Spring in the Vistula Basin.

Author

Karamuz, Emilia and Romanowicz, Renata J.

Subjects
TEMPERATURE, SNOW cover, WINTER, SOIL moisture, DROUGHTS, TREND analysis
Abstract

Inter-annual variability of hydro-meteorological variables indirectly influence soil moisture conditions in winter and early spring seasons. The interactions between temperature changes and drought conditions are studied by an application of statistical analyses of minimum temperature (Tmin), consecutive days with temperature exceeding the 0 °C threshold value, the number of melting pulses in the winter season and Standardized Evaporation Precipitation Index (SPEI). Additionally, shifts in the onset of days with spring temperature and snow cover occurrence are analysed. A Mann–Kendall test is applied for the trend analysis. Studies have shown significant changes in thermal characteristics in the winter season over the past 70 years, which affect the moisture conditions in the Vistula River Basin. As a result of those changes, the Vistula Basin is more prone to droughts. [ABSTRACT FROM AUTHOR]

Published
2021
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24. The Influence of Flow Projection Errors on Flood Hazard Estimates in Future Climate Conditions.

Author

Doroszkiewicz, Joanna, Romanowicz, Renata J., and Kiczko, Adam

Subjects
WATERSHEDS, WATER levels, STREAMFLOW, SIMULATION methods & models, RUNOFF
Abstract

The continuous simulation approach to assessing the impact of climate change on future flood hazards consists of a chain of consecutive actions, starting from the choice of the global climate model (GCM) driven by an assumed CO2 emission scenario, through the downscaling of climatic forcing to a catchment scale, an estimation of flow using a hydrological model, and subsequent derivation of flood hazard maps with the help of a flow routing model. The procedure has been applied to the Biala Tarnowska catchment, Southern Poland. Future climate projections of rainfall and temperature are used as inputs to the precipitation-runoff model simulating flow in part of the catchment upstream of a modeled river reach. An application of a lumped-parameter emulator instead of a distributed flow routing model, MIKE11, substantially lowers the required computation times. A comparison of maximum inundation maps derived using both the flow routing model, MIKE11, and its lump-parameter emulator shows very small differences, which supports the feasibility of the approach. The relationship derived between maximum annual inundation areas and the upstream flow of the study can be used to assess the floodplain extent response to future climate changes. The analysis shows the large influence of the one-grid-storm error in climate projections on the return period of annual maximum inundation areas and their uncertainty bounds. [ABSTRACT FROM AUTHOR]

Published
2019
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25. A semi-empirical model to assess uncertainty of spatial patterns of erosion

Author

Vigiak, Olga, Sterk, Geert, Romanowicz, Renata J., and Beven, Keith J.

Subjects
*EROSION, *SEDIMENTATION & deposition, *GLUE, *SEDIMENT transport
Abstract

Abstract: Distributed erosion models are potentially good tools for locating soil sediment sources and guiding efficient Soil and Water Conservation (SWC) planning, but the uncertainty of model predictions may be high. In this study, the distribution of erosion within a catchment was predicted with a semi-empirical erosion model that combined a semi-distributed hydrological model with the Morgan, Morgan and Finney (MMF) empirical erosion model. The model was tested in a small catchment of the West Usambara Mountains (Kwalei catchment, Tanzania). Soil detachability rates measured in splash cups (0.48–1.16gJ−1) were close to model simulations (0.30–0.35gJ−1). Net erosion rates measured in Gerlach troughs (0.01–1.05kgm−2 per event) were used to calibrate the sediment transport capacity of overland flow. Uncertainties of model simulations due to parameterisation of overland flow sediment transport capacity were assessed with the Generalized Likelihood Uncertainty Estimation (GLUE) methodology. The quality of the spatial predictions was assessed by comparing the simulated erosion pattern with the field-observed erosion pattern, measuring the agreement with the weighted Kappa coefficient of the contingency table. Behavioural parameter sets (weighted Kappa >0.50) were those with short reinfiltration length (<1.5m) and ratio of overland flow power α to local topography power γ close to 0.5. In the dynamic Hortonian hydrologic regime and the dissected terrain of Kwalei catchment, topography controlled the distribution of erosion more than overland flow. Simulated erosion rates varied from −4 to +2kgm−2 per season. The model simulated correctly around 75% of erosion pattern. The uncertainty of model predictions due to sediment transport capacity was high; around 10% of the fields were attributed to either slight or severe erosion. The difficult characterisation of catchment-scale effective sediment transport capacity parameters poses a major limit to distributed erosion modelling predicting capabilities. [Copyright &y& Elsevier]

Published
2006
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