Assessing uncertainties in surface water security: An empirical multimodel approach

Rodrigues, Dulce Buchala Bicca; Gupta, Hoshin; Mendiondo, Eduardo Mário; Oliveira, Paulo Tarso Sanches de

doi:10.1002/2014wr016691

Cited by 16 publications

(6 citation statements)

References 57 publications

(79 reference statements)

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“…The SWAT model (Gassman et al, 2007) is a physically based and continuous watershed simulation model, which is capable of simulating a high level of spatial details, and thus, it has been widely used for hydrological assessment. The SWAT model uses a basin discretization that divides the study area into several subbasins and Hydrological Response Units (HRUs), and subbasins have unique land use, soil, and slope categories (Neitsch et al, 2011; Rodrigues et al, 2015). Each HRU conducts a simulation of hydrological processes, and the output water fluxes are routed to the watershed to generate the total discharge values.…”

Section: Data Sets Models and Drought Indicesmentioning

confidence: 99%

“…The calibration period was selected from 1981 to 1990, and the validation period was from 1991 to 1995. The HYMOD and SWAT models were combined into a general framework using a weighted‐average aggregation method (Rodrigues et al, 2015; Wilby & Harris , 2006). The weights were calculated in proportion to model performance based on the adjusted correlation coefficients (CORs), which were computed for the calibration period (1981–1990), and then the weights were applied for the validation period (1991–1995) and the forecast period (2085–2099) by

R_{adj} = \sqrt{1 - \frac{()(, 1 - r^{2}) ()(, n - 1)}{n - 2}},

where R adj is the adjusted COR, r is the linear COR, and n is the sample element.…”

Section: Data Sets Models and Drought Indicesmentioning

confidence: 99%

See 1 more Smart Citation

Probabilistic Projections of Hydrological Droughts Through Convection‐Permitting Climate Simulations and Multimodel Hydrological Predictions

Chen

Wang

et al. 2020

JGR Atmospheres

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The reliable projection of future changes in hydrological drought characteristics plays a crucial role in providing meaningful insights into agricultural development and water resources planning under climate change. In this study, we develop probabilistic projections of hydrological drought characteristics through a convection‐permitting climate simulation and a multimodel hydrological prediction for two major river basins in South Texas of the United States. The probabilistic hydrological drought projection depicts the future evolution of spatiotemporal characteristics of droughts under best‐ and worst‐case scenarios. Our findings reveal that there is a considerable variation in hydrological drought regimes near the urban area in South Texas. And the prolonged severe drought events are expected to be punctuated by the increasing extreme precipitation in a changing climate. This could lead to an increasing number of the dry‐wet abrupt alternation events. Moreover, hydrological droughts are projected to occur more frequently for the fall season in the Guadalupe River Basin and for the winter season in the Blanco River Basin, advancing our understanding of future changes in seasonal characteristics of hydrological droughts at a river basin scale.

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Section: Data Sets Models and Drought Indicesmentioning

confidence: 99%

R_{adj} = \sqrt{1 - \frac{()(, 1 - r^{2}) ()(, n - 1)}{n - 2}},

where R adj is the adjusted COR, r is the linear COR, and n is the sample element.…”

Section: Data Sets Models and Drought Indicesmentioning

confidence: 99%

Probabilistic Projections of Hydrological Droughts Through Convection‐Permitting Climate Simulations and Multimodel Hydrological Predictions

Chen

Wang

et al. 2020

JGR Atmospheres

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“…1), the climate is humid subtropical, according to the Köppen climate classification, characterized by hot and wet summers (October to March) and dry winters (June to September) (Alvares et al, 2013). The average annual rainfall and temperature are 1592 mm and 25 • C, respectively (Rodríguez-Lado et al, 2007). Pasture used for livestock production (70 %) is predominant, and the remaining natural vegetation accounts for 12 % and 8 % of the respective eucalyptus and pine of forest wood crops.…”

Section: Study Areamentioning

confidence: 99%

“…Due to its ability to successfully represent the major processes driving catchment dynamics, and owing to its relative simplicity, HYMOD has been widely used in studies related to the assessment of methods for model calibration, uncertainty and sensitive analysis, climate change impacts, water security, and several others (Bastola and Misra, 2014;Chen et al, 2013;Gong et al, 2013;Parra et al, 2018;Rodrigues et al, 2015). The relative simplicity of its structure facilitates computationally fast data processing, and it imposes minimal requirements for input data, while maintaining a suit- able level of hydrological process representation (Gong et al, 2013).…”

Section: Hydrological Modelingmentioning

confidence: 99%

Assessing water security in the São Paulo metropolitan region under projected climate change

Gesualdo¹,

Oliveira²,

Rodrigues³

et al. 2019

Hydrol. Earth Syst. Sci.

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Abstract. Climate change affects the global water cycle and has the potential to alter water availability for food–energy–water production, and for ecosystems services, on regional and local scales. An understanding of these effects is crucial for assessing future water availability, and for the development of sustainable management plans. Here, we investigate the influence of anticipated climate change on water security in the Jaguari Basin, which is the main source of freshwater for 9 million people in the São Paulo metropolitan region (SPMR). First, we calibrate and evaluate a hydrological model using daily observed data, obtaining satisfactory coefficient of determination and Kling–Gupta efficiency values for both periods. To represent possible climate change scenarios up to 2095, we consider two International Panel on Climate Change (IPCC) Representative Concentration Pathways (RCP4.5 and RCP8.5) and use an ensemble of future projections generated by 17 general circulation models (GCMs). These data were used to drive the hydrological model to generate projected scenarios of streamflow. We then used indicators of water scarcity and vulnerability to carry out a quantitative analysis of provision probability. Our results indicate that streamflow can be expected to exhibit increased interannual variability, significant increases in flow rate between January and March, and a 2-month extension of the hydrological dry season (currently June to September) until November. The latter includes a more than a 35 % reduction in streamflow during September through November (with a > 50 % reduction in October). Our findings indicate an increased risk of floods and droughts accompanied by an expansion of the basin critical period, and our analysis of the water security indices identifies October and November as the most vulnerable months. Overall, our analysis exposes the fragility of water security in the São Paulo metropolitan region, and provides valuable technical and scientific information that can be used to guide regional plans and strategies to cope with potential future water scarcity.

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“…Due to its ability to successfully represent the major processes driving catchment dynamics, and due to its relative simplicity, HYMOD has been widely used in studies related to assessment of methods for model calibration, uncertainty and sensitive analysis, climate change impacts, water security, and several others (Bastola and Misra, 2014;Chen et al, 2013;Gong et al, 2013;Parra et al, 2018;Rodrigues et al, 2015). The relative simplicity of its structure facilitates computationally fast data processing, and it imposes minimal requirements for input data, while maintain a suitable level of hydrological process representation (Gong et al, 2013).…”

Section: Hydrological Modelingmentioning

confidence: 99%

Assessing Water Security in the Sao Paulo Metropolitan Region Under Projected Climate Change

Gesualdo¹,

Oliveira²,

Rodrigues³

et al. 2019

Preprint

Self Cite

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Abstract. Climate change affects the global water cycle and has the potential to alter water availability for food-energy-water production, and for ecosystems services, on regional and local scales. An understanding these effects is crucial to assessing future water availability, and for the development of sustainable management plans. Here, we investigate the influence of anticipated climate change on water security in the Jaguari Basin, which is the main source of freshwater for 9 million people in the Sao Paulo Metropolitan Region (SPMR). First, we calibrate and evaluate a hydrological model using daily observed data, obtaining satisfactory Coefficient of Determination and Kling-Gupta efficiency values for both periods. To represent possible climate change scenarios up to 2095, we consider two International Panel on Climate Change (IPCC) Representative Concentration Pathways (RCP 4.5 and RCP 8.5) and use an ensemble of future projections generated by 17 General Circulation Models (GCMs). These data were used to drive the hydrological model to generate projected scenarios of streamflow. Then we used indicators of water scarcity and vulnerability to carry out a quantitative analysis of provision probability. Our results indicate that streamflow can be expected to exhibit increased interannual variability, significant increases in flow rate between January and March, and an extension of the dry season (currently June to September) until November. The latter includes more than 35 % reduction in streamflow during September through November (with > 50 % reduction in October). Our findings indicate an increased risk of floods and droughts accompanied by an expansion of the basin critical period, and our analysis of the Water Security Indices identifies October and November as the most vulnerable months. Overall, our analysis exposes the fragility of water security in the Sao Paulo metropolitan region, and provides valuable technical and scientific information that can be used to guide regional plans and strategies to cope with potential future water scarcity.

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Assessing uncertainties in surface water security: An empirical multimodel approach

Cited by 16 publications

References 57 publications

Probabilistic Projections of Hydrological Droughts Through Convection‐Permitting Climate Simulations and Multimodel Hydrological Predictions

Probabilistic Projections of Hydrological Droughts Through Convection‐Permitting Climate Simulations and Multimodel Hydrological Predictions

Assessing water security in the São Paulo metropolitan region under projected climate change

Assessing Water Security in the Sao Paulo Metropolitan Region Under Projected Climate Change

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