An Evaluation Matrix to Compare Computer Hydrological Models for Flood Predictions

Filianoti, Pasquale; Gurnari, Luana; Zema, Demetrio Antonio; Bombino, Giuseppe; Sinagra, Marco; Tucciarelli, Tullio

doi:10.3390/hydrology7030042

Cited by 25 publications

(6 citation statements)

References 65 publications

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“…The hydrological processes in burned soils are very complex, since several factors (weather, fire severity, vegetation cover, soil properties, morphology, and land management) influence the hydrological response of soil [2,4,15]. Computer-based hydrological models are essential tools to better understand and predict the hydrological processes in a costeffective and time-efficient way [16], including in burned soils. However, validation under different environmental conditions is required, to ensure model applicability and reliability for predicting post-fire hydrology [17,18].…”

Section: Introductionmentioning

confidence: 99%

Modelling the Event-Based Hydrological Response of Mediterranean Forests to Prescribed Fire and Soil Mulching with Fern Using the Curve Number, Horton and USLE-Family (Universal Soil Loss Equation) Models

Carrà

Bombino

Lucas‐Borja

et al. 2021

Land

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The SCS-CN, Horton, and USLE-family models are widely used to predict and control runoff and erosion in forest ecosystems. However, in the literature there is no evidence of their use in Mediterranean forests subjected to prescribed fire and soil mulching. To fill this gap, this study evaluates the prediction capability for runoff and soil loss of the SCS-CN, Horton, MUSLE, and USLE-M models in three forests (pine, chestnut, and oak) in Southern Italy. The investigation was carried out at plot and event scales throughout one year, after a prescribed fire and post-fire soil mulching with fern. The SCS-CN and USLE-M models were accurate in predicting runoff volume and soil loss, respectively. In contrast, poor predictions of the modelled hydrological variables were provided by the models in unburned plots, and by the Horton and MUSLE models for all soil conditions. This inaccuracy may have been due to the fact that the runoff and erosion generation mechanisms were saturation-excess and rainsplash, while the Horton and MUSLE models better simulate infiltration-excess and overland flow processes, respectively. For the SCS-CN and USLE-M models, calibration was needed to obtain accurate predictions of surface runoff and soil loss; furthermore, different CNs and C factors must be input throughout the year to simulate the variability of the hydrological response of soil after fire. After calibration, two sets of CNs and C-factor values were suggested for applications of the SCS-CN and USLE-M models, after prescribed fire and fern mulching in Mediterranean forests. Once validated in a wider range of environmental contexts, these models may support land managers in controlling the hydrology of Mediterranean forests that are prone to wildfire risks.

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Section: Introductionmentioning

confidence: 99%

Modelling the Event-Based Hydrological Response of Mediterranean Forests to Prescribed Fire and Soil Mulching with Fern Using the Curve Number, Horton and USLE-Family (Universal Soil Loss Equation) Models

Carrà

Bombino

Lucas‐Borja

et al. 2021

Land

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“…The model belongs to the family of the probability distribution models (PDMs; Moore, 1985), which represent the basin as a series of storages of capacity c. In particular, the TOPDM uses the spatial distribution of the topographic index to derive the probability distribution of the capacity of the considered storages. The model is capable of working at different temporal scales (i.e., from sub-hourly to daily); this makes the TOPDM suitable for simulating runoff and analyzing hydrological processes at the catchment scale, using a daily time step, or for simulating the flood forcing within the small Mediterranean basins, using an hourly or sub-hourly time step (Forestieri et al, 2016).…”

Section: Hydrological Modeling: the Topdmmentioning

confidence: 99%

A paradigm of extreme rainfall pluvial floods in complex urban areas: the flood event of 15 July 2020 in Palermo (Italy)

Francipane

Pumo

Sinagra

et al. 2021

Nat. Hazards Earth Syst. Sci.

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Abstract. In the last few years, some regions of the Mediterranean area have witnessed a progressive increase in extreme events, such as urban and flash floods, as a response to the increasingly frequent and severe extreme rainfall events, which are often exacerbated by the ever-growing urbanization. In such a context, the urban drainage systems may not be sufficient to convey the rainwater, thus increasing the risk deriving from the occurrence of such events. This study focuses on a particularly intense urban flood that occurred in Palermo (Italy) on 15 July 2020; it represents a typical pluvial flood due to extreme rainfall on a complex urban area that many cities have experienced in recent years, especially in the Mediterranean region. A conceptual hydrological model and a 2D hydraulic model, particularly suitable for simulations in a very complex urban context, have been used to simulate the event. Results have been qualitatively validated by means of crowdsourced information and satellite images. The experience of Palermo, which has highlighted the urgent need for a shift in the way stormwater in urban settlements is managed, can be assumed to be a paradigm for modeling pluvial floods in complex urban areas under extreme rainfall conditions. Although the approaches and the related policies cannot be identical for all cities, the modeling framework used here to assess the impacts of the event under study and some conclusive remarks could be easily transferred to other, different urban contexts.

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“…For instance, construction of several check dams in the middle of the last century has avoided disrupting floods with heavy damage to infrastructures and loss of human lives in torrents of Southern Italy [23,24]. In this environment, the peculiar morphological characteristics of catchments (small drainage areas with short length and steep profile of channels), coupled with intrinsic climatic forcing (frequent and intense rainstorms), usually produce heavy flash floods with high erosive power, often causing hydro-geological instability and disruption [25][26][27].…”

Section: Control Of the Hydrological Response In Ephemeral Torrents Of The Mediterraneanmentioning

confidence: 99%

Comparing the Hydrological Response of Forested Headwaters (Unregulated and Regulated with Check Dams) under Mediterranean Semi-Arid Conditions

Bombino

Pérez‐Cutillas

D’Agostino

et al. 2021

Water

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This study has evaluated the runoff and erosion rates in torrents of Southern Italy, two forested headwaters with very similar climatic, hydrological and geomorphological characteristics; in one headwater, 15 check dams were installed in the mid-1950s, while the other is not regulated with engineering works. To this aim, the hydrological variables have been modeled over 15 years after check dam installation using the HEC-HMS (Hydrologic Engineering Center-Hydrologic Modeling System) model coupled to the MUSLE (Modified Universal Soil Loss Equation) equation. The model simulations have shown that check dams have not played a significant role in reducing the surface runoff compared to the unregulated torrent; in both catchments, the well-developed forest cover determined very low runoff coefficients (lower than 0.3%) with a scarce runoff generation capacity. Additionally, the reduction in peak flow due to the check dams was not significant, on average −7.4% compared to the unregulated headwater. Check dams have retained sediments for about 8–10 years after their installation, reducing erosion by about 35%, although soil loss was much lower than the tolerance limit in both catchments. After the sediment retention capacity of the dam sediment wedge was depleted, the sediment yield in the regulated torrent was even higher (by about 20%) compared to the unregulated catchment. Overall, the study has shown that the use of check dams as a catchment management strategy of forested headwaters under semi-arid Mediterranean conditions should be considered with caution, since the structures could be ineffective to reduce water and sediment flows during floods or, in some cases, check dams may increase erosion rates.

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An Evaluation Matrix to Compare Computer Hydrological Models for Flood Predictions

Cited by 25 publications

References 65 publications

Modelling the Event-Based Hydrological Response of Mediterranean Forests to Prescribed Fire and Soil Mulching with Fern Using the Curve Number, Horton and USLE-Family (Universal Soil Loss Equation) Models

Modelling the Event-Based Hydrological Response of Mediterranean Forests to Prescribed Fire and Soil Mulching with Fern Using the Curve Number, Horton and USLE-Family (Universal Soil Loss Equation) Models

A paradigm of extreme rainfall pluvial floods in complex urban areas: the flood event of 15 July 2020 in Palermo (Italy)

Comparing the Hydrological Response of Forested Headwaters (Unregulated and Regulated with Check Dams) under Mediterranean Semi-Arid Conditions

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