Hydrological Modeling in Tropical Regions via TopModel. Study Case: Central Sector of the Middle Magdalena Valley - Colombia

Arenas-Bautista, María Cristina; Arboleda-Obando, Pedro; Duque-Gardeazabal, Nicolás; Saavedra-Cifuentes, Edwin; Donado, Leonardo David

doi:10.20944/preprints201807.0210.v1

Cited by 5 publications

(4 citation statements)

References 45 publications

(59 reference statements)

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“…Hydrological models such as the hydrologic modeling system (HEC-HMS) [7,8], the Australian water balance model (AWBM) [9], the soil moisture accounting and routing (SMAR) model [10], the topography-based hydrological model (TOPMODEL) [11,12] and the soil and water assessment tool (SWAT) [13] are useful for simulating the runoff from ungauged catchment based on the data availability and complexity of the hydrological system. Many studies have demonstrated that SWAT is an effective and promising tool to use for simulating flows and sediments for large-scale watersheds and complex basins with different land uses and various soil types (Access et al [14], Brouziyne et al [15], Palani et al [16], Amatya et al [17], and Tri et al [18], among others).…”

Section: Introductionmentioning

confidence: 99%

The Temporal Variability of Rainfall and Streamflow into Lake Nakuru, Kenya, Assessed Using SWAT and Hydrometeorological Indices

Kimaru¹,

Gathenya

Cheruiyot

2019

Hydrology

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Temporal variability analysis of rainfall and river discharges is useful in determining the likelihood of the occurrence of extreme events such as drought or flooding for the purposes of developing policies to mitigate their effects. This study investigated the temporal variability of rainfall and discharges into Lake Nakuru, Kenya using meteorological drought indicators and hydrological drought indicators from 1981 to 2018. The standardized precipitation index (SPI) and standardized precipitation evaporation index (SPEI) were used to characterize meteorological drought, while the streamflow drought index (SDI) was used to characterize hydrological drought. A SWAT model was applied for the prediction of streamflow on five tributaries of Lake Nakuru (Njoro, Ngosur, Nderit, Larmudiac, and Makalia Rivers). The model was successfully calibrated on Njoro River at the upstream of river gauging station 2FCO5 from 1984 to 1996, and the parameters were validated from 1997 to 2007. The SUFI-2 algorithm was applied in SWATCup to perform the calibration of the model. The model performance was considered satisfactory in daily time step (NSE = 0.58, R2 = 0.58 during calibration and NSE = 0.52, R2 = 0.68 during validation). The average annual water balance revealed that out of 823 mm received annual precipitation, 154 mm was surface runoff and 178 mm was the annual average water yield. The average annual actual evapotranspiration (ET) was 607 mm. The results for the temporal variation of the SPI and SDI for the five subcatchments indicated that the drought events identified by the 12-month SPI/SPEI were almost all identified by the 12-month SDI. At the catchment scale, SPI showed an equal distribution of wet and dry periods, with 50.00% of positive anomalies and 50.00% of negative anomalies being observed from 1981 to 2018, while SDI observes a high frequency of dry periods (52.63%) and a lower frequency of wet periods (47.37%). There is a higher frequency of wet periods compared to dry periods for both indices from 2009 to 2010 at 60.00% and 40.00% for SPI and 90.00% and 10.00% for SDI, respectively. Both indices observed that 1984 and 2000 were severely dry years (SPI/SPEI < −2.00), while 2018 was severely wet (SPI/SPEI > 2.00). The results for the variability in rainfall and streamflow indices revealed that the last 10 years (2009–2018) were wetter than the period from 1981 to 2008.

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Section: Introductionmentioning

confidence: 99%

The Temporal Variability of Rainfall and Streamflow into Lake Nakuru, Kenya, Assessed Using SWAT and Hydrometeorological Indices

Kimaru¹,

Gathenya

Cheruiyot

2019

Hydrology

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“…During the Mesozoic, the central and eastern Andes Mountain ranges were elevated, resulting in the formation of the MMV basin. It consists of sedimentary strata from the Cretaceous Period over a Jurassic igneous metamorphic basement with an average thickness of 8500 m [50][51][52][53] . To the south, there are outcrops of the Real Group, a Neogene formation whose thickness varies from 450 to 3500 m. In the north, there are Quaternary deposits outcrops underlying Real Group.…”

Section: Hydrogeological Contextmentioning

confidence: 99%

Assessment of groundwater quality for human consumption and its health risks in the Middle Magdalena Valley, Colombia

Lora-Ariza,

Piña,

Donado

2024

Sci Rep

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Groundwater is the primary source of water for people living in rural areas, especially during seasons when surface water is contaminated or unavailable. In Colombia, people use groundwater as drinking water without additional treatment. In addition, there is no infrastructure for wastewater collection and sewage treatment in the region of the Middle Magdalena Valley. The current study aims to evaluate the quality of groundwater in this region to determine any potential health hazards associated with its consumption. To reach the objective, three (3) physicochemical and microbiological sampling campaigns were carried out during different hydrological periods. A total of 428 groundwater samples were analyzed for over 28 parameters. The results were compared with the water quality standards proposed by the US EPA and Colombian regulations for human consumption. The analysis revealed the presence of total and fecal coliforms in 89% and 58% of the analyzed samples, respectively, identifying them as the main contaminants in groundwater. Furthermore, the pH levels did not meet the standards set by the US EPA in 33.8% of the cases and by Colombian regulations in 31.02%. Additionally, 32.8%, 17.6%, 14.3%, and 10.9% of the samples failed to meet the established thresholds for apparent color, magnesium, iron, and nitrates, respectively, under both standards. Moreover, only the analyses of selenium, mercury, and zinc complied with the quality standards under both regulatory frameworks. Based on the Colombian Drinking-Water Quality Risk Index (CDWQRI-IRCA), the risk associated with water quality meant for human consumption was assessed. The results showed that over 84% of the samples analyzed posed a high risk to human health, 4.6% posed a medium risk, 5.5% posed a low risk, and only 5.7% posed no risk at all. Additionally, official mortality statistics for children under four years old were reviewed, which revealed two deaths in 2019 due to Acute Diarrheal Disease (ADD) caused by consumption of contaminated water. Therefore, it is crucial to implement water treatment systems, establish aqueducts in rural areas, and conduct rigorous and systematic monitoring of drinking water to ensure it is safe for human consumption. It is also important to track morbidity and mortality rates associated with water consumption.

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“…Dynamic‐TOPMODEL of Beven and Freer (2001) relaxed both of the above assumptions by allowing subsurface storage of individual HSUs to vary locally and independently of both the catchment average storage and TI, by incorporating a time‐dependent kinematic wave solution to the subsurface flow. However, since its introduction 20 years ago, and despite significantly improving catchment representation, the original steady‐state version has remained the preferred choice (albeit sometimes with modifications/improvements) (Arenas‐Bautista et al., 2018; Fu et al., 2018; Gil & Tobón, 2016; Jeziorska & Niedzielski, 2018; J. Wang et al., 2020; Lane & Milledge, 2013; Li et al., 2019; Mukae et al., 2018; Park et al., 2019; Rogelis et al., 2016; Xue et al., 2018; Zhang et al., 2016). Aside from the considerable additional complexity in numerical implementation of the dynamic versus the steady‐state version, the lack of momentum in transitioning is most likely due to the substantially slower runtimes, making the dynamic version much less attractive for calibration purposes.…”

Section: Introductionmentioning

confidence: 99%

A Generalized Multistep Dynamic (GMD) TOPMODEL

Goudarzi

Milledge

Holden

2023

Water Resources Research

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IntroductionTOPMODEL (Beven & Kirkby, 1979) continues to be one of the most widely applied hydrological models in both research and practice (Beven et al., 2021). It assumes that, independent of their specific spatial locations, some parts of the catchment will manifest similar tendencies to become, and remain, saturated during a storm. Based on a catchment-specific Topographic Index (TI) of similarity, these areas are grouped together to form Hydrologically Similar Units (HSUs), for which the numerical computations are performed when estimating a catchment's runoff response to rainfall. This grouping has enabled the dramatic reduction in runtimes associated with TOPMODEL, compared to fully spatially distributed models such as those of Freeze and Harlan (1969), Loague (2010), and Gao et al. (2015.Though fast, TOPMODEL is a lumped model in that only a single value of catchment average subsurface storage is updated in each timestep, from which individual HSU subsurface storage values are back-calculated according to the deviation of their TI value from the catchment average TI value (Beven, 2011, p. 211); hence, it can be construed as a quasi single-store (equally a pseudo multi-store) model. Implicit in such application of a time-invariant TI is the assumption (a) that the transients of water-table between HSUs across the catchment are fast enough, that in each timestep water table can be approximated by a steady-state configuration. At the same time the (quasi) single-store representation leads to assumption (b) that during rainfall there is always downslope flow at each and every point in the catchment, equal to the recharge rate from all of the upslope areas draining to that point (i.e., there is always downslope connectivity everywhere, all the way to the stream network) (Beven et al., 2021). Both assumptions (a) and (b) are clearly approximations.Dynamic-TOPMODEL of Beven and Freer (2001) relaxed both of the above assumptions by allowing subsurface storage of individual HSUs to vary locally and independently of both the catchment average storage and TI, by incorporating a time-dependent kinematic wave solution to the subsurface flow. However, since its introduction 20 years ago, and despite significantly improving catchment representation, the original steady-state version has remained the preferred choice (albeit sometimes with modifications/improvements) (

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Hydrological Modeling in Tropical Regions via TopModel. Study Case: Central Sector of the Middle Magdalena Valley - Colombia

Cited by 5 publications

References 45 publications

The Temporal Variability of Rainfall and Streamflow into Lake Nakuru, Kenya, Assessed Using SWAT and Hydrometeorological Indices

The Temporal Variability of Rainfall and Streamflow into Lake Nakuru, Kenya, Assessed Using SWAT and Hydrometeorological Indices

Assessment of groundwater quality for human consumption and its health risks in the Middle Magdalena Valley, Colombia

A Generalized Multistep Dynamic (GMD) TOPMODEL

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