1. Introduction

The sustainable management of river and lake basins requires mitigating the vulnerability of the eco-hydrological systems against environmental stressors. This is widely considered a crucial priority by organizations such as the United Nations, national and international water resources bureaus, and research institutions. The challenge is augmented by the growth in population, leading to rapid and extensive changes in land use under severe climate variability [1]. These two phenomena are more complicated and severe in arid and semi-arid regions, especially in developing countries. Due to its location, the African Sahel is most vulnerable to simultaneous changes in land use/land cover (LULC) and climate. In addition to the considerable changes in LULC, the arid and semi-arid climate in the Sahel is characterized by scarce rainfall as well as high temperature. These conditions have a large impact on the environment in general and particularly on the surface water resources [2]. The United Nations articulated the Sustainable Development Goals (SDGs) to identify shared priorities towards a better future for all. Specifically, SDG 6 addresses water security through a detailed hierarchy of Tasks and Targets. A better understanding of the impacts of LULC and climate variability is needed to develop effective paths towards sustainable water security regarding both quantity and quality [3,4].

To reveal the hydrological processes that occur in a changing environment, distributed hydrological models such as the Soil and Water Assessment Tool (SWAT) [5] are most useful to assess the impacts of land/water management and climate variability on water quantity and quality. The SWAT model has been applied to understand the hydrological system and explain the impacts of land and water resource management scenarios [6,7]. Such studies based on different climate and land-use scenarios require accurate model calibration and validation which are usually performed using a traditional method based on the ground observed data, e.g., discharge. However, in many regions, such data are very rare or totally absent in some cases for different reasons (e.g., in some basins in Africa); novel calibration and validation procedures are therefore needed.

In Africa, several studies have been conducted by applying the SWAT model in different basins [8,9,10,11,12,13]; the main limitation of these studies was the spatiotemporal coverage of data used for calibration and validation. These previous studies on SWAT applications in Africa documented some variability in model performance, although all aimed at improving model performance in data-scarce catchments. The Lake Chad Basin was selected as a study area because it is considered an ideal study case in terms of ground observation data scarcity.

Due to the scarcity of ground observed data used for calibration and validation, many studies found that retrievals of hydrological variables from remote sensing data may help to improve model performance. Multiple remote sensing actual evapotranspiration (ETa) products have recently become available with extended temporal coverage [14,15,16,17]. These data have proven useful to calibrate and validate hydrological models, especially in data-scarce basins [18]. Recently, Ha et al. (2018) [19] used three years of remote sensing ETa in monthly time steps to calibrate the SWAT model for a tributary of the Red River in Vietnam. The performance of the calibration showed high-performance metrics. Poméon et al. (2018) [20] applied the SWAT model in the Niger, Volta, and Senegal River Basins; they used the traditional calibration method based on observed discharge data for calibration, and they validated the model using time series of remote sensing data in monthly time steps. They used actual evapotranspiration, soil moisture, and total water storage derived from remote sensing data to evaluate model performance after calibration. The multi-objective validation using remote sensing evapotranspiration, total water storage change, and soil moisture revealed good agreement between model estimates and observations. Odusanya et al. [21] applied the SWAT model in the Ogun catchment in Southwestern Nigeria. The SWAT ETa estimates using the Hargreaves equation performed well against the GLEAM ETa data. These studies have used several years of satellite-based data to calibrate and validate the SWAT model. They concluded that the remote sensing data could be potentially used for SWAT calibration and validation. The weak point of these studies is that they did not well emphasize the benefit of the geospatial distribution of remote sensing retrievals, which could resolve the problem of the lack of ground observation time series, e.g., discharge.

This study aims to provide a novel calibration approach of the SWAT model based on limited time series of earth observation data in the data-scarce Lake Chad Basin. This study has two objectives: (1) to evaluate the performance of the SWAT model after a limited calibration period (one year) using multiple satellite remote sensing ETa products, which would be the novelty of this study; and (2) to validate the model using remote sensing ETa, total water storage, and soil moisture in a distributed manner in the whole Lake Chad Basin.

2. Study Area and Data

2.1. Study Area

The Lake Chad Basin (LCB), located in the center of the African Sahel between 5.19° N–25.29° N latitude and 6.85° E–24.45° E longitude (Figure 1), is one of the most important catchments in the Sahel due to the dramatic decrease of water level and extent during the last decades.

The Lake Chad Basin is the largest endorheic basin in the world, with an initial area of 2,500,000 km² (about 8% of Africa) [22,23,24]. The Lake Chad Basin is shared by 10 African countries, i.e., Algeria, Cameroon, Central African Republic, Chad, Libya, Niger, Nigeria, and Sudan. In terms of location, 44% of the lake area is in Chad, and 29% is in Niger. The mean annual precipitation in the Lake Chad Basin is about 415 mm, varying from 1215–1600 mm in the south-western parts of the basin (Central African Republic) to 20–150 mm in the northern region such as Algeria [25,26]. In 1964, the Lake Chad Basin area was reduced to about 20% (427,000 km²) of the initial area [27,28]. In the same year, 1964, the Lake Chad Basin Commission (LCBC) was founded, representing four countries, i.e., Nigeria, Cameroon, Niger, and Chad. According to Policelli et al. [29], the water area continued to decrease till it reached an annual peak area estimated at 14,700 km² in 2017. After the dramatic decrease, Lake Chad became divided into a dry and hydrologically disconnected northern part and a southern part that is active [30]. The northern part of the catchment belongs to the Sahara desert and does not generate runoff that reaches Lake Chad [31]; thus, we focused on the southern part of the Lake Chad Basin (Figure 1).

2.2. Data

We have used two types of data in this study: (a) the configuration and climate forcing data to run the SWAT model; and (b) remote sensing data used to calibrate and validate the model. In this study, the datasets were used from 2009 to 2015. These datasets were resampled to 250 m spatial resolution using ArcGIS resample tool to be aligned with LULC data, except for the remote sensing actual evapotranspiration products, which were used in their original resolutions. A detailed description of the data used in this study is given in the following sections. The forcing data are described in Section 2.2.1 (Table 1), while the data used for calibration and validation of the SWAT model are described in Section 2.2.2 (Table 2) and Section 2.2.4 (Table 3), respectively.

2.2.1. Forcing Data

Atmospheric Forcing Data

Minimum and maximum daily temperature, wind speed, solar radiation, and relative humidity at 2 m height were the fifth generation of the European Centre for Medium-Range Weather Forecasts (ECMWF ERA5) reanalysis. These data are the improvement of ECMWF reanalysis first generation [32]. The variables were used in the daily time step as required by the SWAT model.

Precipitation

Climate Hazards Group Infrared Precipitation with Station data (CHIRPS) were used in this study. The data were generated from 1981 to the present [] in daily, monthly, and yearly time steps. Compared to other precipitation products, its main characteristic is a fine spatial resolution of 5 km [33]. CHIRPS uses several data sources, such as the monthly precipitation climatology from the climate hazard center’s precipitation climatology (CHPclim), infrared measurements from geostationary satellites, and information from the TRMM Multi-satellite Precipitation Analysis (TMPA) 3B42 product. The precipitation estimates are merged with in situ gauge data from several archives, including the sparse World Meteorological Organization’s Global Telecommunication System (GTS), to reduce biases [34]. In this study, the precipitation data were used in the daily time step.

2.2.2. Remote Sensing ETa Data

Due to the scarcity of ground observations in the Lake Chad Basin, particularly of river discharge in the study area, four ETa products derived from remote sensing observations were used to calibrate the SWAT model. These four ET datasets include the global ET products from ETMonitor, the Simplified Surface Energy Balance for operational application (SSEBop_v4, version 4), the FAO WAter Productivity through Open access of Remotely sensed derived data (WaPOR_1.1, version 1.1, covers only Africa), and the Global Land Evaporation Amsterdam Model (GLEAM_3.3a, version 3.3a) (Table 2). The details of the four ETa datasets are described in Text A1. The selection of these ETa products was based on free availability, spatiotemporal coverage, and resolution. GLEAM and WaPOR have been validated in several countries in Africa; SSEBop and ETMonitor have been validated globally using data from ground observation sites.

2.2.3. Soil Moisture

The soil moisture product used in this study is version 5.2 of the European Space Agency Climate Change Initiative combined soil moisture data product (ESA CCI SM v5.2), which was generated by combining various available passive and active microwave-based soil moisture datasets and released in 2019 [39,40,41]. It was generated by blending active and passive microwave soil moisture retrievals from the data acquired by C-band scatterometers and multi-frequency radiometer data. The data are available at a daily temporal resolution from 1978 to 2019 and a spatial resolution of 0.25° and represent only the topsoil layer (0–5 cm).

2.2.4. Total Water Storage Change

The Gravity Recovery and Climate Experiment (GRACE) mission comprises two twin satellites following each other, 220 km apart. It was launched by the National Aeronautics and Space Administration (NASA) and Deutsches Zentrum für Luft- und Raumfahrt (DLR) to determine the global Earth gravity field every 30 days [42]. The time-dependent distance between these two twin satellites is converted to a local Earth gravity field. Retrievals at different times can be applied to compute the mass changes in units of equivalent water height [43]. Different “GRACE solutions,” i.e., retrievals of local gravity, have been reported; for more information about GRACE, see, for example, the study by [44]. The GRACE product used in this study is the global “mascons” solution [45]. The data were downloaded from: (http://www2.csr.utexas.edu/grace; accessed on 13 January 2021). The GRACE provides the total water storage anomaly in the monthly time step (TWSA), which corresponds to the sum of all water mass variations at the continent’s surface and in the soil [46]. Monthly data from GRACE in the study period (2009–2015) yield a total of 84 months with gaps of 15 months (i.e., about 18% of the total data). The GRACE has a spatial resolution of 300 km; in this study, it was resampled to 1 km spatial resolution using the bilinear interpolation method without filling the gaps of missing months (15 months). The same missed months data in GRACE were not considered in the TWSC from the SWAT model in the comparison of the two datasets.

The monthly total water storage change (TWSC) was calculated as the difference between the values estimated in two subsequent months [47]:

(1)$TWS{C}_t=\frac{TWS{A}_t-TWS{A}_{t-1}}{\Delta t}$

2.2.5. Auxiliary Data

The annual land use and land cover dataset (LULC) used in this study was produced by Tsinghua University based on MODerate-resolution Imaging Spectroradiometer (MODIS) data at a spatial resolution of 250 m. More details about the dataset can be found in [32]. The LULC dataset is available from 2000 to 2015. The LULC dataset was used at its original spatial resolution of 250 m, and the other datasets were resampled to this spatial resolution to be used in the SWAT model.

The soil data used in this study were obtained from the Digital Soil Map of the World (DSMW) version 3.6 produced by the Food and Agriculture Organization (FAO) at 1 km resolution. The physical properties were extracted for each soil texture class from the Map Window (MW) interface of the SWAT database (http://swat.tamu.edu/software/mwswat/; accessed on 21 October 2020), which is compiled from FAO world soil data. The MWSWAT interface was developed by the WaterBase project (http://www.waterbase.org; accessed on 21 October 2020) of the United Nations University [48].

The Digital Elevation Model (DEM) of LCB was clipped out of the Shuttle Radar Topography Mission (SRTM) 30 m resolution Digital Elevation Data (www.earthexplorer.usgs.gov; accessed on 6 December 2020).

3. Methodology

The conceptual framework of this study is given in Figure 2. The overall approach used in this study is based on the hydrological SWAT model, which was run to estimate water balance components at each Hydrological Response Unit (HRU) to be aggregated to each of the 37 delineated sub-basins. Actual evapotranspiration (ETa), as a major component of water balance and terrestrial water cycle, is defined as the quantity of water that is actually removed from the land surface by the processes of evaporation (soil or water) and transpiration (vegetation). In this study, the ETa of the HRUs calculated by SWAT was combined with the spatially distributed ETa based on satellite remote sensing observations to calibrate the SWAT model parameters. Four satellite-observation-based ETa data products were evaluated, and the one with the best performance was used for further analysis. The SWAT model calculates the ETa using the potential evapotranspiration (ETp), defined as the measure of the ability of the atmosphere to remove water from the land surface through both evaporation and transpiration. In this study, three available ETp equations (Hargreaves, Priestley–Taylor, and Penman–Monteith) were used to configure the SWAT model to estimate the ETa (Figure 2a). In contrast to previous traditional calibration methods, a new calibration approach based on a limited record length of calibration data (i.e., monthly data for one year), but having rich spatial information from the spatially distributed remote sensing ETa data, was applied using the SUFI-2 algorithm in the SWAT-CUP tool-kit for each sub-basin. To accomplish these steps, four satellite-based ETa datasets were tested to evaluate the performance of the new calibration approach (Figure 2b). For validation, the results from the calibrated SWAT were assessed by comparing with the satellite-based observations of surface layer soil moisture and terrestrial water storage change (Figure 2c).

3.1. Model Description

The eco-hydrological model Soil and Water Assessment Tool (SWAT) is an open-source, process-based, and semi-distributed model [5]. The model uses daily meteorological data, i.e., precipitation, wind speed, air temperature, relative humidity, and solar radiation, in addition to topography, soil data, and LULC, to simulate different water balance components in a watershed. The model can also describe the water quality and soil erosion in the basin. SWAT model describes watershed hydrology in two stages: (a) sediments, nutrients, and water flow into the main channel of each sub-basin; and (b) transport of sediments, nutrients, and water through the network of channels to the outlet of the main watershed. The catchment water balance calculation in SWAT is based on the principle of conservation of mass as follows:

(2)$SW{C}_t=SW{C}_0+{\displaystyle \sum }_{i=1}^t\left(R_{\mathrm{day}}-Q_{\mathrm{surf}}-E{T}_{\mathrm{a}}-W_{\mathrm{sep}}-Q_{\mathrm{gw}}\right)$

The soil dataset used in this study was the Digital Soil Map of the World (DSMW), which provides physical characteristics of the soil profile split into two layers: 0−300 mm and 300–1000 mm. SWAT model calculates the soil moisture (SWAT SM) as plant-available water (PAW) [46], specifically as the mean values for the soil layers at 0−10 mm as part of the first layer (septic layer), 0−300 mm, and 300−700 mm. The PAW is calculated as:

(3)$PA{W}_{ly}=SW{C}_{ly}-W{P}_{ly}$

(4)$SW{C}_{ly}=PA{W}_{ly}+W{P}_{ly}$

The permanent wilting point (WP) is the amount of water held in the soil at a tension of 1.5 MPa. The WP in each soil layer was estimated from soil texture [46] using the clay fraction and the mean bulk density in each HRU as:

(5)$W{P}_{ly}=0.4\times B{d}_{ly}\times f_{clay,ly}$

Since the soil dataset used in this study does not have a 50 mm soil layer, this SWAT model could not compute the soil moisture at 50 mm to be compared to ESA CCI SSM (50 mm). In this part, the conversion of the SWAT SM at the soil layer 0–300 mm into volumetric soil moisture was performed by dividing it by the depth of 300 mm and adding the soil water at the wilting point of the same soil layer (0–300 mm), then multiplying by 50 mm to obtain the soil moisture at 50 mm as shown in the following equation:

(6)$S{M}_{50\mathrm{mm}}=\left(\raisebox{1ex}{$PA{W}_{300\mathrm{mm}}$}\!\left/ \!\raisebox{-1ex}{$300$}\right.\right)\times 50+W{P}_{300\mathrm{mm}}\times 50$

The values of $S{M}_{50\mathrm{mm}}$ obtained soil moisture were compared with the ESA CCI SSM multiplied by 50 mm.

The SWAT model does not directly calculate the TWSC as output. However, it simulates the shallow aquifer and the deep aquifer in the function of recharge and percolation as described in [49,50]. The groundwater (shallow and aquifer storages) is given by the SWAT model as outputs in “output.hru” file. So, the TWSC was estimated as the sum of the soil water content (SWC), deep aquifer (DA), and shallow aquifer (SA). Then, the deviation of monthly TWSC was estimated according to Poméon et al. [20] as:

(7)$\mathsf{\Delta }TW{S}_t=\left(SW{C}_t+D{A}_t+S{A}_t\right)-\overline{\left(SW{C}_t+D{A}_t+S{A}_t\right)}$

3.2. Model Setup

In this study, the model was run in each Hydrological Response Unit (HRU) with a monthly time step for each year of land use/land cover data separately (2009–2015), and then the results from the HRUs were integrated to monthly and annual values for each sub-basin for further analysis. In the SWAT model, each HRU is defined as a combination of an LULC class, soil type, and slope class for each sub-basin separately [51]. The Lake Chad Basin was partitioned into 37 sub-basins using the topography data (SRTM-DEM). In this study, eight LULC classes were considered: forest (FRST), agriculture (AGRR), bare land (BARR), shrubland (RNGB), grassland (RNGE), urban (URBN), water (WATR), and wetland (WETN). Within the model domain there are seven soil types, i.e., loam, loamy-sand, sand, sandy-loam, sandy-clay-loam, clay, and clay-loam, and five slope classes, i.e., (1) 0–8% (flat); (2) 8–15% as gently sloping; (3) 15–20% as moderately steep; (4) 20–45% as steep; (5) >45% as very steep. This yields 8 × 7 × 5 = 280 possible combinations. The thresholds reduce the number of combinations, to which threshold rules (given in the next paragraph) are applied to define and delineate (using the maps of attributes) the HRUs.

The thresholds, i.e., fraction of area of specific LULC class in each sub-basin (F_{_LULC}), the fraction of area of specific soil type in that LULC class area (F_{LULC_soil}), and the fraction of specific slope class in the area of that land cover type and that soil type (F_{LULC_soil_slope}), are employed to select the LULC classes, soil types, and slope classes that need to be taken into account in a given sub-basin. We carried out the experiments by comparing the SWAT model results from using different combinations of thresholds (i.e., F_{_LULC}, F_{LULC_soil}, F_{LULC_soil_slope}) with the results from the standard delineation of HRU, which is carried out using zero-thresholds (i.e., F_{_LULC}, F_{LULC_soil}, and F_{LULC_soil_slope} were all >0% sequentially). The experiment results showed that the best agreement was obtained by using the thresholds of LULC class, soil type, and slope class of 5%, 20%, and 20%, respectively, which were used in this study to run SWAT. Those LULC classes, soil types, and slope classes that were below the thresholds would be reapportioned into the other qualified land covers, soil types, and slope classes, respectively. If no one HRU in a sub-basin can be defined by the thresholds (meaning all are below the defined thresholds), the model selects the combination that has the largest fraction of areas of land cover, soil type, and slope class, respectively, as a single HRU. A similar procedure could be found in other studies, though they have used different values of the thresholds for their study cases [52,53].

In this study, we used annual land use data, i.e., the land use changed for each year from 2009 to 2015. This change in land use led to the change in the number of HRUs for each year, as shown in Table 4.

After the delineation of the HRUs, the weather data (precipitation, temperature, wind speed, relative humidity, and solar radiation) were averaged for each HRU in the Lake Chad Basin catchment.

The SWAT-simulated ETa was used for the calibration of model parameters as described in Section 3.3. Literature and our own experiments showed that the SWAT estimates of ETa are highly sensitive to the choice of the equation applied to estimate ETp. We could not select one equation among the three equations provided in the SWAT a priori; therefore, we designed the calibration experiments to shed light on model performance in the estimation of ETa. Our numerical experiments on SWAT calibration and validation showed that the best performance was achieved by using the ETMonitor ETa combined with SWAT ETa calculated based on Hargreaves equation for ETp; the results from this combination will be used for further analysis.

3.3. Calibration Procedure

The calibration of the SWAT model was performed using the semi-automated multi-site and inverse modeling algorithm SUFI-2 in the SWAT-CUP tool-kit [54,55]. The parameters to be calibrated were initially preselected (about 40 parameters) on the basis of literature [11,18,19,21,55,56,57,58]. Furthermore, a global sensitivity analysis was carried out to identify the parameters most influential on ETa by applying the multiple regression method following the study by Abbaspour et al. (2015) [54]. An iteration included 1000 simulations for all HRUs, and the parameters were ranked on the basis of the p- and the t-test values. The latter provide information about the influence of the parameter on ETa, with a larger absolute value indicating more influence on ETa, while the former indicates the significance of the influence, i.e., a value close to zero indicates highly significant influence. Based on the global sensitivity analysis, 15 parameters were selected to be determined by calibration with SUFI-2 (Figure 2b).

The traditional approach to calibrating hydrological models such as SWAT relies on discharge measurements at hydrometric stations. This requires multiple stations distributed in a river basin and a long time series of discharge data, in which the calibration period generally is longer than the validation period. In our study, we used raster-based spatially distributed retrievals of hydrological variables from multiple remote sensing observations. The spatial coverage of such data, which provided rich information in space, made it possible to limit the temporal coverage of the calibration experiments to one year at a monthly time step. Specifically, the calibration was performed using satellite retrievals of actual evapotranspiration (ETa), i.e., ETMonitor, GLEAM, SSEBop, and WaPOR. Monthly observations for each of the 37 delineated sub-basins in the watershed were applied for each yearly calibration or validation, adding up to 444 data points to estimate the 15 selected parameters.

The parameter values are assigned to each HRU, and two types of parameters are considered: (1) heterogeneous, i.e., specific for each soil type, slope range, or LULC class, which have a different value in each HRU; (2) homogeneous, i.e., constant in the entire watershed. SWAT-CUP allows three types of updates on the selected model parameters through the iterations: (a) by a multiplicative factor “$\left(1+\alpha \right)$”; (b) by adding a constant “$\beta$”; and (c) assigning a parameter a new value “$\gamma$”. The default parameter value is replaced with a new candidate value in each iteration by:

(8)$P_{new}=P\times \left(1+\alpha \right)$

(9)$P_{new}=P+\beta$

(10)$P_{new}=\gamma$

A full SWAT run is carried out, and new monthly values of ETa are obtained and compared with ETa from satellite-based observations. The accuracy of the SWAT model estimate of ETa is evaluated using the Nash–Sutcliffe efficiency (NSE) [59,60]. The calibration is carried out by evaluating the candidate correction values iteratively for the selected parameters to maximize the NSE value. The performance is considered satisfactory when the objective function reaches a certain threshold, e.g., NSE = 0.5, and the iterations are terminated. The values of the parameter corrections in the last iteration are the final result of a calibration experiment.

Using four remote sensing ETa data products, i.e., ETMonitor, GLEAM, SSEBop, and WaPOR, and three SWAT ETa, i.e., based on ETp calculated with the Hargreaves, Penman–Monteith, and Priestley–Taylor equations, this added up to 12 calibration projects: the three ETp equations; Hargreaves (HG), Penman–Monteith (PM), and Priestley–Taylor (PT) with the four ETa products; ETMonitor (ETM), GLEAM (GLM), SSEBop (SEB), and WaPOR (WaP) were named HG_ETM, PM_ETM, PT_ETM, HG_GLM, PM_GLM, PT_GLM, HG_SEB PM_SEB, PT_SEB, HG_WaP, PM_WaP, and PT_WaP.

3.4. Evaluation of Calibration, Validation, and Uncertainty Analysis

The uncertainty in the input data, the observed variable used for calibration, and calibration parameters lead to uncertainty in the output results [61]. The analysis of the uncertainties of the outputs caused by the propagation of the uncertainty of the parameters used for calibration was performed using SUFI-2. These uncertainties are expressed as 95% probability distributions (95PPU). In this stage, the SUFI-2 depicts the 95PPU of the model estimates compared with the ETa retrievals. The 95PPU was computed at the 2.5% and 97.5% levels of the cumulative distribution of the model ETa generated by the propagation of the uncertainties using Latin Hypercube Sampling. The uncertainties were evaluated based on two factors: the P factor and the R factor [62,63]. The P-factor is the fraction of observations enveloped by the model estimates (95PPU) and varies from 0 to 1, where 1 indicates 100% bracketing of the observations within model simulations. The R-factor is the thickness of the 95PPU envelope, with values ranging between zero and infinity. The ideal situation is when the P factor is g close to 1, and the R factor is close to 0.

The metrics of model performance are recommended by Moriasi et al. [59,60], i.e., NSE, PBIAS, and R² are usually applied to calibration and validation of model estimates of monthly sediment and nutrient transport and runoff. In this study, the calibration was performed using satellite retrievals of actual evapotranspiration. We applied the evaluation methods that were well documented in the literature [18,19,21,64,65], where calibration and validation of hydrological models were carried out by applying the NSE, PBIAS, and R² metrics according to Moriasi et al. [59,60].

In this study, the simulation period (2009–2015) was split into one year for calibration (2009) and six years for validation (2010–2015). The calibration experiments have been described in Section 3.2 on model setup and Section 3.3. Then, according to the user manual of SWAT-CUP [61], the number of simulations in each iteration is recommended to be 500, but if the calibration is too slow, it could be even less (200–300). SWAT-CUP has been run for five iterations, each one comprising 500 simulations. The validation was performed by running the SWAT model using the calibrated values of the 15 model parameters. Likewise, the calibration and the validation were performed by comparing the model ETa with each one of the four remote sensing ETa datasets for the period (2010–2015).

We applied four performance metrics: the R squared coefficient (R²), the Nash–Sutcliffe Efficiency (NSE), Kling–Gupta Efficiency (KGE), and the percent bias (PBIAS) to evaluate the SWAT calibration and the validation, as performed by Odusanya et al. [21]. The R² is a metric of the strength of the relationship between the data and the fitted regression line. The range of R² is from 0 to 1, where the value close to 1 means less error variance.

The NSE is used to compare the relative magnitudes of the residual (“noise”) and the variance of the observations [62]. NSE varies from −∞ to 1, where NSE > 0.5 means a good agreement [59,60] between model estimates and observations. NSE close to 1 is the optimal value.

The KGE goodness-of-fit metric was developed by [66], and it measures the relative importance of different metrics, i.e., correlation, bias, and variability, in hydrologic simulations. The range of KGE is from −∞ to 1, with KGE = 1 being the optimal value.

The PBIAS is the relative bias, which indicates whether the model data are larger or smaller than the observations. The ideal value is zero, i.e., a value closer to zero indicates better model accuracy. A negative value indicates that the model overestimates observations, and vice versa if the value is positive [67]. The performance metrics equations are all described in Table 6.

4. Results

The SWAT-CUP was run for five iterations comprising 500 simulations each. The values of the fifteen corrections estimated in each calibration experiment are given in Table A1.

4.1. Sensitivity Study

To explain the effectiveness of the ETa vs. discharge-based calibration, we have determined the sensitivity of the selected parameters to the simulated ETa and discharge. SWAT was run using the initial range of 15 selected parameters described in Table 5 for 1000 simulations. To determine the sensitivity of the parameters to the simulated ETa and discharge, the variation of the parameter values during the simulations was used. Two linear regression projects were implemented. The first was to evaluate the 15 parameters’ sensitivity to simulated ETa, while the second was to determine the sensitivity of the same 15 parameters to simulated discharge. The results are shown in Table 7. The higher the absolute value of the t-stat, the higher the parameter sensitivity, provided the p-value is lower than 5%. The t-stat values of the parameters for ETa are much higher than the t-stat values for discharge (e.g., CN2 t-stat = −26.91 for ETa while it is 2.93 for discharge). Moreover, the number of parameters that have very high sensitivity to ETa (p-value <<< 0.05) is higher than those that have high sensitivity to discharge (eight parameters vs. three parameters).

The configuration using the Hargreaves ETp (Figure 3) achieved the best performance compared to other configuration ETp equations (Figure A1), so only these results are presented in detail (Table 8). The P-factor varied between 0.2 and 0.3, with the highest achieved with the GLEAM retrievals. Note that p = 0.29 means that 29% of the model estimates were within the 95% PPU. The lowest p = 0.21 was obtained with SSEBop, while ETMonitor gave p = 0.27. The R-factor varied between 0.07 and 0.29, where the lowest was achieved with the ETMonitor ETa and the highest with WaPOR. The ETMonitor and the GLEAM ETa data gave the best performance, i.e., the highest P-factor values and the lowest R-factor values (Table 8). The validation experiments gave higher P-factor and r-factor values than the calibration with all the ETa retrievals (Table 9). The P-factor varied between 0.25 (WaPOR) and 0.65 (GLEAM). The R-factor varied between 0.16 (ETMonitor) and 0.96 (WaPOR). The highest P-factor and the lowest R-factor were achieved with the GLEAM and ETMonitor data.

4.2. Calibration Results

The performance achieved in the calibration and validation was further evaluated by considering the R², NSE, KGE, and PBIAS metrics (Table 8 and Table 9). The ETMonitor ETa gave the best performance with R² = 0.91, NSE = 0.83, and KGE = 0.79, indicating very good performance. The second-best performance (Table 8) was achieved with the GLEAM ETa data, i.e., R² = 0.88, NSE = 0.8, and KGE = 0.78. The PBIAS was lowest with the ETMonitor and GLEAM, i.e., less than ±5% (2.33 and −4.18, respectively), while the highest values were obtained with the SSEBop and WaPOR ETa, i.e., 7.59 and 30.44, respectively. SWAT underestimated ETa by 2.33% compared to ETMonitor, by 7.59% vs. SSEBop, 30.44% vs. WaPOR, while it overestimated ETa by 4.18% compared to GLEAM data. Each scatter plot in Figure 4 shows the 12 monthly values of the SWAT estimates of ETa (based on Hargreaves ETp equation which returned the highest performance) against the ETMonitor retrievals of ETa (which also yielded the highest performance compared to other ETa of remote sensing products) for a given sub-basin.

The high performance of SWAT ETa estimates against the ETMonitor retrievals was confirmed by the comparison disaggregated across the 37 sub-basins, and it gave a slope positive and mostly equal to 1 in different sub-basins (Figure 4).

The calibration was performed in the monthly time step for one year (12 months) of 2009 for each of the 37 sub-basins; Figure 3 and Table 8 show the metrics performance in which the ETa from SWAT was based on Hargreaves ETp. In Figure 3, the spatial distribution of the performance metrics of SWAT configured using Hargreaves ETp against the four remote sensing ETa products (ETMonitor (a), GLEAM (b), WaPOR (c), and SSEBop (d)) within the Lake Chad watershed provides further insights on the sensitivity of model performance to parameter setting. There is clearly an advantage in performance of the ETMonitor and the GLEAM compared to the WaPOR and the SSEBop. The spatial distribution metrics maps of the SWAT ETa calculated based on the other two ETp equations (Penman–Monteith and Priestley–Taylor) against the four remote sensing ETa are shown in Figure A1.

4.3. Validation Results

Likewise, the performance metrics were calculated for each year of the validation period (Table 9 and Figure 5). The model validation experiments gave higher R² values than calibration with the ETMonitor data (Table 9), i.e., R² = 0.94 on average across sub-basins. Good agreement with slightly lower values of R² was also achieved with the GLEAM data, i.e., mean R² = 0.88 varying between 0.85 and 0.92 across sub-catchments. Performance was lower against the WaPOR and the SSEBop data with mean R² = 0.67 and 0.62, respectively. The NSE metric provided similar indications, i.e., higher values were obtained against ETMonitor in the validation experiments, with NSE = 0.86, compared to calibration (see above). A lower NSE = 0.79 was obtained with the GLEAM data, while NSE was negative with the WaPOR and SSEBop data. Likewise, with ETMonitor ETa, the mean KGE = 0.79, i.e., the same value as in the calibration experiments, while KGE = 0.76 with GLEAM and KGE = 0.2 with WaPOR, lower than in the calibration experiments in both cases. The validation using SSEBop gave a higher value than the corresponding calibration experiment (0.56). PBIAS values shown for validation using both ETMonitor and GLEAM datasets indicated promising values (<10%). In general, the SSEBop and WaPOR products gave high PBIAS values greater than ±15%.

Overall, the performance achieved in the SWAT calibration and validation was rather high and consistent when using the ETMonitor and GLEAM data. The highest performance, with R², NSE, PBIAS, and KGE values, respectively, 0.94, 0.86, 0.43, and 0.79, was achieved with the ETMonitor data, while the corresponding metric values with the GLEAM data were 0.88, 0.79, −2.35, and 0.76, respectively, indicating slightly worse performance. The performance with SSEBop and WaPOR was much worse, with very low metrics values.

Taking into account the overall performance achieved in the calibration (Table 8 and Figure 3) and validation (Table 9), the results of SWAT configured using Hargreaves validation against ETMonitor for the year 2010 to 2015 are shown in Figure 5 for both calibration (Figure 3a) and validation (Figure 5a–f); R² was higher than 0.7 for all the sub-basins within the study area in the Lake Chad Basin, and more than 80% of the 37 sub-basins gave NSE and KGE between 0.7 and 1. This shows very good performance of SWAT estimates of ETa, with ETp computed with the Hargreaves equation against ETa from ETMonitor.

The comparison of calibrated and uncalibrated SWAT ETa (Figure 6) confirms these findings. SWAT ETa prior to calibration was in good agreement with the ETMonitor ETa during the transitions from the dry to wet season and vice versa. In the first few months of the year, the SWAT uncalibrated ETa curve (red color) shows the second peak in ETa in the early season of every year (Figure 6), which was successfully corrected after model calibration. SWAT underestimated maximum ETa in summer without calibration, while the SWAT ETa was much closer to ETa retrievals after calibration. Overall, the calibration gave R² > 0.9 and NSE > values higher than 0.8 every year.

4.3.1. Validation of SWAT Soil Moisture

During the dry months, there was good agreement between SWAT SWC and the ESA CCI SSM (Figure 7a,c). Larger differences were observed during the wet months (June to September) (Figure 7b,d), which is also the growing season, probably due to the potential SWAT model deficiency in the ETa parameterization [68].

The time series of SWAT SWC and ESA CCI SSM in the top 50 mm soil layer gave better agreement throughout the entire period 2009–2015 (Figure 8a). Contrary to the top 10 mm soil layer (Figure 7), the maximum SWAT SWC during the wet months was consistently higher than the ESA CCI SSM. This suggests that model estimates and the surface soil moisture data product capture, in a different manner, the vertical redistribution of rainwater. The R², NSE, and KGE were all higher than 0.85 (Figure 8b).

4.3.2. Validation of SWAT Estimates of Changes in Total Water Storage

Overall, the SWAT estimates appear to capture the seasonality correctly in TWSC: the total water storage change estimated by the SWAT (SWAT TWSC) model was in good agreement with the GRACE retrievals, although the differences in the wet months were at times large and not systematic (Figure 9). The monthly GRACE TWSC data showed rather large and rapid fluctuations in the dry period, leading to large and variable differences with the SWAT TWSC estimates. The performance metrics were satisfactory, but not very high, i.e., R² = 0.56 and NSE = 0.55 (Figure 9b).

The resampling of the GRACE data to 1 km did not affect the signal. Both at 1 km (Figure 9(a1,b1)) and 300 km (Figure 9(a2,b2)), the GRACE data provide a comparable signal, as shown in Figure 9, particularly the comparable regression coefficient in Figure 9(a1,a2). The resampling was performed to apply the same spatial sampling as the ETMonitor ETa, which was used for calibration (1 km sampling grid—size). In addition, according to [69], it is possible to capture a meaningful signal from GRACE data for catchments larger than 200,000 km². In this study, the area of the catchment is approximately equal to 10⁶ km², i.e., >200,000 km². The results at 1 km and 300 km resolution (Figure 9) are almost the same with (R² = 0.57).

4.4. Water Balance

In fact, the calibration had clear impacts on different water balance components, besides ETa, which were used to calibrate the model (Figure 10). Generally, all the water balance components showed an increase compared to the first year of simulation (2009). The lowest value was shown in 2009, and the maximum value occurred in 2012. The mean annual values of actual evapotranspiration (ETa), soil water (SW), perception (PERC), surface runoff (SURQ), groundwater recharge (GW_Q), water yield (WYLD), and lateral runoff (LAT_Q) are 533.88 mm/year, 7.15 mm/year, 62.15 mm/year, 51.9 mm/year, 43.15 mm/year, 98.01 mm/year, and 0.59 mm/year, respectively.

5. Discussion

Both the calibration and validation with the ETMonitor and GLEAM ETa retrievals showed very good performance when the model was configured using the Hargreaves ETp equation to simulate ETa. The SSEBop and WaPOR ETa data gave the lowest calibration and validation performance with different ETp equations used to estimate ETa.

According to Moriasi et al. [59,60] and Kouchi et al. [70], good model performance is indicated by the PBIAS values (PBIAS ≤ ±15) for the calibration and validation of the SWAT model with monthly remote sensing ETa from ETMonitor and GLEAM (Table 8 and Table 9). These positive values of PBIAS showed that the SWAT model underestimated monthly ETa in the LCB. On the other hand, negative values of PBIAS indicate that SWAT overestimated the ETa. This difference between different RS ETa products and SWAT ETa estimates is mainly due to the difference in forcing data and to the algorithm used to estimate the ETa. The PBIAS values achieved in the calibration and validation using ETMonitor and GLEAM < 15% were lower than values in Odusanya et al. [21], who calibrated and validated SWAT using MOD16 and GLEAM < 25% in the Ogun River Basin in Nigeria. The PBIAS achieved during calibration and validation of the model with ETMonitor almost agreed with the results by Poméon et al. [20] when they validated the SWAT in West Africa using MOD16. The PBIAS values obtained with the WaPOR and SSEBop data do not agree with the findings of Weerasingh et al. [71], who evaluated different remote sensing ETa products in Africa and found that the highest-ranked products were WaPOR and SSEBop, while the GLEAM dataset attained the lowest rank.

Our results on the calibration with ETMonitor suggested an underestimation by SWAT, but in the validation experiments, SWAT generally overestimated ETa. A very good performance of the SWAT model ETa configured using Hargreaves ETp equation with both ETMonitor and GLEAM was indicated by all performance metrics. These findings showed better values than those found by other studies [21]. The best SWAT calibration and validation performance is related to the choice of the Hargreaves ETp equation. This equation was applied to actual observations of precipitation and maximum and minimum temperature to compute the ETa. On the other hand, the other two ETp equations (Penman–Monteith and Priestley–Taylor) were calculated with the model (reanalysis) meteorological data on solar radiation relative humidity and wind speed due to the absence of the required data. The differences in all remote sensing ETa datasets are due to their input and forcing data [72] and to the different remote sensing ETa retrieval algorithms. Our findings agreed with Lopez et al. [18] in Morocco. They reported that the GLEAM ETa gave a satisfactory performance for the calibration of a large-scale hydrological model set-up. Moreover, our results agree with the findings of Odusanya et al. [21] in the Ogun River Basin in Nigeria. They reported that the calibration of the SWAT model using the GLEAM dataset showed a satisfactory performance.

Furthermore, the four remote sensing ETa products were compared and we found that the WaPOR values were on average higher than SSEBop, ETMonitor, and GLEAM by 80 mm, 240 mm, and 300 mm, respectively. The SSEBop values are on average higher than ETMonitor and GLEAM by 160 mm and 220 mm, respectively, while the difference between ETMonitor and GLEAM is about 60 mm (Figure A2). Moreover, the calibration was performed using the original spatial resolutions of the four products, and, as shown in Figure 3, the spatial distribution of the performance metrics indicated that there is no relation between the calibration performance and sub-basin extensions (size). Furthermore, the calibration with the ETMonitor data achieves the highest performance, while SSEBop gave a lower performance at the same spatial resolution (Figure 3 and Table 8) and this indicates that the performance is not related to the spatial resolution of the products.

The SWAT estimates of SWC for the top 10 mm soil layer were compared with the ESA CCI SSM for a dry, i.e., 2009, and wet year, i.e., 2012 (Figure 7). To further refine this analysis, the results are also presented separately for the dry, i.e., January–May and November–December, and wet months, i.e., June–October. During the dry months, there was good agreement between SWAT SWC and ESSA CCI SSM. Larger differences were observed during the wet months, suggesting limited sensitivity of the SWAT SWC to precipitation.

The time series of ESA CCI SSM at a depth of 50 mm and SWAT SWC at the top 50 mm gave better agreement throughout the entire period 2009–2015 (Figure 8b). Contrary to the top 10 mm soil layer, the maximum SWAT SWC during the wet months was consistently higher than the ESA CCI SSM. This suggests that model estimates and the SSM data product capture in a different manner the vertical redistribution of rainwater. The R², NSE, and KGE were all higher than 0.85. That confirmed what was reported by Poméon et al. [20] and Odusanya et al. [21] that the dynamic of the SWAT SM fit very well with the ESA CCI SSM (%) in the upper few centimeters of the soil profile in most of the basin at a monthly time step.

Overall, the SWAT estimates appear to capture the seasonality correctly in TWSC (Figure 9b): the SWAT TWSC was in good agreement with the GRACE retrievals, although the differences in the wet months were at times large and not systematic. The monthly GRACE TWSC data showed rather large and rapid fluctuations in the dry period, leading to large and variable differences with the SWAT TWSC estimates. The performance metrics were satisfactory, but not very high, i.e., R² = 0.56 and NSE = 0.55. Grippa et al. [73] observed similar outcomes in the Sahel and West Africa after they compared the TWSC GRACE retrievals with estimates based on nine hydrological models. They concluded that the most important difference between the two TWSC datasets is the noticeable decline of TWSC during dry months. They reported that these results were explained by the incorrectly simulated evapotranspiration through the dry season. Ndehedehe et al. [74] reported similar results, and they assumed that it might have been due to the anthropogenic influences intensifying land surface processes that were not properly captured by hydrological models. Poméon et al. [20] also suggested that the lack of observations to be used in model calibration could lead to a biased estimation of soil water outflow, which causes erroneous estimates of TWSC. The multi-validation results show the SWAT model to perform satisfactorily in the study area.

Several studies have been performed in order to evaluate the water balance of the Lake Chad Basin [2,25,30,75,76,77,78,79]. Some of these studies are summarized in Table 10. The first two studies evaluated the water budget when the Lake Chad Basin was in hydrological equilibrium and the lake was not shrinking. Almost all the previous studies simulated the runoff only for the Chari-Logone River, such as the studies conducted by Vuillaume [79], Olivry et al. [77], Odada et al. [2], Zhu et al. [25], and Mahamat Nour et al. [30]. In our study, the runoff was estimated for the whole southern Lake Chad Basin. Note that all these studies were carried out in different years and different parts of Lake Chad Basin so that exact comparison is unrealistic. In general, the runoff simulated by our study is comparable to the other studies in recent years (i.e., after 1970), notwithstanding the different temporal and spatial coverage of the study.

We also compared the time series of our estimates of yearly runoff with other available studies on time series, either from observations or by modeling [80,81] (Figure 11). All the model studies and the observed runoff confirmed the increase in the runoff in the comparison period starting from 2009, and followed similar trends and fluctuations. The difference in some values between our study and the two other studies is probably due to the different spatial coverage, where the studies by Zhu et al. [81] and Mahmood and Jia [80] simulated the runoff only for the Chari-Logone River Basin which is a part of our study area. In these two studies, data of observed runoff were collected only at the outlet of Chari-Logone River [80,81], while our study simulated the runoff for the whole southern Lake Chad Basin. There is a difference in various hydro-meteorological conditions between those two studies, the observations, and our study, which is probably the main reason for the high value in 2012 in our study; however, our simulated runoff showed higher agreement with the runoff observations shown in Figure 11.

6. Conclusions

This study demonstrated that it is feasible to calibrate the semi-distributed regional hydrological model SWAT for the entire LCB, notwithstanding the scarcity of hydrological data, by using remote sensing data products of ETa. An innovative aspect was to limit the calibration to one year, i.e., 2009, by designing the calibration experiments to reduce the number of unknown parameters. Our results demonstrated that this new limited calibration approach did improve model performance for the entire period past calibration, i.e., 2010–2015. A broader set of forty potentially influential parameters was defined based on the literature. Using the global sensitivity analysis tool in SWAT-CUP, fifteen parameters were selected for calibration. The 15 correction values used to modify the selected parameters, which are assigned by HRU, were computed using LHS in SUFI-2 in the SWAT-CUP package, and only one value for each correction of each parameter was calculated for the entire LCB using twelve observations of ETa in each of the 37 sub-basins, i.e., using 444 data points in the calibration experiments. The final values of the corrections were applied in the validation experiments and subsequent analyses by SWAT.

The calibration experiments were designed to improve the accuracy of the SWAT estimates of monthly ETa against four different ETa datasets based on remote sensing observations. The model was configured to use three equations to calculate potential evapotranspiration, i.e., Hargreaves, Priestley–Taylor, and Penman–Monteith, due to their impacts on the estimated ETa. Four satellite observation-based ETa products and SWAT estimates with the three ETp equations gave twelve (12) calibration experiments aiming to improve model performance in the LCB. Generally, the limited calibration (one year on a monthly timescale) results show that the remote sensing products are useful to calibrate and validate the SWAT model in arid to semi-arid poorly gauged basins, even though the temporal coverage of the calibration was limited. The best performance was obtained with the SWAT ETa estimates based on the ETMonitor ETa.

A statistical study has been performed to evaluate the model calibration limited to one year. Differences across the remote sensing ETa products were significant, consistent with the different algorithms used to estimate the ETa. The statistical analysis of both calibration and validation results indicated that the ETMonitor and GLEAM led to a better SWAT performance than SSEBop and WaPOR. The variations in ETa performance across different sub-basins are due to the non-linearity of the algorithms used to generate the four data products and the SWAT model. This gives a complex response of actual evapotranspiration to the spatial variability in the main input data such as weather, land use, soil moisture, etc. To address this issue properly requires a complete, in-depth study to analyze and explain in detail the interplay of these factors in determining the spatially variable performance in estimating ETa across different locations.

SWAT estimates of soil water content and total water storage change were compared with satellite data products. Overall, the agreement was good, further confirming the usefulness of the proposed limited calibration in our data-scarce study area. The limited calibration of a hydrological model using remote sensing data is one of the solutions to deal with the scarcity of hydrological data, and it also needs less computational capacity and time, as opposed to a calibration performed for several years which requires much computational time and resources. So, the computational load in the case of limited calibration is much lower than the calibration for several years.

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Figure 1. The African Sahel, the location of the Lake Chad Basin, the study area (Southern Lake Chad Basin), and the 37 delineated sub-basins.

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Figure 2. The conceptual framework of this study: (a) the SWAT flowchart (and uncalibrated model outputs), (b) SWAT-CUP flowchart (parameter selection and calibration), and (c) the validation schemes (using the calibrated model).

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Figure 3. Spatial distribution of performance metrics (R2, NSE, and KGE) of SWAT_Hargreaves, when calibrated in 2009 against ETMonitor, GLEAM, WaPOR, and SSEBop (a,b,c,d), respectively, in the study area in the Lake Chad Basin.

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Figure 4. Comparison between ETMonitor ETa and SWAT-calibrated ETa for all sub-catchments in the LCB.

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Figure 5. Spatial distribution of performance metrics (R2, NSE, and KGE) of SWAT_Hargreaves when validated against ETMonitor in 2010, 2011, 2012, 2013, 2014, and 2015 (a,b,c,d,e,f), respectively, in the study area in the Lake Chad Basin.

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Figure 6. Time series of monthly uncalibrated and calibrated ETa simulated by the SWAT and ETa from ETMonitor in 2009–2015 in the study area in the Lake Chad Basin.

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Figure 7. Seasonal comparison between monthly averaged SWAT and ESA CCI SSM at 1 cm on 2009 as driest year: (a) dry months, (b) wet months and on 2012 as wettest year: (c) dry months, and (d) wet months.

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Figure 8. Comparison between monthly averaged SWAT SWC (black line) vs. ESA CCI SM (red line) at 50 mm during 2009–2015 in the study area in the Lake Chad Basin: (a) the scatter plot, (b) comparison of time series.

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Figure 9. Comparison between monthly TWSC averaged over the study area in the Lake Chad Basin for 2009–2015: SWAT estimates and GRACE data product, at 1 km resolution: (a1) scatter plot, (b1) time series, and at 300 km resolution: (a2) scatter plot, (b2) time series.

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Figure 10. Average annual water balance components in the study area in the Lake Chad Basin based on SWAT-simulated output before (Uncalibrated) and after (Calibrated) calibration. (ETa: actual evapotranspiration; SW: soil water content; PERC: perception; SURQ: surface runoff; GW_Q: groundwater recharge; WYLD: water yield; LATQ: lateral runoff.

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Figure 11. Comparison of simulated runoff in the Lake Chad Basin by different studies.

Appendix A

Text A1: Details about remote sensing ETa products.

ETMonitor

In this study, the ETMonitor ETa was used on its version v1.0. In the ETMonitor model, different modules were integrated to estimate each evapotranspiration component for different land cover types. These include soil evaporation and plant transpiration by a dual-source Shuttleworth–Wallace model for the soil-plant system, vegetation canopy rainfall interception loss by the modified Gash analytical model, open water body, and a sublimation module for snow/ice surfaces by Penman equation. Each module is described in [15]. ETMonitor has been validated globally using in situ measurements in several bioclimatic zones [36].

SSEBop

The version of the ETa of the Simplified Surface Energy Balance for operational application (SSEBop) used in this paper was v4. The SSEBop model requires elevation, land surface temperature, clear-sky net radiation, reference ETa, albedo, and NDVI data. The SSEBop ETa is based on a thermal index approach, and more details can be found in [80].

WaPOR

Version v1.1 of the water productivity (WaPOR) ETa was used in this study. The WaPOR evapotranspiration dataset was produced by the Food and Agriculture Organization of the United Nations. Evaporation (E) and Transpiration (T) were calculated based on the ETLook model described in [82]. It uses the Penman–Monteith (P-M) equation, adapted to remote sensing input data. The Penman–Monteith equation [83] estimates the rate of total evapotranspiration using commonly measured meteorological data (solar radiation, air temperature, vapor pressure, and wind speed). Calculating evapotranspiration requires input from seven data components. Solar radiation and precipitation were obtained from ground stations; other weather data (the wind speed, min and max temperature, and relative humidity were estimated using models) are daily inputs. Soil moisture stress, NDVI, and surface albedo are decadal inputs; readers can refer to FAO, (2018) [38] for further details. The WaPOR ETa product has been available since 2009.

GLEAM

The Global Land Evaporation Amsterdam Model (GLEAM) was developed in 2011 [17], and it was revised and updated in 2017 [16]. In this study, the latest version of this product (GLEAM_v3.3a) was downloaded from (www.gleam.eu; accessed on 28 October 2020). The forcing variables used to produce GLEAM_v3.3a are detailed in [16]. The Priestley–Taylor equation was used in GLEAM to compute the potential evapotranspiration (mm/day) based on surface net radiation and near-surface air temperature observations. Actual evapotranspiration is estimated by multiplying potential evapotranspiration with the evaporative stress factor “S” which was calculated based on microwave observations of the vegetation optical depth, remote sensing retrievals of soil moisture, and simulations of root-zone soil moisture. More details about GLEAM can be found in [16,84].

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Figure A1. Spatial distribution of performance metrics (R2, NSE, and KGE) of SWAT ETa based on P-M when calibrated in 2009 against ETMonitor, GLEAM, WaPOR, and SSEBop (a1,b1,c1,d1), respectively, and SWAT ETa based on P-T when calibrated in 2009 against ETMonitor, GLEAM, WaPOR, and SSEBop (a2,b2,c2,d2), respectively.

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Figure A2. The annual mean of different remote sensing evapotranspiration products in Lake Chad.

References

1. Chen, C.; Park, T.; Wang, X.; Piao, S.; Xu, B.; Chaturvedi, R.K.; Fuchs, R.; Brovkin, V.; Ciais, P.; Fensholt, R. et al. China and India lead in greening of the world through land-use management. Nat. Sustain.; 2019; 2, pp. 122-129. [DOI: https://dx.doi.org/10.1038/s41893-019-0220-7] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30778399]

2. Odada, E.O.; Oyebande, L.; Oguntola, A.J. Lake Chad: Experience and lessons learned Brief. Proceedings of the International Lake Environment Committee Foundation; Kusatsu, Japan, 27 November 2006; pp. 75-91.

3. Carroll, S.; Liu, A.; Dawes, L.; Hargreaves, M.; Goonetilleke, A. Role of Land Use and Seasonal Factors in Water Quality Degradations. Water Resour. Manag.; 2013; 27, pp. 3433-3440. [DOI: https://dx.doi.org/10.1007/s11269-013-0356-6]

4. McDonald, R.I.; Weber, K.; Padowski, J.; Flörke, M.; Schneider, C.; Green, P.A.; Gleeson, T.; Eckman, S.; Lehner, B.; Balk, D. et al. Water on an urban planet: Urbanization and the reach of urban water infrastructure. Glob. Environ. Chang.; 2014; 27, pp. 96-105. [DOI: https://dx.doi.org/10.1016/j.gloenvcha.2014.04.022]

5. Arnold, J.G.; Srinivasan, R.; Muttiah, R.S.; Williams, J.R. Large area hydrologic modeling and assessment part I: Model development. J. Am. Water Resour. Assoc.; 1998; 34, pp. 73-89. [DOI: https://dx.doi.org/10.1111/j.1752-1688.1998.tb05961.x]

6. Awotwi, A.; Kumi, M.; Jansson, P.E.; Yeboah, F.; Nti, I.K. Predicting Hydrological Response to Climate Change in the White Volta Catchment, West Africa. J. Earth Sci. Clim. Chang.; 2015; 6, 249. [DOI: https://dx.doi.org/10.4172/2157-7617.1000249]

7. Cheng, Y.; He, H.; Cheng, N.; He, W. The Effects of Climate and Anthropogenic Activity on Hydrologic Features in Yanhe River. Adv. Meteorol.; 2016; 2016, 5297158. [DOI: https://dx.doi.org/10.1155/2016/5297158]

8. Schuol, J.; Abbaspour, K.C. Calibration and uncertainty issues of a hydrological model ( SWAT ) applied to West Africa. Adv. Geosci.; 2006; 9, pp. 137-143. [DOI: https://dx.doi.org/10.5194/adgeo-9-137-2006]

9. Laurent, F.; Ruelland, D. Modélisation à base physique de la variabilité hydroclimatique à l’échelle d’un grand bassin versant tropical. Global Change: Facing Risks and Threats to Water Resour; Fez: Morroco, France, 2010; pp. 474-484.

10. Adeogun, A.; Sule, B.; Salami, A.; Okeola, O. GIS-Based Hydrological Modelling Using Swat: Case Study of Upstream Watershed of Jebba Reservoir in Nigeria. Niger. J. Technol.; 2014; 33, 351. [DOI: https://dx.doi.org/10.4314/njt.v33i3.13]

11. Nkiaka, E.; Nawaz, N.R.; Lovett, J.C. Effect of single and multi-site calibration techniques on hydrological model performance, parameter estimation and predictive uncertainty: A case study in the Logone catchment, Lake Chad basin. Stoch. Environ. Res. Risk Assess.; 2018; 32, pp. 1665-1682. [DOI: https://dx.doi.org/10.1007/s00477-017-1466-0]

12. Schuol, J.; Abbaspour, K.C.; Srinivasan, R.; Yang, H. Estimation of freshwater availability in the West African sub-continent using the SWAT hydrologic model. J. Hydrol.; 2007; 352, pp. 30-49. [DOI: https://dx.doi.org/10.1016/j.jhydrol.2007.12.025]

13. Mengistu, A.G.; van Rensburg, L.D.; Woyessa, Y.E. Techniques for calibration and validation of SWAT model in data scarce arid and semi-arid catchments in South Africa. J. Hydrol. Reg. Stud.; 2019; 25, 100621. [DOI: https://dx.doi.org/10.1016/j.ejrh.2019.100621]

14. Senay, G.; Leake, S.; Nagler, P.L.; Artan, G.; Dickinson, J.; Cordova, J.; Glenn, E. Estimating basin scale evapotranspiration (ET) by water balance and remote sensing methods. Hydrol. Process.; 2011; 25, pp. 4037-4049. [DOI: https://dx.doi.org/10.1002/hyp.8379]

15. Zheng, C.; Jia, L.; Hu, G.; Lu, J.; Wang, K.; Li, Z. Global evapotranspiration derived by ETMonitor model based on earth observations. Int. Geosci. Remote Sens. Symp.; 2016; 2016, pp. 222-225. [DOI: https://dx.doi.org/10.1109/IGARSS.2016.7729049]

16. Martens, B.; Miralles, D.G.; Lievens, H.; Van Der Schalie, R.; De Jeu, R.A.M.; Fernández-Prieto, D.; Beck, H.E.; Dorigo, W.A.; Verhoest, N.E.C. GLEAM v3: Satellite-based land evaporation and root-zone soil moisture. Geosci. Model Dev.; 2017; 10, pp. 1903-1925. [DOI: https://dx.doi.org/10.5194/gmd-10-1903-2017]

17. Miralles, D.G.; Holmes, T.R.H.; De Jeu, R.A.M.; Gash, J.H.; Meesters, A.G.C.A.; Dolman, A.J. Global land-surface evaporation estimated from satellite-based observations. Hydrol. Earth Syst. Sci.; 2011; 15, pp. 453-469. [DOI: https://dx.doi.org/10.5194/hess-15-453-2011]

18. Lopez Lopez, P.; Sutanudjaja, E.; Schellekens, J.; Sterk, G.; Bierkens, M. Calibration of a large-scale hydrological model using satellite-based soil moisture and evapotranspiration products. Hydrol. Earth Syst. Sci.; 2017; 21, pp. 3125-3144. [DOI: https://dx.doi.org/10.5194/hess-21-3125-2017]

19. Ha, L.T.; Bastiaanssen, W.G.M.; van Griensven, A.; van Dijk, A.I.J.M.; Senay, G.B. Calibration of spatially distributed hydrological processes and model parameters in SWAT using remote sensing data and an auto-calibration procedure: A case study in a Vietnamese river basin. Water; 2018; 10, 212. [DOI: https://dx.doi.org/10.3390/w10020212]

20. Poméon, T.; Diekkrüger, B.; Springer, A.; Kusche, J.; Eicker, A. Multi-objective validation of SWAT for sparsely-gaugedWest African river basins—A remote sensing approach. Water; 2018; 10, 451. [DOI: https://dx.doi.org/10.3390/w10040451]

21. Odusanya, A.E.; Mehdi, B.; Schürz, C.; Oke, A.O.; Awokola, O.S.; Awomeso, J.A.; Adejuwon, J.O.; Schulz, K. Multi-site calibration and validation of SWAT with satellite-based evapotranspiration in a data-sparse catchment in southwestern Nigeria. Hydrol. Earth Syst. Sci.; 2019; 23, pp. 1113-1144. [DOI: https://dx.doi.org/10.5194/hess-23-1113-2019]

22. Tang, L.; Yang, D.; Hu, H.; Gao, B. Detecting the effect of land-use change on streamflow, sediment and nutrient losses by distributed hydrological simulation. J. Hydrol.; 2011; 409, pp. 172-182. [DOI: https://dx.doi.org/10.1016/j.jhydrol.2011.08.015]

23. Coe, M.T.; Foley, J.A. Human and natural impacts on the water resources of the Lake Chad basin. J. Geophys. Res. Atmos.; 2001; 106, pp. 3349-3356. [DOI: https://dx.doi.org/10.1029/2000JD900587]

24. Gao, H.; Bohn, T.J.; Podest, E.; McDonald, K.C.; Lettenmaier, D.P. On the causes of the shrinking of Lake Chad. Environ. Res. Lett.; 2011; 6, [DOI: https://dx.doi.org/10.1088/1748-9326/6/3/034021]

25. Zhu, W.; Yan, J.; Jia, S. Monitoring recent fluctuations of the southern pool of lake chad using multiple remote sensing data: Implications for water balance analysis. Remote Sens.; 2017; 9, 1032. [DOI: https://dx.doi.org/10.3390/rs9101032]

26. Policelli, F.; Hubbard, A.; Jung, H.C.; Zaitchik, B.; Ichoku, C. A predictive model for Lake Chad total surface water area using remotely sensed and modeled hydrological and meteorological parameters and multivariate regression analysis. J. Hydrol.; 2019; 568, pp. 1071-1080. [DOI: https://dx.doi.org/10.1016/j.jhydrol.2018.11.037]

27. Lemoalle, J.; Magrin, G. Development of Lake Chad Current Situation and Posiible Outcomes, IRD ed.; Robert, S.; André, L.V. OpenEdition Books: Marseille, France, 2014; ISBN 9782709918367

28. Frenken, K.; Jean-Marc, F. Irrigation Potential in Africa: A Basin Approach; FAO: Rome, Italy, 1997; ISBN 92-5-103966-6

29. Policelli, F.; Hubbard, A.; Jung, H.C.; Zaitchik, B.; Ichoku, C. Lake Chad total surface water area as derived from Land Surface Temperature and radar remote sensing data. Remote Sens.; 2018; 10, 252. [DOI: https://dx.doi.org/10.3390/rs10020252]

30. Mahamat Nour, A.; Vallet-Coulomb, C.; Gonçalves, J.; Sylvestre, F.; Deschamps, P. Rainfall-discharge relationship and water balance over the past 60 years within the Chari-Logone sub-basins, Lake Chad basin. J. Hydrol. Reg. Stud.; 2021; 35, 100824. [DOI: https://dx.doi.org/10.1016/j.ejrh.2021.100824]

31. Delclaux, F.; Le Coz, M.; Coe, M.; Favreau, G.; Ngounou Ngatcha, B. Confronting Models with Observations for Evaluating Hydrological Change in the Lake Chad Basin, Africa. Proceedings of the 13th IWRA World Water Congress; Montpellier, France, 1–4 September 2008.

32. Hersbach, H.; Bell, B.; Berrisford, P.; Hirahara, S.; Horányi, A.; Muñoz-Sabater, J.; Nicolas, J.; Peubey, C.; Radu, R.; Schepers, D. et al. The ERA5 global reanalysis. Q. J. R. Meteorol. Soc.; 2020; 146, pp. 1999-2049. [DOI: https://dx.doi.org/10.1002/qj.3803]

33. Funk, C.; Peterson, P.; Landsfeld, M.; Pedreros, D.; Verdin, J.; Shukla, S.; Husak, G.; Rowland, J.; Harrison, L.; Hoell, A. et al. The climate hazards infrared precipitation with stations—A new environmental record for monitoring extremes. Sci. Data; 2015; 2, 150066. [DOI: https://dx.doi.org/10.1038/sdata.2015.66]

34. Katsanos, D.; Retalis, A.; Michaelides, S. Validation of a high-resolution precipitation database (CHIRPS) over Cyprus for a 30-year period. Atmos. Res.; 2016; 169, pp. 459-464. [DOI: https://dx.doi.org/10.1016/j.atmosres.2015.05.015]

35. Wang, J.; Zhao, Y.; Li, C.; Yu, L.; Liu, D.; Gong, P. Mapping global land cover in 2001 and 2010 with spatial-temporal consistency at 250m resolution. ISPRS J. Photogramm. Remote Sens.; 2015; 103, pp. 38-47. [DOI: https://dx.doi.org/10.1016/j.isprsjprs.2014.03.007]

36. Jia, L.; Zheng, C.; Hu, G.C.; Menenti, M. Evapotranspiration. Comprehensive Remote Sensing; Elsevier: Beijing, China, 2018; Volumes 1–9, pp. 25-50. ISBN 9780128032206

37. Senay, G.B.; Bohms, S.; Singh, R.K.; Gowda, P.H.; Velpuri, N.M.; Alemu, H.; Verdin, J.P. Operational Evapotranspiration Mapping Using Remote Sensing and Weather Datasets: A New Parameterization for the SSEB Approach. J. Am. Water Resour. Assoc.; 2013; 49, pp. 577-591. [DOI: https://dx.doi.org/10.1111/jawr.12057]

38. WaPOR Database Methodology: Level 1 Remote Sensing for Water Productivity Technical Report: Methodology Series; FAO: Rome, Italy, 2018; ISBN 978-92-5-109769-4

39. Gruber, A.; Dorigo, W.A.; Crow, W.; Wagner, W. Triple Collocation-Based Merging of Satellite Soil Moisture Retrievals. IEEE Trans. Geosci. Remote Sens.; 2017; 55, pp. 6780-6792. [DOI: https://dx.doi.org/10.1109/TGRS.2017.2734070]

40. Gruber, A.; Scanlon, T.; Van Der Schalie, R.; Wagner, W.; Dorigo, W. Evolution of the ESA CCI Soil Moisture climate data records and their underlying merging methodology. Earth Syst. Sci. Data; 2019; 11, pp. 717-739. [DOI: https://dx.doi.org/10.5194/essd-11-717-2019]

41. Dorigo, W.; Wagner, W.; Albergel, C.; Albrecht, F.; Balsamo, G.; Brocca, L.; Chung, D.; Ertl, M.; Forkel, M.; Gruber, A. et al. ESA CCI Soil Moisture for improved Earth system understanding: State-of-the art and future directions. Remote Sens. Environ.; 2017; 203, pp. 185-215. [DOI: https://dx.doi.org/10.1016/j.rse.2017.07.001]

42. Tapley, B.D.; Bettadpur, S.; Watkins, M.; Reigber, C. The gravity recovery and climate experiment: Mission overview and early results. Geophys. Res. Lett.; 2004; 31, pp. 1-4. [DOI: https://dx.doi.org/10.1029/2004GL019920]

43. Wahr, J.; Molenaar, M.; Bryan, F. Time variability of the Earth’s gravity field: Hydrological and oceanic effects and their possible detection using GRACE. J. Geophys. Res. Solid Earth; 1998; 103, pp. 30205-30229. [DOI: https://dx.doi.org/10.1029/98JB02844]

44. Wouters, B.; Bonin, J.A.; Chambers, D.P.; Riva, R.E.M.; Sasgen, I.; Wahr, J. GRACE, time-varying gravity, Earth system dynamics and climate change. Rep. Prog. Phys.; 2014; 77, [DOI: https://dx.doi.org/10.1088/0034-4885/77/11/116801]

45. Save, H.; Bettadpur, S.; Tapley, B.D. High-resolution CSR GRACE RL05 mascons. J. Geophys. Res. Solid Earth; 2016; 121, pp. 7547-7569. [DOI: https://dx.doi.org/10.1002/2016JB013007]

46. Biancamaria, S.; Mballo, M.; Le Moigne, P.; Sánchez Pérez, J.M.; Espitalier-Noël, G.; Grusson, Y.; Cakir, R.; Häfliger, V.; Barathieu, F.; Trasmonte, M. et al. Total water storage variability from GRACE mission and hydrological models for a 50,000 km2 temperate watershed: The Garonne River basin (France). J. Hydrol. Reg. Stud.; 2019; 24, 100609. [DOI: https://dx.doi.org/10.1016/j.ejrh.2019.100609]

47. Long, D.; Longuevergne, L.; Scanlon, B.R. Uncertainty in evapotranspiration from land surface modeling, remote sensing, and GRACE satellites. Water Resour. Res.; 2014; 50, pp. 1131-1151. [DOI: https://dx.doi.org/10.1002/2013WR014581]

48. George, C.; Leon, L.F. WaterBase: SWAT in an Open Source GIS. Open Hydrol. J.; 2008; 2, pp. 1-6. [DOI: https://dx.doi.org/10.2174/1874378100802010001]

49. Neitsch, S.L.; Arnold, J.G.; Kiniry, J.R.; Williams, J.R. Soil & Water Assessment Tool Theoretical Documentation Version 2009; Texas Water Resources Institute: College Station, TX, USA, 2011.

50. Neitsch, S.L.; Arnold, J.G.; Kiniry, J.R. Soil and Water Assessment Tool Input/Output File Documentation Version 2009; Soil and Water Assessment Tool: College Station, TX, USA, 2011; 643.

51. Neitsch, S.L.; Arnold, J.G.; Kiniry, J.R.; Williams, J.R. Soil and Water Assessment Tool Documentation Version 2005; Grassland, Soil and Water Research Laboratory: College Station, TX, USA, 2005; 476.

52. Teshager, A.D.; Gassman, W.P.; Secchi, S.; Justin, T.S.; Girmaye, M. Modeling Agricultural Watersheds with the Soil and Water Assessment Tool (SWAT): Calibration and Validation with a Novel Procedure for Spatially Explicit HRUs. Environ. Manag.; 2016; 57, pp. 894-911. [DOI: https://dx.doi.org/10.1007/s00267-015-0636-4] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/26616430]

53. Her, Y.; Frankenberger, J.; Chaubey, I.; Srinivasan, R. Threshold effects in HRU definition of the soil and water assessment tool. Am. Soc. Agric. Biol. Eng.; 2015; 58, pp. 367-378. [DOI: https://dx.doi.org/10.13031/trans.58.10805]

54. Abbaspour, K.C.; Rouholahnejad, E.; Vaghefi, S.; Srinivasan, R.; Yang, H.; Kløve, B. A continental-scale hydrology and water quality model for Europe: Calibration and uncertainty of a high-resolution large-scale SWAT model. J. Hydrol.; 2015; 524, pp. 733-752. [DOI: https://dx.doi.org/10.1016/j.jhydrol.2015.03.027]

55. Abbaspour, K.C.; Johnson, C.A.; van Genuchten, M.T. Estimating Uncertain Flow and Transport Parameters Using a Sequential Uncertainty Fitting Procedure. Vadose Zone J.; 2004; 3, pp. 1340-1352. [DOI: https://dx.doi.org/10.2136/vzj2004.1340]

56. Wang, X.; Melesse, A.M.; Yang, W. Influences of potential evapotranspiration estimation methods on SWAT’s hydrologic simulation in a northwestern Minnesota watershed. Trans. ASABE; 2006; 49, pp. 1755-1771. [DOI: https://dx.doi.org/10.13031/2013.22297]

57. Emam, A.R.; Kappas, M.; Linh, N.H.K.; Renchin, T. Hydrological modeling and runoff mitigation in an ungauged basin of central Vietnam using SWAT model. Hydrology; 2017; 4, 16. [DOI: https://dx.doi.org/10.3390/hydrology4010016]

58. Boulain, N.; Cappelaere, B.; Séguis, L.; Favreau, G.; Gignoux, J. Water balance and vegetation change in the Sahel: A case study at the watershed scale with an eco-hydrological model. J. Arid Environ.; 2009; 73, pp. 1125-1135. [DOI: https://dx.doi.org/10.1016/j.jaridenv.2009.05.008]

59. Moriasi, D.N.; Gitau, M.W.; Pai, N.; Daggupati, P. Hydrologic and water quality models: Performance measures and evaluation criteria. Am. Soc. Agric. Biol. Eng.; 2015; 58, pp. 1763-1785. [DOI: https://dx.doi.org/10.13031/trans.58.10715]

60. Moriasi, D.N.; Arnold, J.G.; Van Liew, M.W.; Bingner, R.L.; Harmel, R.D.; Veith, T.L. Model evaluation guidelines for systematic quantification of accuracy in watershed simulations. Am. Soc. Agric. Biol. Eng.; 2007; 50, pp. 885-900. [DOI: https://dx.doi.org/10.13031/2013.23153]

61. Abbaspour, K.C. SWAT-CUP SWAT Calibration and Uncertainty Programs—A User Manual 2015; Swiss Federal Institute of Aqualtic Science and Technology: Dübendorf, Switzerland, 2015.

62. Schuol, J.; Abbaspour, K.C. Using monthly weather statistics to generate daily data in a SWAT model application to West Africa. Ecol. Model.; 2007; 201, pp. 301-311. [DOI: https://dx.doi.org/10.1016/j.ecolmodel.2006.09.028]

63. Djaman, K.; Tabari, H.; Balde, A.B.; Diop, L.; Futakuchi, K.; Irmak, S. Analyses, calibration and validation of evapotranspiration models to predict grass-reference evapotranspiration in the Senegal river delta. J. Hydrol. Reg. Stud.; 2016; 8, pp. 82-94. [DOI: https://dx.doi.org/10.1016/j.ejrh.2016.06.003]

64. Samadi, S.Z. Assessing the sensitivity of SWAT physical parameters to potential evapotranspiration estimation methods over a coastal plain watershed in the southeastern United States. Hydrol. Res.; 2017; 48, pp. 395-415. [DOI: https://dx.doi.org/10.2166/nh.2016.034]

65. Nash, J.E.; Sutcliffe, J.V. River flow forecasting through conceptual models Part I—A discussion of principales. J. Hydrol.; 1970; 10, pp. 282-290. [DOI: https://dx.doi.org/10.1016/0022-1694(70)90255-6]

66. Gupta, H.V.; Kling, H.; Yilmaz, K.K.; Martinez, G.F. Decomposition of the mean squared error and NSE performance criteria: Implications for improving hydrological modelling. J. Hydrol.; 2009; 377, pp. 80-91. [DOI: https://dx.doi.org/10.1016/j.jhydrol.2009.08.003]

67. Gupta, H.V.; Sorooshian, S.; Yapo, P.O. Status of Automatic Calibration for Hydrologic Models: Comparison with Multilevel Expert Calibration. J. Hydrol. Eng.; 1999; 4, pp. 135-143. [DOI: https://dx.doi.org/10.1061/(ASCE)1084-0699(1999)4:2(135)]

68. Rajib, M.A.; Merwade, V.; Yu, Z. Multi-objective calibration of a hydrologic model using spatially distributed remotely sensed/in-situ soil moisture. J. Hydrol.; 2016; 536, pp. 192-207. [DOI: https://dx.doi.org/10.1016/j.jhydrol.2016.02.037]

69. Rodell, M.; Famiglietti, J.S. Detectability of variations in continental water storage from satellite observations of the time dependent gravity field. Water Resour. Res.; 1999; 35, pp. 2705-2723. [DOI: https://dx.doi.org/10.1029/1999WR900141]

70. Kouchi, D.H.; Esmaili, K.; Faridhosseini, A.; Sanaeinejad, S.H.; Khalili, D.; Abbaspour, K.C. Sensitivity of calibrated parameters and water resource estimates on different objective functions and optimization algorithms. Water; 2017; 9, 384. [DOI: https://dx.doi.org/10.3390/w9060384]

71. Weerasinghe, I.; Bastiaanssen, W.; Mul, M.; Jia, L.; Van Griensven, A. Can we trust remote sensing evapotranspiration products over Africa. Hydrol. Earth Syst. Sci.; 2020; 24, pp. 1565-1586. [DOI: https://dx.doi.org/10.5194/hess-24-1565-2020]

72. Trambauer, P.; Dutra, E.; Maskey, S.; Werner, M.; Pappenberger, F.; Van Beek, L.P.H.; Uhlenbrook, S. Comparison of different evaporation estimates over the African continent. Hydrol. Earth Syst. Sci.; 2014; 18, pp. 193-212. [DOI: https://dx.doi.org/10.5194/hess-18-193-2014]

73. Grippa, M.; Kergoat, L.; Frappart, F.; Araud, Q.; Boone, A.; De Rosnay, P.; Lemoine, J.M.; Gascoin, S.; Balsamo, G.; Ottlé, C. et al. Land water storage variability over West Africa estimated by Gravity Recovery and Climate Experiment (GRACE) and land surface models. Water Resour. Res.; 2011; 47, pp. 1-18. [DOI: https://dx.doi.org/10.1029/2009WR008856]

74. Ndehedehe, C.; Awange, J.; Agutu, N.; Kuhn, M.; Heck, B. Understanding changes in terrestrial water storage over West Africa between 2002 and 2014. Adv. Water Resour.; 2016; 88, pp. 211-230. [DOI: https://dx.doi.org/10.1016/j.advwatres.2015.12.009]

75. Report on the State of the Lake Chad Basin Ecosystem; Lake Chad Basin Commission and German Cooperation: N’Djamena, Chad, 2016.

76. Lemoalle, J.; Bader, J.C.; Leblanc, M.; Sedick, A. Recent changes in Lake Chad: Observations, simulations and management options (1973–2011). Glob. Planet. Chang.; 2012; 80–81, pp. 247-254. [DOI: https://dx.doi.org/10.1016/j.gloplacha.2011.07.004]

77. Olivry, J.; Chouret, A.; Lemoalle, J.; Bricquet, J. Hydrologie du lac Tchad; ORSTOM: Paris, France, 1996; ISBN 2-7099-1353-4

78. Pham-Duc, B.; Sylvestre, F.; Papa, F.; Frappart, F.; Bouchez, C.; Crétaux, J.F. The Lake Chad hydrology under current climate change. Sci. Rep.; 2020; 10, 5498. [DOI: https://dx.doi.org/10.1038/s41598-020-62417-w]

79. Vuillaume, G. Bilan hydrologique mensuel et modelisation sommaire du regime hydrologique du lac Tchad. Cah. ORSTOM Hydrol.; 1981; 18, pp. 23-72.

80. Mahmood, R.; Jia, S. Assessment of hydro-climatic trends and causes of dramatically declining stream flow to Lake Chad, Africa, using a hydrological approach. Sci. Total Environ.; 2019; 675, pp. 122-140. [DOI: https://dx.doi.org/10.1016/j.scitotenv.2019.04.219]

81. Zhu, W.; Jia, S.; Lall, U.; Cao, Q.; Mahmood, R. Relative contribution of climate variability and human activities on the water loss of the Chari/Logone River discharge into Lake Chad: A conceptual and statistical approach. J. Hydrol.; 2019; 569, pp. 519-531. [DOI: https://dx.doi.org/10.1016/j.jhydrol.2018.12.015]

82. Bastiaanssen, W.G.M.; Cheema, M.J.M.; Immerzeel, W.W.; Miltenburg, I.J.; Pelgrum, H. Surface energy balance and actual evapotranspiration of the transboundary Indus Basin estimated from satellite measurements and the ETLook model. Water Resour. Res.; 2012; 48, pp. 1-16. [DOI: https://dx.doi.org/10.1029/2011WR010482]

83. Monteith, J.L. Evaporation and environment. Symp. Soc. Exp. Biol.; 1965; 19, pp. 205-234.

84. Miralles, D.G.; De Jeu, R.A.M.; Gash, J.H.; Holmes, T.R.H.; Dolman, A.J. Magnitude and variability of land evaporation and its components at the global scale. Hydrol. Earth Syst. Sci.; 2011; 15, pp. 967-981. [DOI: https://dx.doi.org/10.5194/hess-15-967-2011]