Suitability of a Coupled Hydrologic and Hydraulic Model to Simulate Surface Water and Groundwater Hydrology in a Typical North-Eastern Germany Lowland Catchment

Waseem, Muhammad; Kachholz, Frauke; Klehr, Wolfgang; Tränckner, Jens

doi:10.3390/app10041281

Cited by 19 publications

(8 citation statements)

References 38 publications

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“…Waseem at el. [20] uses available low-frequency monitored flow and water quality data in combination with integrated hydrological and hydraulic modeling to represent the surface water and groundwater hydrology and NO 3 -N loads in the Tollense River catchment. The water balance results showed that 60-65% of total precipitation is lost via evapotranspiration.…”

Section: Introductionmentioning

confidence: 99%

An Integrated Hydrological Modelling Approach to Evaluate the Capacity of Keenjhar Lake by Using STELLA

et al. 2022

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Due to overexploitation and lower rainfall rates, it is essential to study the detailed water balance of the Keenjhar lake by considering the climate change impacts and higher water demands linked with the population growth. A hydrological model of Keenjhar Lake is developed based on a system dynamic approach using STELLA (Structural Thinking and Experiential Learning Laboratory with Animation). The model (STELLA) developed in the current research study comprises the following three sub-systems: population, water supply, and water demand. The hydrological and climate data for the period of seventeen years (2000–2016) is used in the current study. The monthly water budget of the Keenjhar Lake is determined by inflow components such as rainfall and the Kalri-Baghar Feeder (K.B.F) (upper) and outflow components such as evaporation, the K.B. Feeder (lower), and the Keenjhar-Gujju (K.G) canal from the lake. The water balance results revealed that the contribution of direct rainfall and the annual inflow components to the lake are 22.03% and 77.91%, respectively. Whereas the evaporation, outflow to K.B.F lower and water abstraction to the K.G. Canal constituted about 5.78%, 92.55%, and 1.57% of the total annual outflow from the lake, respectively. Moreover, the annual inflow components of the water budget of the lake showed a declining trend while the outflow components (water abstraction) intimated an increasing trend. The study results also acknowledged that the demand for water can increase from 3 × 1010 ft3/yr up to 1.2 × 1011 ft3/yr by the year 2050 (influence of overdrawing of water due to population growth), and water supply may decrease to 9.066 × 1010 ft3 (rainfall depletion due to climate change). A detailed water balance explains the main water loss components and will help in developing better water management practices and well-informed policy decisions.

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Section: Introductionmentioning

confidence: 99%

An Integrated Hydrological Modelling Approach to Evaluate the Capacity of Keenjhar Lake by Using STELLA

et al. 2022

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“…It concluded that groundwater modelling based on realistic assumptions on hydrogeological structure, boundary conditions, recharge and discharge areas can used as valuable tool for verification of the conceptual models accepted. There are four different process models, which integrate ground and surface water processes [4]. These models were compared based on own data requirement, desired complexity level, their ability to simulate relevant hydrologic and hydraulic processes.…”

Section: Introductionmentioning

confidence: 99%

Optimization of hydrogeological monitoring in the coal-mining region of Western Donbass

Yevhrashkina

Kharytonov

Shikula

et al. 2022

IOP Conf. Ser.: Earth Environ. Sci.

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The results of the solutions for assessing the degree of reliability compared with the results of regime observation network, water balance hydrogeological stations and key sites created for it. Epignous tasks occupy a special place in the optimization of hydrogeological monitoring of coal-mining regions. The “disordered dispersion” scheme should recognized as the most reliable after numerous numerical experiments to solve the problems of assessing the technogenic pollution of groundwater in the conditions of Western Donbas. The direct forecasting problem for various periods before the stabilization time was determined and solved at the final stage.

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“…This future climate scenario investigation approach is commonly based on the predictions of climate models and is deemed more scientific than directly assuming temperature and precipitation changes. The distributed hydrological model, MIKE SHE, has been widely used to simulate the runoff under different climates and underlying surface conditions (Waseem, Kachholz, Klehr, & Tränckner, 2020). It is the only integrated catchment modeling system in the MIKE series.…”

Section: Introductionmentioning

confidence: 99%

Runoff responses to climate change in China's Buyuan River Basin

Lü

Jiang

et al. 2021

River Research & Apps

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Climate change has affected the dynamics of the water cycle and its consequent effects on water resources in many regions. The Buyuan River, the largest tributary of the Upper Mekong River, is one of the regions with the strongest climate change in the Mekong River Basin, and its cross‐border impact on water resources has received increasing attention. However, few studies have focused on the runoff responses to future climate change in the Buyuan River Basin (BRB). In this study, the MIKE SHE model was applied to estimate the runoff of the BRB, based on climate‐change scenarios from the Beijing Climate Center Climate System Model (BCC‐CSM1‐1) under two Representative Concentration Pathways (RCPs). The simulations predicted a slight decrease in the mean annual runoff of the BRB under the RCP4.5 and RCP8.5 scenarios (2020–2049) compared with the reference period (1959–2012), with an increase in the magnitude of inter‐annual variation, leading to increased deficit and surplus during dry and wet years. The simulations predicted the earlier maximum monthly runoff and a more evenly distributed annual distribution of the runoff under RCP4.5 and RCP8.5 scenarios as compared to the reference period. The arrival of the flood season in the BRB was advanced by a month under future climate‐change scenarios. The results showed that the average annual runoff of the BRB does not change significantly under future climate‐change scenarios. However, there are obvious changes in the inter‐annual and intra‐annual distribution of the runoff.

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Suitability of a Coupled Hydrologic and Hydraulic Model to Simulate Surface Water and Groundwater Hydrology in a Typical North-Eastern Germany Lowland Catchment

Cited by 19 publications

References 38 publications

An Integrated Hydrological Modelling Approach to Evaluate the Capacity of Keenjhar Lake by Using STELLA

An Integrated Hydrological Modelling Approach to Evaluate the Capacity of Keenjhar Lake by Using STELLA

Optimization of hydrogeological monitoring in the coal-mining region of Western Donbass

Runoff responses to climate change in China's Buyuan River Basin

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