Expansion of unplanned agriculture and urbanization increases the danger of extreme flood and sedimentation. The Upper Awash basin has been under tremendous influence of human activities in the last five decades. The historical land use/land cover (LULC) change analysis was made by processing multi-temporal Landsat images and the future LULC was predicted using the Land Change Modeler. The LULC transition between a pair of classified LULC maps and driver variables were combined to predict the future LULC scenario. The five different LULC change and future land management scenarios are LULC 1974, LULC 2014, increase in the urban area, riparian and steep slope afforestation, and predicted future LULC 2045. The LULC change scenarios together with other spatial and climate data were used to simulate the hydrology, and sedimentation at four main subbasins using the calibrated soil and water assessment tool (SWAT) model. The mean monthly change in the water balance components and sedimentation have indicated higher rates of fluctuation due to LULC change. The riparian and steep slope reforestation scenario has reduced the mean annual surface runoff volume by 9.3% and sedimentation yield by 6.1% from the baseline LULC 2014. Moreover, the frequency of estimated 100-year annual extreme daily discharge reveals significant variation among the LULC scenarios. Notably, the future LULC 2045 has indicated a higher increase of extreme daily discharge by 23.5% at Homole subbasin. The study outlined the impact of land management on the flood events and sedimentation in the large basin, and spatial variation of LULC change impact has been presented. It suggests that the increase in deforestation due expansion of cropland and urbanization will intensify floods, whereas, riparian and steep slope reforestation has significantly reduced the peak discharge and sedimentation. Therefore, the future land management plans should consider appropriate vegetative conservation measures in the upland areas.

In this study, contaminant transport behaviour in the aquifer system (140 m × 180 m × 5 m) was analyzed using a 3-D groundwater flow and contaminant transport model viz. MODFLOW2005 and MT3DMS. The impacts of hydrodynamic dispersion parameters on the conservative contaminant plume dynamics were analyzed for homogeneous and heterogeneous aquifer systems with low permeability porous media (LPPM). The spatio-temporal distribution of contaminant concentration and breakthrough curves (BTCs) at 12 observation wells were used to analyze the transport dynamics due to conservative contaminant released from a single point source over a hypothetical study area for a period of 1 year (365 days). Results from MODPATH show a significant variation in the pathway of groundwater for homogeneous and heterogeneous aquifer systems. During the source loading period, a very low value of concentration of order 10-9 mg/m3 was observed in the LPPM region. The spatial distribution of contaminant plume for aquifer system with LPPM varied largely as compared to homogeneous aquifer system. The maximum value of concentration in the aquifer with LPPM was found to be ~40% higher than the homogeneous system after source removal. After the source removal, the maximum value of 1.98 mg/m3 was observed for the homogeneous system at a location away from pumping and extraction well after 730 days; however, for a heterogeneous system with LPPM, the maximum value of 2.57 mg/m3 was observed. An early breakthrough was observed for αL= 54 m as compared to αL= 9 m for homogeneous aquifer system, clearly depicting the effect of longitudinal dispersivity on BTC. However, effects of dispersivity on the rising and falling limbs of the BTC were negligible for heterogeneous aquifer system with LPPM. Further, an impact of LPPM and longitudinal dispersivity on the peak concentration value at observation well (OBS-7) was undistinguishable. The numerical simulations carried out in this study mimic the realistic heterogeneous aquifer conditions and highlighted the relevance of LPPM and associated transport processes on contaminant transport dynamics at field-scale, which was usually overlooked.