ASSESSMENT OF SALT WATER INTRUSION IN THE SOUTH WESTERN COASTAL AQUIFERS OF KHULNA BY USING VISUAL MODFLOW

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dc.contributor.author AHSAN, NAFIZ UL
dc.date.accessioned 2019-04-18T03:16:53Z
dc.date.available 2019-04-18T03:16:53Z
dc.date.issued 2019-04
dc.identifier.uri http://hdl.handle.net/123456789/447
dc.description First of all I express my highest praise to the omnipresent, omnipotent and omniscient Allah who has enabled me to complete this thesis work. I would then like to express my sincerest gratitude to my thesis supervisor Prof. Md. Tauhid Ur Rahman for his continuous support to my M.Sc. study and related research and for his patience, motivation, inspiration and above all immense knowledge. His guidance has helped me always during the research and the writing of this thesis. I could never imagine having a better advisor and mentor than him for my M.Sc. study. I am very grateful to my parents and especially to my spouse Dr. Zannatul Habiba, who have provided me with morale and inspirational support in my work. I am also grateful to my other family members and friends who have supported me along the way. A very special gratitude goes to Higher Education Quality Enhancement Project (HEQEP) at MIST for the technical and financial support and also to the Ministry of Science and Technology for funding the work by awarding R&D grant scheme 2016-17. I am also deeply indebted to Anjuman Anju, Md Arman Habib, the data collection team, HEQEP team and EWCE Dept of MIST for their great cooperation in general. And finally, last but by no means least, I pay my heartiest thanks to everyone in the Climate Change lab. Nafiz Ul Ahsan en_US
dc.description.abstract The objective of the study is to investigate the salinity intrusion status of groundwater using visual MODFLOW in the study area (Khulna) and salinity transport scenario in the coastal aquifers. The model domain covers an area of approximately 350 km² in 40m X 40m grid size and defined by three hydro-stratigraphic layers. To set up model fluid transfer boundary of Northern and Southern sides‘ ground water levels from observed wells and surface water level of various ponds were used. For Eastern and Western boundaries water level of the river Shibsa and Rupsha were used respectively. The observed groundwater levels from the wells were used as a boundary condition for deeper aquifer. Model base represents impermeable boundary and model top represents recharge boundary. Beside this the concentration of different rivers was used as mass transfer boundary condition for upper shallow aquifer. Other than upper shallow aquifer no concentration boundary was used. Recharge due to infiltration of rainfall in the catchment area was estimated to the range between 8% to 12% of rain fall. The value of Kx and Ky is assigned 2.5x10-4 cm/s to the entire aquifer. In this case the Kx and Ky are the same indicating that the assigned property values are horizontally and vertically isotropic. In these three layer models, layer 1 represents the upper aquifer and layer 3 represents the lower aquifer. Layer 2 represents the aquitard separating the upper and lower aquifers. In the model for contamination transport (salinity) MT3DMS engine was used and also upstream finite difference solution method with the implicit GCG solver. It provides a stable solution to the contaminant transport model in a relatively short period of time. The distribution of salinity was simulated for a period of twenty years in terms of chloride concentration. Through the representation of the salinity model in MODFLOW the salinity concentration in the sub-surface layers appears to increase by about 3.75 times in a span of 20 years due to the occurrence of surface water-groundwater interaction. Present salinity concentration has a value of nearly 800-2200 mg/L while in another two years in 2020 the concentration is expected to reach a maximum of approximately 3200 mg/L. The salinity model developed in MODFLOW was checked for stability using Courant number and it was found that with the increase in time step Courant number also increases which marks the stability of the model. The model was further validated using field data collected in 2013 for the study area and the model data for 2013 in the same location. The salinity data from the field and the model has striking similarities. en_US
dc.language.iso en en_US
dc.publisher DEPARTMENT OF CIVIL ENGINEERING en_US
dc.title ASSESSMENT OF SALT WATER INTRUSION IN THE SOUTH WESTERN COASTAL AQUIFERS OF KHULNA BY USING VISUAL MODFLOW en_US
dc.type Thesis en_US


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