Assessment of Shoreline Changes and the Groundwater Quality along the Coast of Kuakata, Patuakhali, Bangladesh

Goswami, Sukhen; Rahman, Shaikh Ashikur; Alam, Mir Md. Tasnim; Rahman, Mahfuzur; Rafiq, Md. Risalat; Jaman, Md. Hasnat; Roy, Dhiman Kumer

doi:10.12911/22998993/149938

Powiadomienia systemowe

Sesja wygasła!
Sesja wygasła!

Artykuł - szczegóły

Tytuł artykułu

Assessment of Shoreline Changes and the Groundwater Quality along the Coast of Kuakata, Patuakhali, Bangladesh

Autorzy

Goswami Sukhen , Rahman Shaikh Ashikur , Alam Mir Md. Tasnim , Rahman Mahfuzur , Rafiq Md. Risalat , Jaman Md. Hasnat , Roy Dhiman Kumer

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.12911/22998993/149938

Warianty tytułu

Języki publikacji

Abstrakty

Shoreline changes and groundwater quality monitoring have become pressing issues for the coastal region of Bangladesh. This study investigated the shoreline changes from 2000 to 2020 and evaluated the groundwater quality, as well as SWI in the Kuakata coastal area. While analyzing satellite images, the temporal shoreline changes were assessed through the Digital Shoreline Analysis System (DSAS) in ArcGIS 10.4.1. Higher erosion rates (>2 m/year) were found in the southernmost part and the SE part of the studied area. Twenty-five groundwater samples were collected, and the physicochemical parameters were measured to assess the groundwater quality. The geographic information system (GIS) was used to assess the spatial variation of the EC, pH, and Cl⁻ contents through the inverse distance weighted (IDW) interpolation method. The EC, Cl⁻, and pH values of the studied groundwater ranged from (1.2 mS/cm to 19.5 mS/cm), (79.88 mg/L to 11241.67 mg/L), and (7.9 to 8.7), repectively. The analysis revealed that the majority of the groundwater samples were unsuitable for drinking purpose due to higher EC and Cl⁻ values. Saline water intrusion (SWI) was determined by using the alternative EC vs Cl⁻ method in the southern part of the Kuakata beach area, which was closest to the sea.

Słowa kluczowe

saline water intrusion hydrogeochemical analysis digital shoreline analysis system salinity

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2022

Tom

Vol. 23, nr 7

Strony

323--332

Opis fizyczny

Bibliogr. 52 poz., rys., tab.

Twórcy

autor

Goswami Sukhen

Department of Geology and Mining, Faculty of Science and Engineering, University of Barishal, Barishal, 8254, Bangladesh

autor

Rahman Shaikh Ashikur

Department of Geology and Mining, Faculty of Science and Engineering, University of Barishal, Barishal, 8254, Bangladesh

autor

Alam Mir Md. Tasnim

Palli Karma-Sahayak Foundation, Dhaka, 1207, Bangladesh

autor

Rahman Mahfuzur

Department of Oceanography, Faculty of Science, Noakhali Science and Technology University, Noakhali, 3814, Bangladesh

autor

Rafiq Md. Risalat

Department of Geology and Mining, Faculty of Science and Engineering, University of Barishal, Barishal, 8254, Bangladesh

autor

Jaman Md. Hasnat

Department of Geology and Mining, Faculty of Science and Engineering, University of Barishal, Barishal, 8254, Bangladesh

autor

Roy Dhiman Kumer

dhimans14@yahoo.com

Department of Geology and Mining, Faculty of Science and Engineering, University of Barishal, Barishal, 8254, Bangladesh

https://orcid.org/0000-0002-6968-2578

Bibliografia

1. Adhikari D.K., Roy M.K., Datta D.K., Roy P.J., Roy D.K., Malik A.R., Alam A.B. 2006. Urban geology: a case study of Khulna city corporation, Bangladesh. Journal of Life and Earth Science, 1(2), 17–29.
2. Aggarwal P.K., Basu A.R., Poreda R.J. 2000. A Report on Isotope Hydrology of Groundwater in Bangladesh: Implications for Characterization and mitigation of Arsenic in Groundwater. Dec 2000; 65 p; IAEA TC Project BGD/8/016. http://ripcnt01.iaea.org/ih/publications/BGD_Report
3. Ahmed A.U. 2006. Bangladesh climate change impacts and vulnerability. Comprehensive Disaster Management Programme (CDMP), Government of the People’s Republic of Bangladesh.
4. Alam M.Z., Carpenter-Boggs L., Mitra S., Haque M.M., Halsey J., Rokonuzzaman M., Saha B., Moniruzzaman M. 2017. Effect of Salinity Intrusion on Food Crops, Livestock, and Fish Species at Kalapara Coastal Belt in Bangladesh. Journal of Food Quality, 1–23.
5. Bahar M.M., Reza M.S. 2010. Hydrochemical characteristics and quality assessment of shallow groundwater in a coastal area of southwest Bangladesh. Environmental Earth Sciences, 61(5), 1065–1073.
6. Bangladesh Bureau of Statistics (BBS). 2011. Statistical Yearbook of Bangladesh, Govt. of the People’s Republic of Bangladesh.
7. Bangladesh Bureau of Statistics (BBS). 2011. Patuakhali district statistics, Govt. of the People’s Republic of Bangladesh.
8. Bangladesh Meteorological Department (BMD), 2020. Government of the Peoples Republic of Bangladesh. http://datalibrary.bmd.gov.bd/
9. BGS and DPHE. 2001. Arsenic contamination of groundwater in Bangladesh, British Geological Survey Technical Report WC/00/19, 4.
10. Brammer H. 2014. Bangladesh’s dynamic coastal regions and sea-level rise. Climate Risk Management, 1, 51–62.
11. BWDB. 2013. Hydrogeological study and mathematical modelling to identify sites for installation of observation well nests, Main Report. Bangladesh Water Development Board (BWDB) and Institute of Water Modelling (IWM).
12. Chand P., Acharya P. 2010. Shoreline change and sea level rise along coast of Bhitarkanika wildlife sanctuary, Orissa: An analytical approach of remote sensing and statistical techniques. International journal of geomatics and geosciences, 1(3), 436–455.
13. Detay M., Carpenter M.N.S. 1997. Water wells: implementation, maintenance and restoration (p. 379P). London: Wiley.
14. Elango L., Kannan, R. 2007. Rock–water interaction and its control on chemical composition of groundwater. Developments in environmental science, 5, 229–243.
15. Eutech Instruments. 1997. Conductivity to TDS conversion factors. http://www.eutechinst.com/techtips/tech-tips40.htm Accessed: February 19, 2014.
16. Ghosh M.K., Kumar L., Roy C. 2015. Monitoring the coastline change of Hatiya Island in Bangladesh using remote sensing techniques. ISPRS J. Photogram. Remote Sensing, 101, 137–144.
17. Hem J.D. 1991. Study and interpretation of the chemical characteristics of natural waters, 3rd edn. Scientific Publishers, Jodhpur Book, 2254.
18. Hussain M.S., Abd-Elhamid H.F., Javadi A.A., Sherif M.M. 2019. Management of Seawater Intrusion in Coastal Aquifers: A Review. Water, 11, 2467.
19. Islam M.A., Hossain M.S., Murshed S. 2015. Assessment of coastal vulnerability due to sea level change at Bhola Island, Bangladesh: using geospatial techniques. Journal of the Indian Society of Remote Sensing, 43(3), 625–637.
20. Islam S.M., Majumder R.K., Uddin M.J., Khalil M., Ferdous Alam M. 2017. Hydrochemical characteristics and quality assessment of groundwater in Patuakhali district, southern coastal region of Bangladesh. Exposure and health, 9(1), 43–60.
21. Khalil M.I., Majumder R.K., Islam S.M.D., Uddin M. 2016. Geophysical Investigation for Groundwater Exploration and Quality Assessment in Coastal Area of Kalapara, Patuakhali. International Water Conference, March 13–16, 2016, Sultan Quabbos University, Oman.
22. Khalil M.T., Islam S.M.D., Uddin M.J., Majumder R.K. 2020. Coastal Groundwater Aquifer Characterization from Geoelectrical Measurements — A Case Study at Kalapara, Patuakhali, Bangladesh. Journal Of Applied Geology, 5(1), 1–12.
23. Lo K.F.A., Gunasiri C.W.D. 2014. Impact of coastal land use change on shoreline dynamics in Yunlin County, Taiwan. Environments, 1(2), 124–136.
24. Lee H.S. 2013. Estimation of extreme sea levels along the Bangladesh coast due to storm surge and sea-level rise using EEMD and EVA. Journal of Geophysical Research: Oceans, 118, 4273–4285.
25. Luo W., Gao X., Zhang X. 2018. Geochemical processes controlling the groundwater chemistry and fluoride contamination in the yuncheng basin, China—an area with complex hydrogeochemical conditions. PLoS ONE, 13(7), 1–25.
26. Mahmuduzzaman Md., Ahmed Z.U., Nuruzzaman A.K.M., Rabbi F., Ahmed S. 2014. Causes of Salinity Intrusion in Coastal Belt of Bangladesh. International Journal of Plant Research, 4(4A), 8–13.
27. MoWR. 2005. The national coastal zone policy. Ministry of Water Resources, Dhaka, Bangladesh.
28. Patra S., Satiprasad S., Mishra P., Chandra S. 2018. Impacts of Urbanization on Land Use / Cover Changes and Its Probable Implications on Local Climate and Groundwater Level. Journal of Urban Management, 7(2), 70–84.
29. Preda M., Cox M.E. 2000. Sediment-water interaction, acidity and other water quality parameters in a subtropical setting, Pimpama River, southeast Queensland. Environmental Geology, 39(3–4), 319–329.
30. Rahman M., Islam M. 2019. Scarcity of Safe Drinking Water in the South-West Coastal Bangladesh. Journal of Environmental Science and Natural Resources, 11(1–2), 17–25.
31. Rahman M., Tushar M.A.N., Zahid A., Mustafa M.G., Siddique M.A.M., Ahmed K.M., 2021. Spatial distribution of manganese in groundwater and associated human health risk in the southern part of the Bengal Basin. Environmental Science and Pollution Research, 28(30), 41061–41070.
32. Rahman M., Khan M.S.I., Hossain M.S., Hossain M.I.S., Hasan M., Hamli H., Mustafa M. G. 2022. Groundwater Contamination and Health Risk Evaluation of Naturally Occurring Potential Toxic Metals of Hatiya Island, Bangladesh. Journal of Ecological Engineering, 23(6), 223–236.
33. Salauddin M., Hossain K.T., Tanim I.A., Kabir M.A., Saddam M.H., 2018. Modeling Spatio-Temporal Shoreline Shifting of a Coastal Island in Bangladesh Using Geospatial Techniques and DSAS Extension. Annals of Valahia University of Targoviste, Geographical Series, 18(1), 1–13.
34. Sarker M.R., Camp M.H., Islam M., Ahmed N., Walraevens K., 2018. Hydrochemistry in Coastal Aquifer of Southwest Bangladesh: Origin of Salinity. Environmental Earth Science, 77(2), 1–20.
35. Sarwar M.G.M., Woodroffe C.D. 2013. Rates of shoreline change along the coast of Bangladesh. Journal of Coastal Conservation, 17(3), 515–526.
36. Saxena V.K., Singh V.S., Mondal N.C., Jain S.C. 2003. Use of hydrochemical parameters for the identification of fresh groundwater resources, Potharlanka Island, India. Environmental Geology, 44 (5), 516–21.
37. Shammi M., Rahman M.M., Bondad S.E., Bodrud-Doza M. 2019. Impacts of Salinity Intrusion in Community Health: A Review of Experiences on Drinking Water Sodium from Coastal Areas of Bangladesh. Healthcare, 7(1), 50.
38. Shamsudduha M., Zahid A., Burgess W.G. 2019. Security of deep groundwater against arsenic contamination in the Bengal Aquifer System: a numerical modeling study in southeast Bangladesh. Sustainable Water Resources Management, 5(3), 1073–1087.
39. Shibly A.M., Takewaka, S. 2012. Morphological changes along Bangladesh coast derived from satellite images. Proceedings of Coastal Engineering, 3, 41–45.
40. Singh S., Raju N., Ramakrishna C. 2015. Evaluation of Groundwater Quality and Its Suitability for Domestic and Irrigation Use in Parts of the Chandauli-Varanasi Region, Uttar Pradesh, India. Journal of Water Resource and Protection, 7, 572–587.
41. Sreekesh S., Sreerama Naik S.R., Rani S. 2018. Effect of Sea Level Changes on the Groundwater Quality along the Coast of Ernakulam District, Kerala. Journal of Climate Change, 4(2), 51–65.
42. Subhani R., Ahmad M. 2019. Socio-economic impacts of cyclone Aila on migrant and non-migrant households in the southwestern coastal areas of Bangladesh. Geoscience, 9(11), 482.
43. Thieler E.R., Himmelstoss E.A., Zichichi J.L., Ergul A. 2009. The Digital Shoreline Analysis System (DSAS) Version 4.0 - An ArcGIS extension for calculating shoreline change. Open-File Report, 2008-1278.
44. Todd D.K. 1980. Groundwater hydrology. Wiley, New York, 10–138.
45. The Washington State Department of Ecology. 2005. Water Resource Inventory Area 06 Islands. Seawater Intrusion Topic Paper.
46. Uddin A.M.K., Kaudstaal R. 2003. Delineation of the coastal zone. Integrated Coastal Zone Management Plan (PDO-ICZMP), 1–42.
47. UNDP. 2019. Sea level rise hits Bangladesh islanders hard. February 2019. https://www.bd.undp.org/content/bangladesh/en/home/presscenter/articles/2019/02/Sea_level_rise_hits_islanders.html
48. WHO (World Health Organisation). 1993. Guidelines for drinking water quality, vol. 1, 2nd edn, Recommendations, WHO, Geneva, 130
49. WHO (World Health Organization). 1993. Guidelines for drinking-water quality, 4th edn. World Health Organization, WHO, Geneva.
50. World Bank. 2014. River Salinity and Climate Change Evidence from Coastal Bangladesh, (March).
51. Woobaidullah A.S.M., Hasan M.A., Reza M.H., Noor A., Amin M.K. 2006. Groundwater potentiality-a review of the hydrogeological data available in the coastal belt of Khulna and Satkhira districts. Dhaka University Journal of Science, 42, 229–233.
52. Zahid A., Hassan M., Imes J.L., Clark D.W. 2011. Hydraulic characterization of aquifer(s) and pump test data analysis of deep aquifer in the arsenic affected meghna river floodplain of Bangladesh. Environmental Research Journal, 13, 325–355.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-c286aa24-4572-401b-be8a-d08a2e5ac595