Archives
 
Year 2020
 
Vol 61, Issue 4, [08 - 2020]

Morphometric analysis of Vu Gia - Thu Bon using GIS

DOI:10.46326/JMES.2020.61(4).03

  • Affiliations:

    1 Faculty of Surveying, Mapping and Geographic Information , Hanoi University of Natural resources and Environment, Vietnam
    2 Faculty of Geomatics and Land Administration, Hanoi University of Mining and Geology, Vietnam

  • *Corresponding:
    This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Received: 21st-June-2020
  • Revised: 29th-July-2020
  • Accepted: 31st-Aug-2020
  • Online: 31st-Aug-2020
Pages: 25 - 35
Views: 2043
View onlineView online
Downloads: 997
Downdload PDF
Rating: 5.0, Total rating: 99
Yours rating

Abstract:

The Vu Gia - Thu Bon river basin is one of the largest basins in Vietnam. Research and assessment of this potential basin is a great interest to scientists and regulators. One of the important studies is the evaluation of morphological parameters of the basin. The morphological parameters represent water resources and at the same time are one of the factors that help researchers give a comprehensive view of the basin, assessing the factors related to the direction of the flow, the flow rate or hazards throughout the basin. Therefore, this paper is an attempt to evaluate the morphology of Vu Gia - Thu Bon river basin using DEM SRTM (30 m) data in GIS. This analysis can be achieved through the measurement of linear aspects, aerial aspects and relief aspects of the drainage basin. The results of the study show that stream order ranges from first to sixth order with a total stream length of 1024, a total length of 3183.2 km. Basin was divided into three subregions: upland, midland, and lowland. Those represent 66,9%, 26,0% and 7,1% percent of the region’s total area respectively.

How to Cite
Trinh, T.Hoai Thi, Bui, D.Thuy Thi, Nguyen, N.Viet and Dao, H.Mai 2020. Morphometric analysis of Vu Gia - Thu Bon using GIS (in Vietnamese). Journal of Mining and Earth Sciences. 61, 4 (Aug, 2020), 25-35. DOI:https://doi.org/10.46326/JMES.2020.61(4).03.
References

Biswas, S., Sudhakar, S. and Desai, V. R., (1999). Prioritisation of Sub-watersheds based on Morphometric Analysis of Drainage Basin: A Remote Sensing and GIS Approach. Journal of the Indian Society of Remote Sensing 27 (3), 155-166.

Burhan Niyazi, Syed Zaidi and Milad Masoud, (2019). Comparative Study of Different Types of Digital Elevation Models on the Basis of Drainage Morphometric Parameters (Case Study of Wadi Fatimah Basin, KSA). Earth Systems and Environment 3, 539-550.

Cannon, J. P., (1976). Generation of explicit parameters for a quantitative geomorphic  study of the Mill Creek Drainage Basin. Oklahoma Geology notes 36(1), 13-17.

Chorley, R. J., Donald-Malm E. G. and Pogorzelski H. A, (1957). A new standard for estimating drainage basin shape. American Journal of Science 255(2), 138-141.

Chorley, R. J., (1969). Introduction to fluvial processes. London: Methuen and Co. Limited (Pub.), 588.

Gardiner, V., (1975). Drainage Basin Morphometry. British Geomorphological Research Group Technical Bulletin 14, 48-50.

Gregory, K. J. and Walling, D. E., (1973). Drainage basin form and processes: A geomorphological approach. E. Arnold, ed. New York: Halsted Press. 456.

Hadley R. F. and Schumm S. A., (1961). Sediment sources and drainage basin characteristics in upper Cheyenne River Basin. U.S. Geological Survey Water-Supply Paper. 1531-B, 198.

Horton, R. E., (1932). Drainage‐basin characteristics. Eos. Transactions American Geophysical Union 13(1), 350-361

Horton, R. E., (1945). Erosional development of streams and their drainage basins; hydrophysical approach to quantitative morphology. Geological Society of America 56, 275-370.

Ibrahim Bathis. K. and S. A. Ahmed, S. A., (2014). Evaluation of Morphometric Parameters - A comparative study from Cartosat DEM, SRTM and SOI Toposheet in Karabayyanahalli sub-watershed, Karnatak., International Journal of Research (IJR) 1(11).

Jenks George, F., (1967). The Data Model Concept in Statistical Mapping. International Yearbook of Cartography 7. 186-190.

Krishnamurthy J., Srinivas G., Jayaram V., Chandrasekhar M. G., (1996). Influence of rock type and structure in the development of drainage networks in typical hard rock terrain. ITC J 3/4, 252-259.

Leilei Li, Jintao Yang and Jin Wu, (2019). A Method of Watershed Delineation for Flat Terrain Using Sentinel-2A Imagery and DEM: A Case Study of the Taihu Basin. International Journal of Geo - Information 8, 258.

Moore, I. D., Grayson, R. B., Ladspm, A. R., (1991). Digital terrain modelling: a review of hydrological, geomorphological and biological applications. Hydrol Process 5, 3-30.

Nag, S. K. and Chakraborty, S., (2003). Influence of rock types and structures in the development of drainage network in hard rock area. Journal of the Indian Society of Remote Sensing 31 (1), 25-35.

Nagaraju, D., Siddalingamurthy, D., Balasubramanian, S., Lakshmamma, A. and Sumithra S., (2015). Morphometric analysis of Byramangala Watershed, Bangalore Urban District, Karnataka, India. International Journal of Current Engineering and Technology 5(3).

Ngô Đạt Tam, Nguyễn Quý Thao, (2018). Atlat địa lý Việt Nam. Nhà xuất bản giáo dục Việt Nam.

Nisha Sahu, G. P. Obi Reddy, Nirmal Kumar, M. S. S. Nagaraju, Rajeev Srivastava and S. K. Singh., (2017). Morphometric analysis in basaltic Terrain of Central India using GIS techniques: a case study. Applied Water Science 7, 2493-2499.

Pakhmode, V., Kulkarni H., and Deolankar S., (2003). Hydrological-drainage analysis in watershed-programme planning: a case from the Deccan basalt, India. Hydrogeology Journal 11(5), 595-604.

Putty, M. R. Y., (2007). Quantitative geomorphology of the upper Kaveri basin in Western Ghats, in Karnataka. IE(I) Journal-CV 88, 44-49.

Reddy, G. P. O., Maji A. K., and Gajbhiye K. S. (2004). Drainage morphometry and its influence on landform characteristics in a basaltic terrain, Central India-a remote sensing and GIS approach. International Journal of Applied Earth Observation and Geoinformation 6(1), 1-16.

Schumm, S. A., (1956). Evolution of drainage systems and slopes in badlands at Perth Amboy, New Jersey. Geological Society of America Bulletin 67, 597- 646

Schumm, S. A., (1963). Sinuosity of alluvial rivers on the Great Plains. Geological Society of America Bulletin. 74, 1089-1100.

Singh, S. and Singh, M. C. (1997). Morphometric Analysis of Kanhar River Basin. National Geographical Journal of India, 43 (1), 31-43.from the Gagas River Basin, India. Journal Geological Society of India 77, 160-166.

Smith, K. G., (1950). Standards for grading textures of erosional topography. American Journal of Science 248, 655-668.

Strahler, A. N., (1964). Quantitative geomorphology of drainage basins and channel networks. Handbook of Applied Hydrology. McGraw-Hill. New York, 4-11

TCVN 9845, (2013). Tiêu chuẩn quốc gia. Tính toán các đặc trưng dòng chảy lũ.

Thông tư số 12 /2014/TT-BTNMT. Quy định kỹ thuật điều tra, đánh giá tài nguyên nước mặt.

Trần Văn Tình, (2013). Xây dựng bản đồ ngập lụt vùng hạ lưu lưu vực sông Vu gia - Thu bồn. Luận văn thạc sĩ. Trường đại học Khoa học Tự nhiên.

Vincy, M. V., Brilliant Rajan, M. V.,  and Pradeepkumar A. P., (2012). Geographic information system-based morphometric characterization of sub-watersheds of Meenachil river basin, Kottayam district, Kerala, India. Geocarto International.

Zaidi, F. K., (2011). Drainage Basin Morphometry for Identifying Zones for Artificial Recharge: A Case Study.