ASSESSMENT OF SEDIMENT REPLENISHMENT VOLUME IN LANGAT RIVER SYSTEM
Main Article Content
Abstract
The river sand mining activity has taken place in a sand-bed river system in Selangor, Malaysia for decades even before the legalisation was initiated in 2008. This study focuses on the determination of optimum sand extraction for low-flow and high-flow seasons. The sand replenishment rate was used as the benchmark in determining the threshold level of the extractable rate in the Langat River, Selangor system. The total sediment load was computed using Yang (1973) equation due to the high percentage of agreement between the predicted sediment load and measured sediment load. Almost 41.6% of the predicted data fall within the allowable discrepancy ratio test between the predicted value and measured value. The comparison of sand replenishment rate in high and low flow seasons proved that the river system has quicker capabilities in sand replenishment rate at the extraction point during the high-flow season compared to the latter by 83%. The quantifiable volume of the extractable sand rate is proposed specifically during low-flow months (May to September) whereby the slower replenishment rate is critical and riskier. The optimal sand mining volume during the low-flow months is calculated by reducing 10% from the total replenishment volume and the recommended optimum extraction load has been delivered by the number of 25 tons lorries for easier observation by the contractor and authority’s body. The monthly optimum extraction in Langat River during low-flow months is calculated at a minimum of 437 trucks to a maximum of 20,114 trucks per month.
Downloads
Article Details
Transfer of Copyrights
- In the event of publication of the manuscript entitled [INSERT MANUSCRIPT TITLE AND REF NO.] in the Malaysian Journal of Science, I hereby transfer copyrights of the manuscript title, abstract and contents to the Malaysian Journal of Science and the Faculty of Science, University of Malaya (as the publisher) for the full legal term of copyright and any renewals thereof throughout the world in any format, and any media for communication.
Conditions of Publication
- I hereby state that this manuscript to be published is an original work, unpublished in any form prior and I have obtained the necessary permission for the reproduction (or am the owner) of any images, illustrations, tables, charts, figures, maps, photographs and other visual materials of whom the copyrights is owned by a third party.
- This manuscript contains no statements that are contradictory to the relevant local and international laws or that infringes on the rights of others.
- I agree to indemnify the Malaysian Journal of Science and the Faculty of Science, University of Malaya (as the publisher) in the event of any claims that arise in regards to the above conditions and assume full liability on the published manuscript.
Reviewer’s Responsibilities
- Reviewers must treat the manuscripts received for reviewing process as confidential. It must not be shown or discussed with others without the authorization from the editor of MJS.
- Reviewers assigned must not have conflicts of interest with respect to the original work, the authors of the article or the research funding.
- Reviewers should judge or evaluate the manuscripts objective as possible. The feedback from the reviewers should be express clearly with supporting arguments.
- If the assigned reviewer considers themselves not able to complete the review of the manuscript, they must communicate with the editor, so that the manuscript could be sent to another suitable reviewer.
Copyright: Rights of the Author(s)
- Effective 2007, it will become the policy of the Malaysian Journal of Science (published by the Faculty of Science, University of Malaya) to obtain copyrights of all manuscripts published. This is to facilitate:
- Protection against copyright infringement of the manuscript through copyright breaches or piracy.
- Timely handling of reproduction requests from authorized third parties that are addressed directly to the Faculty of Science, University of Malaya.
- As the author, you may publish the fore-mentioned manuscript, whole or any part thereof, provided acknowledgement regarding copyright notice and reference to first publication in the Malaysian Journal of Science and Faculty of Science, University of Malaya (as the publishers) are given. You may produce copies of your manuscript, whole or any part thereof, for teaching purposes or to be provided, on individual basis, to fellow researchers.
- You may include the fore-mentioned manuscript, whole or any part thereof, electronically on a secure network at your affiliated institution, provided acknowledgement regarding copyright notice and reference to first publication in the Malaysian Journal of Science and Faculty of Science, University of Malaya (as the publishers) are given.
- You may include the fore-mentioned manuscript, whole or any part thereof, on the World Wide Web, provided acknowledgement regarding copyright notice and reference to first publication in the Malaysian Journal of Science and Faculty of Science, University of Malaya (as the publishers) are given.
- In the event that your manuscript, whole or any part thereof, has been requested to be reproduced, for any purpose or in any form approved by the Malaysian Journal of Science and Faculty of Science, University of Malaya (as the publishers), you will be informed. It is requested that any changes to your contact details (especially e-mail addresses) are made known.
Copyright: Role and responsibility of the Author(s)
- In the event of the manuscript to be published in the Malaysian Journal of Science contains materials copyrighted to others prior, it is the responsibility of current author(s) to obtain written permission from the copyright owner or owners.
- This written permission should be submitted with the proof-copy of the manuscript to be published in the Malaysian Journal of Science
References
Abidin R. Z., Sulaiman M.S., and Yusoff N., (2017). Erosion risk assessment: A case study of the Langat River bank in Malaysia. Int. Soil Water Conserv. Res., 5, 26-35.
Ashraf M. A., Maah M. J., Yusoff I., Wajid A., and Mahmood K., (2011). Sand mining effects, causes and concerns: A case study from Bestari Jaya, Selangor, Peninsular Malaysia. Sci. Res. Essays., 6, 1216–1231.
Ashraf M.A., Maah M.J. and Yusoff I. (2012) Chemical speciation and potential mobility of heavy metals in the soil of former tin mining catchment. The Scientific World Journal 2012: 1-11.
Collins A. L., Naden P. S., Sear D. A., Jones J. I., Foster I. D. L., and Morrow K., (2011). Sediment targets for informing river catchment management. Int. Experience Prospect Hydrol. Processes.25, 2112–2129.
Dunne T., and Leopold L. B., (1978) Water in Environmental Planning. W.H. Freeman and Co., San Francisco, 818.
Engelund F., and Hansen E., (1967). A monograph on sediment transport in alluvial streams. Copenhagen: Danish Technical Press.
Fang Y. T., Ab. Ghani A., and Chang K. C., (2017). River sand mining capacity in Malaysia. Proceedings of the 37th IAHR World Congress August 13 – 18, 2017, Kuala Lumpur, Malaysia, 538-546.
Follman E. H., (1980) Interdisciplinary overview of gravel removal. In: Woodward-Clyde Consultants, ed. Gravel removal studies in arctic and subarctic floodplain in Alaska - technical report, 331-384.
Hafifi M., Nazir M., Awang S., Shaaban A. J., Khan N., Azman E. M. Y., and Ghani A. A., (2015). Sediment transport dynamic in a meandering fluvial system: case study of Chini River. Soft Soil Eng. Inter. Conf. 2015 (SEIC2015)
Jinshan L. B., and Liangjun F. B., (2017). Particle size distribution and settling velocity of sediments in water diverted from the Yellow River during border-strip irrigation. Tecnología y Ciencias del Agua, 8, 31-41.
Julien, P. (2002) , River Mechanics, Cambridge University Press, 58-59.
Kiat C.C., Ab Ghani A., Azazi Z. N., Abu Hasan Z., Abdullah R., (2005). Sediment transport equation assessment for selected rivers in Sediment transport equation assessment for selected rivers in Malaysia. Intl. J. River Basin Manage. 33, 203–208.
Kondolf G. M. (1994) Geomorphic and environmental effects of instream gravel mining. Landscape Urban Plann.,28, 225-243.
Kondolf, G. M. (1997) Hungry water: effects of dams and gravel mining on river channels. Journal Environ. Manage. 21, 533-551.
Kondolf G.M., Smeltzer M. and Kimball L., (2002) Freshwater gravel mining and dredging Issues. Herrera Environmental Consultants.
Lai F. S., Lee M. J., and Rizal S. M. (1995). Changes in sediment discharge resulting from commercial logging in the Sungai Lawing basin , Selangor , Malaysia. Proceedings of a Boulder Symposium.226, 55–62
Leopold L.B. and Maddock T., (1953). The hydraulic geometry of stream channels and some physiographic implication.
Leopold L.B., and Maddock T., (1953). The hydraulic geometry of stream channels and some physiographic implications. United States Geological Survey, Professional Paper 252, Washington, DC., USA., pp: 57.
Lu X. X., Zhang S. R., Xie S. P., and Ma P. K. (2007). Rapid channel incision of the lower Pearl River (China) since the 1990s as a consequence of sediment depletion. Hydrol. Earth Syst. Sci.,11, 897-1906.
Malaysian Minerals Yearbook 2013, (2014). Kuala Lumpur: Minerals and Geoscience Department Malaysia.
Mattamana B. A., Varghese S., and Kichu P., (2013). River Sand Inflow Assessment and Optimal Sand mining policy Development. Int. J. Emergency Technol. Adv., Eng. 3, 305-317.
Mebust C. M. (2015). Analysis of Sedimentation Characteristics of Dredge Sediment Used in Coastal Restoration and Marsh Creation Projects. Retrieved from https://scholarworks.uno.edu/td/1988
Memarian H., Balasundram S. K., Talib J. B., Sood A. M., Abbaspour C., Memarian H., and Sood A. M. (2012). Trend analysis of water discharge and sediment load during the past three decades of development in the Langat basin, Malaysia. Hydrol. Sci. J., 57, 1207-1222.
Milliman J. D. (2010). River Inputs. In Encyclopedia of Ocean Sciences.
Mmom P. C., Chukwu-Okeah G. O., (2012). Sand dredging and river morphology change along parts of new calabar river in Akpor area of rivers state, Nigeria and its implications for biological resource conservation. Res. J. Environ. Earth Sci.,4, 82–87.
Mohamed A. F., Yaacob W. Z., Mohd R. T., Abdul M. S., (2009). Groundwater and soil vulnerability in the Langat Basin Malaysia. Eur. J. Sci. Res., 27, 628–635.
Nguyen M. D, and Phuong L. N. (2015). An analysis of river sand mining management in Cau River of Vietnam. Asian J. Res. Bus. Eco. Manage. 5, 19-32
Peck Y. T., and Rohasliney H., (2013). Status of water quality subject to sand mining in the Kelantan River, Kelantan. Trop. Life Sci. Res.,24, 19-34.
Petts G. E. and Foster I., (1985) Channel Morphology. In: Rivers and Landscape, Edward Arnold, London.
Pitchaiah P. S., (2017). Impacts of sand mining on environment – A Review. SSRG Int. J. Geoinformatics Geological Sci., 4, 1-5.
Pike A. S., Scatena F. N., and Wohl E. E., (2010). Lithological and fluvial controls on the geomorphology of tropical montane stream channels in Puerto Rico. Earth Surf. Process. Landforms, 35, 1402–1417.
Pourebrahim, S., Hadipour, M. & Mokhtar, M.B. (2015). Impact assessment of rapid development on land use changes in coastal areas; case of Kuala Langat district, Malaysia. Environ Dev Sustain 17, 1003–1016.
Ra M. M. P., Haynes H., and Hoey T.B., (2012). The spatial distribution of coarse surface grains and the stability of gravel river beds. In. Ass. Sediment., 59(3) : 1014-1029
Rinaldi M., Wyżga B. and Surian N. (2005). Sediment mining in alluvial channels: physical effects and management perspectives. River Research and Applications, 21(7): 805-828.
Rosgen D. L., (1994). A stream channel stability assessment methodology. Proceedings of the Seventh Federal Interagency Sedimentation Conference.
Sulaiman, M. S., Sinnakaudan, S. K., Azhari, N. N., & Abidin, R. Z. (2017). Behavioral of sediment transport at lowland and mountainous rivers: a special reference to selected Malaysian rivers. Environmental Earth Sciences, 76(7), 300. doi:10.1007/s12665-017-6620-y
Saudi A. S. M., Juahir H., Azid A., Toriman M. E., Kamarudin M. K. A., Mustafa A. D. and Amran M. A. (2015). Flood risk pattern recognition by using environmetric technique: A case study in Langat river basin. Jurnal Teknologi, 77(1): 145–152.
Sharma, A.; Kumar, B.; Oliveto, G., (2021) Experimental Study on the Near-Bed Flow Characteristics of Alluvial Channel with Seepage. Appl. Sci., 11, 9619.
Surian N., and Rinaldi M., (2003). Morphological response to river engineering and management in alluvial channels in Italy. Geomorphology, 50: 307-326.
State of River Report, Sungai Langat (2015), Lembaga Urus Air Selangor (LUAS).
Toriman M. E., (2008). Developing a conceptual model of geomorphic change for channel management proposes. Jurnal e-Bangi, 3: 1-12.
Van Rijn L. C., (1993). Simple general formulae for sand transport in rivers, estuaries and coastal waters. van Rijn, L. C. (2013). Coastal Waters. Retrieved Feb 4, 2014. Retrieved from www.leovanrijn-sediment.com
Wu G., Leeuw J. D., Skidmore A. K., Prins H. H. T., and Liu Y., (2007). Concurrent monitoring of vessels and water turbidity enhances the strength of evidence in remotely sensed dredging impact assessment. Water Res., 41(15): 3271–3280.
Yang C. T., (1973). Incipient motion and sediment transport. Proc. ASCE, 99(11): 1679-1704.
Yang C. T., and Randle, T. J., (2006). Erosion and sedimentation manual U.S. Department of the Interior, Bureau of Reclamation, Technical Service Center, Sedimentation and River Hydraulics Group, Denver, Colorado November 2006.
Yang H. H., Jaafar O., El-shafie,A. and Abdullah S. M. S., (2011). Impact of land-use changes toward base-flow regime in Lui and Langat Dengkil sub-basin. International Journal of the Physical Sciences Vol. 6:21. Pp. 4960-4976.