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Impact of Landslides Induced by the 2018 Palu Earthquake on Flash Flood in Bangga River Basin, Sulawesi, Indonesia

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
High magnitude flash flood has occurred several times in some areas in Central Sulawesi Province after the 2018 Palu Earthquake, one of them is in the Bangga River, Sigi Regency, Indonesia. It has caused massive impacts such as damaging agricultural and plantation areas and submerging public facilities and infrastructure and even causing fatalities. The flood carries a variety of materials, especially high concentration sediments which are thought to originate from eroded soils due to landslides induced by a 7.5 magnitude earthquake. These materials are eroded and transported by the flow at the upstream watershed due to heavy rainfall. This study intends to investigate the potential of landslides, factors that trigger floods and increased flooding after the earthquake. This research was conducted by investigating the landslides potency based on field surveys and interpretation of the latest satellite imagery, analyzing the characteristics of rainfall as a trigger for flooding, and predicting the flood potency as the primary impact of these two factors. Rainfall-flood transformation was simulated with the HEC-HMS Model, one of the freeware semi-distributed models commonly used in hydrological analysis. The model input is the configuration of river networks generated from the National DEM (DEMNAS), hourly rainfall during floods and other watershed parameters such as land cover, soil types and river slope. The similar simulation was also carried out on the condition of the watershed before the earthquake. Based on the results of the analysis, It can be inferred that flash floods in the Bangga River are mainly caused by heavy rainfall with long duration and landslide areas in the upper watershed triggered by the 2018 Palu Earthquake with an area of approximately 10.8 km2. The greatest depth of rainfall as a trigger for flooding is 30.4 mm with a duration of 8 hours. The results of the study also showed that landslides in the upper watershed could increase the peak flood by 33.33% from 118.56 m3/s to 158.08 m3/s for conditions before and after the earthquake.
Słowa kluczowe
Rocznik
Strony
190--200
Opis fizyczny
Bibliogr. 37 poz., rys., tab.
Twórcy
  • Department of Civil Engineering, Faculty of Engineering, Universitas Tadulako, Kampus Bumi Tadulako Tondo, Jalan Soekarno – Hatta Km.9 Palu, Central Sulawesi, 94117, Indonesia
autor
  • Department of Civil Engineering, Faculty of Engineering, Universitas Tadulako, Kampus Bumi Tadulako Tondo, Jalan Soekarno – Hatta Km.9 Palu, Central Sulawesi, 94117, Indonesia
  • Department of Civil Engineering, Faculty of Engineering, Universitas Tadulako, Kampus Bumi Tadulako Tondo, Jalan Soekarno – Hatta Km.9 Palu, Central Sulawesi, 94117, Indonesia
Bibliografia
  • 1. Andiesse V.W. 2012. The testing of GAMA I synthetic unit hydrograph for analysis of flood design in Bangga Catchment. MEKTEK, 14(1), 1–9. [in Indonesian]
  • 2. Bai Y., Zhang Z., Zhao W. 2019. Assessing the impact of climate change on flood events using HECHMS and CMIP5. Water, Air, and Soil Pollution. 230(119).
  • 3. Bao H., Ampuero J.P., Meng L., Fielding E.J, Liang C., Milliner C.W.D, Feng T., Huang H., Early and persistent supershear rupture of the 2018 magnitude 7.5 Palu earthquake. Nature Geoscience, 12, 200–205.
  • 4. Bradley K., Mallick R., Alfian D., Andikagumi H., Benazir B., Brocard G., Feng G., Hill E.M., Hubbard J., Majewski J., Meilianda E., Switzer A., Wei S., Yun S.H. 2009. Wet rice cultivation was the primary cause of the earthquake-triggered Palu landslides. EarthArxiv, Preprint article.
  • 5. Bradley K., Mallick R., Andikagumi H., Hubbard J., Meilianda E., Switzer A., Du N., Brocard G., Alfian D., Benazir B., Feng G., Yun S.H., Majewski J., Wei S., Hill, E.M. 2019. Earthquake-triggered 2018 Palu Valley landslides enabled by wet rice cultivation. Nature Geoscience, 12, 935–939.
  • 6. Cahyono C., Adidarma W.K., 2019. Influence analysis of peak rate factor in the flood events’ calibration process using HEC–HMS. Modeling Earth Systems and Environment, 5(4), 1705–1722.
  • 7. Carvajal M., Cornejo C.A., Sepúlveda I., Melnick D., Haase J.S. 2019. Nearly instantaneous tsunamis following the Mw 7.5 2018 Palu earthquake. Geophysical Research Letter, 46(10), 5117–5126.
  • 8. Cummins P.R., 2019. Irrigation and the Palu landslides. Nature Geoscience, News and Views.
  • 9. Frederik M.C.G., Udrekh, Adhitama R., Hananto N.D., Asrafil, Sahabuddin S., Irfan M., Moefti O., Putra D.B., Riyalda B.F. 2019. First results of a bathymetric survey of Palu Bay, Central Sulawesi, Indonesia following the Tsunamigenic Earthquake of 28 September 2018. Pure and Applied Geophysics, 76(8), 3277–3290.
  • 10. Gao Y., Zhang Z., Liu Y. 2019. Sensitivity analysis of parameters of a HEC-HMS model with polders. Journal of Coastal Research, 93,163–169.
  • 11. Geospatial Information Office of Indonesia (BIG). 2019. http://tides.big.go.id/DEMNAS/. Accessed on 20 August 2019. [in Indonesian]
  • 12. Huang C.L., Hsu, N.S, Liu H.J., Huang Y.H., 2018. Optimization of low impact development layout designs for megacity flood mitigation. Journal of Hydrology, 564, 542–558
  • 13. Hui G., Li S., Wang P., Suo Y., Wang I.D. Somerville I.D., 2018. Linkage between reactivation of the sinistral strike-slip faults and 28 September 2018 Mw7.5 Palu Earthquake, Indonesia. Science Bulletin, 63(24), 1635–1640.
  • 14. Kha D.D., Nhu N.Y., Anh T.N. 2018. An approach for flow forecasting in ungauged catchments – A Case study for Ho Ho reservoir catchment, Ngan Sau river, Central Vietnam. Journal of Ecological Engineering, 19(3), 74–79.
  • 15. Lanini A., Yodo S., Syafiuddin I. 2019. The protection of refugees rights of natural disasters in Central Sulawesi Indonesia. Proc. The 3rd International Conference on Globalization of Law and Local Wisdom (ICGLOW 2019), 358, 48–50.
  • 16. Mardin R., Shen, Z. 2018. Integrated criteria for flood disaster mitigation in indonesian urban masterplan; housing and settlement suitability case in Palu Urban masterplan. Urban Planning and Waterrelated Disaster Management, Springer Nature, Basel, Switzerland.
  • 17. Maryanti S. 2019. Spatial analysis of social facility building damage due to the 2018 earthquake in Palu City, Central Sulawesi Province. Bachelor Thesis, Universitas Muhammadiyah Surakarta. [in Indonesian]
  • 18. Miyajima M., Setiawan H., Yoshida M., Ono Y., Kosa K., Oktaviana I.S., Martini, Irdhiani. 2019. Geotechnical damage in the 2018 Sulawesi earthquake, Indonesia. Geoenvironmental Disasters, 6, 1–8.
  • 19. Natarajan S., Radhakrishnan N. 2019. Simulation of extreme event-based rainfall–runoff process of an urban catchment area using HEC-HMS. Modeling Earth Systems and Environment, 5(4), 1867–188.
  • 20. National Disaster Mitigation Agency of Indonesia (BNPB). 2019. https://www.bnpb.go.id/berita. Accessed on 19 September 2019. [in Indonesian]
  • 21. Pancoro W., Mangoki, W., Prasetyo S.Y.J. 2019. Evaluation of earthquake affected areas in Palu City using OBIA method on Landsat Image 8. Indonesian Journal of Computing and Modeling, 2(1), 32–35. [in Indonesian]
  • 22. Patil V.K., Saraf V.R., Karad O.V., Ghodke S.B., Gore D.K., Dhekale S.S. 2019. Simulation of rainfall runoff process using HEC-HMS model for Upper Godavari Basin Maharashtra, India. European Journal of Engineering Research and Science, 4(4), 102–107.
  • 23. Paulik R., Gusman A., Williams J.H., Pratama G.M., Lin S.L., Prawirabhakti A., Sulendra K., Zachari M.Y., Fortuna Z.E.D., Layuk N.B.P., Suwarni N.W.I. 2019. Tsunami hazard and built environment damage observations from Palu City after the September 28 2018 Sulawesi earthquake and tsunami. Pure and Applied Geophysics, 176(8), 3305–3321.
  • 24. Piacentini T., Galli A., Marsala V., Miccadei, E. 2018. Analysis of soil erosion induced by heavy rainfall: a case study from the NE Abruzzo Hills area in Central Italy. Water, 10(10), 1314.
  • 25. Saito H., Uchiyama S., Hayakawa Y.S., Obanawa H. 2018. Landslides triggered by an earthquake and heavy rainfalls at Aso volcano, Japan, detected by UAS and SfM-MVS photogrammetry. Progress in Earth and Planetary Science, 5(15).
  • 26. Salami A.W., Bilewu S.O., Ibitoye A.B., Ayanshola A.M. 2017. Runoff hydrographs using Snyder and SCS synthetic unit hydrograph methods: A case study of selected rivers in south west Nigeria. Journal of Ecological Engineering, 18(1), 25–34.
  • 27. Sassa S., Takagawa T. 2019, Liquefied gravity flowinduced tsunami: first evidence and comparison from the 2018 Indonesia Sulawesi earthquake and tsunami disasters. Landslides, 16(1), 195–200.
  • 28. Socquet A.,  Hollingsworth J., Pathier E.,  Bouchon M. 2019. Evidence of supershear during the 2018 magnitude 7.5 Palu earthquake from space geodesy. Nature Geoscience, 12, 192–199.
  • 29. Tritamodjo B. 2008. Applied hydrology. Beta Offset, Yogyakarta. [in Indonesian]
  • 30. Tunas I.G. 2019. The application of ITS-2 model for flood hydrograph simulation in large-size rainforest watershed, Indonesia. Journal of Ecological Engineering, 20(7), 112–125.
  • 31. Tunas I.G., Anwar N., Lasminto U. 2018. A synthetic unit hydrograph model based on fractal characteristics of watersheds. International Journal of River Basin Management, 17(4), 465–477.
  • 32. Tunas I.G., Maadji, R. 2018. The use of GIS and hydrodynamic model for performance evaluation of flood control structure. International Journal on Advanced Science, Engineering and Information Technology (IJASEIT), 8(6):2413–2420
  • 33. Watkinson I.M., Hall R. 2019. Impact of communal irrigation on the 2018 Palu earthquake-triggered landslides. Nature Geoscience, Article in press.
  • 34. Widjaja B., Gautama K.A. 2019. Prediction of the impact of following landslide in Poi Village with the Bingham model. Proc. The 2019 National Civil Engineering Seminar, 95–99. [in Indonesian]
  • 35. Yuan W., Liu M., Wan F. 2019. Calculation of critical rainfall for small-watershed flash floods based on the HEC-HMS hydrological model. Water Resources Management, 33(2), 555–2575.
  • 36. Zhang Y., Zhao Y., Liu B., Wang Z., Zhang S. 2019. Rill and gully erosion on unpaved roads under heavy rainfall in agricultural watersheds on China’s Loess Plateau. Agriculture, Ecosystems & Environment, 284(106580).
  • 37. Zhuang J., Peng J., Xu C., Li Z., Densmore A., Milledge D., Iqbal J., Cui Y. 2018. Distribution and characteristics of loess landslides triggered by the 1920 Haiyuan Earthquake, Northwest of China. Geomorphology, 314, 1–12.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-39169ca1-ab69-4d70-8695-a89e849bac59
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