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Bamboo vegetation is an endemic plant in Indonesia that grows on riverbanks. These plants have the potential to increase shear resistance due to the bond between the roots to the soil. However, an increase in plant weight due to its growth causes additional loads of soil. The condition triggers the release of soil on the slopes and causes riverbank sliding. Therefore, in developing the riparian ecological function, it is necessary to maintain the plants without neglecting the risk of physical damage to the river. This study aimed to estimate the risk of riverbank sliding due to the presence of bamboo plants by utilizing the bamboo vegetation conditions on the Walanae River. It was carried out on the 42.4 km riverbank in the middle area of Walanae watershed. The researchers selected 46 clumps of parring bamboo (Gigantochloa atter) as an endemic bamboo in this area and growing in the riverbank. The diameter of the bamboo trunk is the basis for an estimate of the weight of the bamboo clump. Furthermore, a numerical analysis was carried out by taking into account the load and shear resistance on the slope, including the weight of the plant. The research results indicated that bamboo is feasible to be applied for riverbank protection using the soil bioengineering method. The bamboo weight, which is indicated by the number of poles and diameter, significantly affects the stability of the slope. Therefore, the prevention of rising weight by harvesting method is critical to consider in riverbank protection.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
176--184
Opis fizyczny
Bibliogr. 28 poz., rys., tab.
Twórcy
autor
- Civil Engineering Education Faculty of Engineering, Universitas Negeri Makassar, Makassar, Indonesia
autor
- Civil Engineering Education Faculty of Engineering, Universitas Negeri Makassar, Makassar, Indonesia
autor
- Civil Engineering Education Faculty of Engineering, Universitas Negeri Makassar, Makassar, Indonesia
Bibliografia
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- 2. Bischetti G.B., De Cesare G., Mickovski S.B., Rauch H.P., Schwarz M., Stangl R. 2021. Design and temporal issues in Soil Bioengineering structures for the stabilisation of shallow soil movements. Ecol. Eng., 169, 106309.
- 3. Bordoloi S., Ng C.W.W. 2020. The effects of vegetation traits and their stability functions in bio-engineered slopes: A perspective review. Eng. Geol., 105742.
- 4. Cislaghi A.E., Chiaradia A., Bischetti G.B. 2017. Including root reinforcement variability in a probabilistic 3D stability model. Earth Surf. Process. Landforms, 42(12), 1789–1806.
- 5. Cislaghi A.E., Chiaradia A., Bischetti G.B. 2018. A probabilistic multidimensional approach to quantify large wood recruitment from hillslopes in mountainousforested catchments. Geomorphology, 306, 108–127.
- 6. De Baets S., Torri D., Poesen J., Salvador M.P., Meersmans J. 2008. Modelling increased soil cohesion due to roots with EUROSEM. Earth Surf. Process. Landforms J. Br. Geomorphol. Res. Gr., 33(13), 1948–1963.
- 7. Dietrich W.E., McKean J., Bellugi D., Perron T. 2007. The prediction of shallow landslide location and size using a multidimensional landslide analysis in a digital terrain model, in In: Chen, CL; Major, JJ, editors. Proceedings of the Fourth International Conference on Debris-Flow Hazards Mitigation: Mechanics, Prediction, and Assessment (DFHM4); Chengdu, China, September 10-13, 2007. The Netherlands, Amsterdam: IOS Press. 12.
- 8. Gasser E. et al.. 2019. A review of modeling the effects of vegetation on large wood recruitment processes in mountain catchments. Earth-Science Rev., 194, 350–373.
- 9. Gasser E., Perona P., Dorren L., Phillfips C., Hübl J., Schwarz M. 2020. A new framework to model hydraulic bank erosion considering the effects of roots. Water, 12(3), 893.
- 10. Guo W.Z. et al.. 2020. Telling a different story: The promote role of vegetation in the initiation of shallow landslides during rainfall on the Chinese Loess Plateau, Geomorphology, 350, 106879.
- 11. Hairiah D.K., Sulistyani H., Suprayogo D., Purnomosidhi P., Widodo R.H., Van Noordwijk M. 2006. Litter layer residence time in forest and coffee agroforestry systems in Sumberjaya, West Lampung, For. Ecol. Manage., 224(1–2), 45–57.
- 12. Lin C., Yang Y., Guo J., Chen G., Xie J. 2011. Fine root decomposition of evergreen broadleaved and coniferous tree species in mid-subtropical China: dynamics of dry mass, nutrient and organic fractions. Plant Soil, 338(1–2), 311–327.
- 13. Lu C., Chen S., Jiang Y., Shi J., Yao C., Su X. 2018. Quantitative analysis of riverbank groundwater flow for the Qinhuai River, China, and its influence factors. Hydrol. Process., (32)17, 2734–2747.
- 14. McMahon J.M. et al.. 2020. Vegetation and longitudinal coarse sediment connectivity affect the ability of ecosystem restoration to reduce riverbank erosion and turbidity in drinking water. Sci. Total Environ., 707, 135904.
- 15. Mao Z. et al.. 2012. Engineering ecological protection against landslides in diverse mountain forests: choosing cohesion models, Ecol. Eng., 45, 55–69.
- 16. Nath A.J. & Das A.K. 2011. Decomposition dynamics of three priority bamboo species of homegardens in Barak Valley, Northeast India, Trop. Ecol., 52(3), 325–330.
- 17. Pollen N., Simon A. 2005. Estimating the mechanical effects of riparian vegetation on stream bank stability using a fiber bundle model. Water Resour. Res., 41(7).
- 18. Recking A., Piton A., Montabonnet L., Posi S., Evette A. 2019. Design of fascines for riverbank protection in alpine rivers: Insight from flume experiments. Ecol. Eng., 138, 323–333.
- 19. Rey F. et al.. 2019. Soil and water bioengineering: Practice and research needs for reconciling natural hazard control and ecological restoration. Sci. Total Environ., 648, 1210–1218.
- 20. Schmitt K., Schäffer M., Koop J., Symmank. 2018. River bank stabilisation by bioengineering: potentials for ecological diversity, J. Appl. Water Eng. Res., 6(4), 262–273.
- 21. Shen P., Zhang L.M., Chen H.X., Gao L. 2017. Role of vegetation restoration in mitigating hillslope erosion and debris flows. Eng. Geol., 216, 122–133.
- 22. Seitz S. et al.. 2015. The influence of leaf litter diversity and soil fauna on initial soil erosion in subtropical forests, Earth Surf. Process. Landforms, 40(11), 1439–1447.
- 23. Shu A., Duan G., Rubinato M., Tian L., Wang M., Wang S. 2019. An experimental study on mechanisms for sediment transformation due to riverbank collapse, Water, 11(3), 529.
- 24. Wang L., Zhang G., Zhu P., Wang X. 2020. Comparison of the effects of litter covering and incorporation on infiltration and soil erosion under simulated rainfall. Hydrol. Process., 34(13), 2911–2922.
- 25. WSDOT. 2005. Geotechnical design manual M4603.” Washington State Department of Transportation Olympia, WA.
- 26. Wu T.H. & Watson A. 1998. In situ shear tests of soil blocks with roots. Can. Geotech. J., 35(4), 579–590.
- 27. Yuen J.Q., Fung T., Ziegler A.D. 2017. Carbon stocks in bamboo ecosystems worldwide: Estimates and uncertainties, For. Ecol. Manage., 393, 113–138.
- 28. Zhang H., Zhao Z., Ma G., Sun L. 2020. Quantitative evaluation of soil anti-erodibility in riverbank slope remediated with nature-based soil bioengineering in Liaohe River, Northeast China, Ecol. Eng., 151, 105840.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-89cae77a-b3d4-4b60-9b9b-31d256869ed6