The Study of Soil-Roots Strength Performance of Soil Slope by Using Guinea Grass

Mohd Syazwan bin Zainordin; Nor Azizi bin Yusoff; Tuan Norhayati binti Tuan Chik; Muhamad Ali Hanapiah bin Ab Manap; Zulhazmi Sayuti; Muhamad Firdaurs bin Abdullah

doi:10.4028/www.scientific.net/AMM.802.10

Paper Titles

Preface, Committees and Organizer

Adverse Effects of Soil Grouting on Sandy Soils
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The Study of Soil-Roots Strength Performance of Soil Slope by Using Guinea Grass
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Rock Overstressing in Deep Tunnel Excavation of Pahang-Selangor Raw Water Transfer Project
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Groundwater Inflows Characterization in the Pahang-Selangor Raw Water Transfer Tunnel Using δ²H and δ¹⁸O as Tracers
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Finite Element Analysis of Tunnelling Induced Deformation towards Pile Foundation
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Modification of Published Prediction Model of Ground Motion due to Sumatra Subduction Earthquakes for the Application in Peninsular Malaysia
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Seismic Microzonation for Denizli Metropolitan Area, Turkey
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Development of a New Tsunami Generator
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 802The Study of Soil-Roots Strength Performance of...

The Study of Soil-Roots Strength Performance of Soil Slope by Using Guinea Grass

Abstract:

Vegetation has been proven for establishing and implementing resistive measures against erosion and failure of slopes, river banks, removal of air pollution and reduced storm water runoff. Installation of cover crop involved soil element usage as growth medium which create several interaction between both strands. This study was carried out to investigate the soil strength performance by using Guinea grass at different construction period up to three months. Grass was planted in a 300 mm x 300 mm x 700 mm test plot with a suitable soil medium. Direct shear tests were conducted for each plot to determine the soil shear strength according to different construction period. Some basic geotechnical testing also were carried out. The results showed there is an increment in shear strength for soil sample over the time at various depths. During period of 1st, 2nd and 3rd month, the average shear stress of 100 mm depth was 50.56 kPa, 63.96 kPa, and 96.59 kPa respectively. Meanwhile, for 200 mm depth the result was 40.843 kPa, 53.91 kPa and 62.93 kPa respectively. Lastly, on 300 mm depth, shear stress was 37.21 kPa, 51.09 kPa, and 59.27 kPa respectively. Based on the result, the higher shear strength was obtained at different construction period and at varying depths. From the observation, roots mass increased for different construction period. In terms of tensile strength, the diameter of the root affects the rate of resistance against the tensile forces. This indicated that the roots structure growth affects the soil shear strength.

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Periodical:

Applied Mechanics and Materials (Volume 802)

Pages:

10-15

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.802.10

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Online since:

October 2015

Authors:

Mohd Syazwan bin Zainordin, Nor Azizi bin Yusoff, Tuan Norhayati binti Tuan Chik, Muhamad Ali Hanapiah bin Ab Manap, Zulhazmi Sayuti, Muhamad Firdaurs bin Abdullah

Keywords:

Guinea Grass, Root Mass, Shear Strength, Soil-Roots Interaction, Tensile Strength

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