Analysis on Collapsibility and Microstructure of Unsaturated Loess Using Fractal Geometry

Fu Li Ma; Mei Wang; Jing Yang; Xiao Hong Bai

doi:10.4028/www.scientific.net/AMM.238.435

Paper Titles

Study on Construction Technology of Geogrid Treatment for Slope of Swelling Rock
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Study on the Impact of Long-Term Immersion on the Shear Strength of Compacted Lime Stabilized Expansive Soils
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Analysis on Collapsibility and Microstructure of Unsaturated Loess Using Fractal Geometry
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Study on Reasonable Feature of Compaction Loess with Air Porosities
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Theoretical Solution to the Change of Site Predominant Period Caused by Soil Softening
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The Finite-Element Analysis of Characteristics of Soil Slopeseepage Field Change in Continuous Rain Condition
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Influence of Compaction Density of Soil Mass to the Seepage Build Capacity of Rain and Drainage Design Parameter
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 238Analysis on Collapsibility and Microstructure of...

Analysis on Collapsibility and Microstructure of Unsaturated Loess Using Fractal Geometry

Abstract:

This paper studies the microstructure of 16 group samples from three different sites of North-west region in P. R. China. Pictures of microstructure were processed with imaging processing program to acquire the geometer parameter and fractal dimension of pores. The range of pores’ fractal dimension is between 1.816~1.936. The pore distribution function of unsaturated soil is established based on fractal geometry theory. The pore water distribution of loess under natural moisture is analyzed. The relationships of collapsibility coefficient with fractal dimension and porosity of unsaturated pores are analyzed with the method of regression analysis. A larger fractal dimension represents a more complex pore-structure. The collapsibility coefficient of loess increases with the increase of fractal dimension and porosity of unsaturated pores.

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Periodical:

Applied Mechanics and Materials (Volume 238)

Pages:

435-440

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.238.435

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Online since:

November 2012

Authors:

Fu Li Ma, Mei Wang, Jing Yang, Xiao Hong Bai

Keywords:

Collapsible Loess, Fractal, Microstructure, Unsaturated Soil

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