Rock and Soil Mechanics ›› 2022, Vol. 43 ›› Issue (2): 358-364.doi: 10.16285/j.rsm.2021.0440

• Fundamental Theroy and Experimental Research • Previous Articles     Next Articles

Shrinkage behavior responses to nano-silica filling pores in aggregate laterite

TAN Yun-zhi, WANG Yuan, ZHAN Shao-hu, ZUO Qing-jun, MING Hua-jun   

  1. Key Laboratory of Geological Hazards on Three Gorges Reservoir Area of Ministry of Education, China Three Gorges University, Yichang, Hubei 443002, China
  • Received:2021-03-28 Revised:2021-11-28 Online:2022-02-11 Published:2022-02-22
  • Supported by:
    This work was supported by the National Natural Science Foundation of China (51579137, 51979150), the Youth Innovation Team Project of Hubei Province (T201803) and the 111 Project of Hubei Province (2018-19-1).

PDF (Chinese)

204

Abstract: The laterite may form cracks due to shrinkage for dehydration. These cracks not only reduce the overall strength, but also provide infiltration channel for rainwater, which intensifies the weakening of its bearing capacity. Therefore, how to inhibit laterite shrinkage is a key problem for engineering applications. The nano-silica particles are extremely fine in size and belong to the nano category. It is proposed to fully utilize the size advantage of nano-silica, so that nano-silica particles can enter the laterite aggregates and resist the shrinkage behavior of laterite caused by dehydration. Therefore, different dry mixing ratios (i.e. nano-silica: laterite = 0: 100, 2: 100, 3.5: 100, 5: 100, and 6.5: 100) were programmed, and nano-silica was mixed with laterite for compaction (dry density is 1.44 g/cm3 and 1.46 g/cm3 respectively). Shrinkage characteristics and pore distribution of compacted laterite-nano-silica mixture were compared. It was found that nano-silica could inhibit the shrinkage of laterite, and the shrinkage limit was also increased by the mixing ratio rising. Besides, plenty of nano-silica particles were found in the pores while the mixing ratio was greater than 5% by means of apparent morphology images. Meanwhile, the pore distribution curve also showed that the pores with diameter at 0.03 ?m reduced significantly, which indicated that nano-silica mainly filled the pores with diameter greater than 0.03 ?m. Adding nano-silica into laterite is a physical method to improve the shrinkage properties, which is different from the chemical methods such as lime treatment and has potential advantages to environmental protection.

Key words: laterite, nano-silica, pore, shrinkage, filling

CLC Number: 

  • TU 446
[1] DU Yu, LIU Song-yu, ZHU Liu-wen, ZOU Hai-feng, CAI Guo-jun, . Soil classification method for port and waterway engineering based on piezocone penetration test [J]. Rock and Soil Mechanics, 2022, 43(5): 1353-1363.
[2] WANG Yan-xing, LI Chi, GE Xiao-dong, GAO Li-ping, . Experimental study on improvement of weathered Pisha sandstone soil in Inner Mongolia section of the Yellow River Basin based on microbially induced carbonate precipitation technology [J]. Rock and Soil Mechanics, 2022, 43(3): 708-718.
[3] WANG Hai-man, NI Wan-kui. Prediction model of saturated/unsaturated permeability coefficient of compacted loess with different dry densities [J]. Rock and Soil Mechanics, 2022, 43(3): 729-736.
[4] TIAN Jia-li, WANG Hui-min, LIU Xing-xing, XIANG Lei, SHENG Jin-chang, LUO Yu-long, ZHAN Mei-li. Study on permeability characteristics of sandstone considering pore compression sensitivity at different scales [J]. Rock and Soil Mechanics, 2022, 43(2): 405-415.
[5] LI Yan, LI Tong-lu, HOU Xiao-kun, LI Hua, ZHANG Jie, . Prediction of unsaturated permeability curve of compaction loess with pore-size distribution curve and its application scope [J]. Rock and Soil Mechanics, 2021, 42(9): 2395-2404.
[6] GE Miao-miao, LI Ning, SHENG Dai-chao, ZHU Cai-hui, PINEDA Jubert, . Experimental investigation of microscopic deformation mechanism of unsaturated compacted loess under hydraulic coupling conditions [J]. Rock and Soil Mechanics, 2021, 42(9): 2437-2448.
[7] LIU Xuan-ting, CHEN Cong-xin, LIU Xiu-min, XIA Kai-zong, ZHANG Chu-qiang, WANG Tian-long, WANG Yue, . Analysis of catastrophic instability of roof-rib pillar support system under backfill mining [J]. Rock and Soil Mechanics, 2021, 42(9): 2461-2471.
[8] YIN Xiao-ka, DU Si-yi, WANG Tao-tao. Experimental study of relationship between sand liquefaction and CFG pile construction parameters [J]. Rock and Soil Mechanics, 2021, 42(9): 2518-2524.
[9] LIU Kang, CHEN Guo-xing, WU Qi, MA Wei-jia, QIN You, . Effects of cyclic loading directions on liquefaction characteristics of saturated coral sand [J]. Rock and Soil Mechanics, 2021, 42(7): 1951-1960.
[10] WANG Jing, XIAO Tao, ZHU Hong-hu, MEI Guo-xiong, LIU Zheng-yuan, WEI Guang-qing, . Study on bearing capacity of permeable pipe pile by field optical fiber monitoring [J]. Rock and Soil Mechanics, 2021, 42(7): 1961-1970.
[11] LIU Zhang-rong, YE Wei-min, CUI Yu-jun, ZHU He-hua, WANG Qiong, CHEN Yong-gui, . Water retention curve model based on micro-pore filling and capillary condensation theories [J]. Rock and Soil Mechanics, 2021, 42(6): 1549-1556.
[12] LIU Jie, ZHANG Han, WANG Rui-hong, WANG Fang, HE Zhuo-wen, . Investigation of progressive damage and deterioration of sandstone under freezing-thawing cycle [J]. Rock and Soil Mechanics, 2021, 42(5): 1381-1394.
[13] SHEN Ji-wei, WAN Shui, LIU Su-ying, WANG Zheng-cheng, FU Jun-dong. Experimental study on the effect of zinc pollution on drying shrinkage and resistivity of purple soil [J]. Rock and Soil Mechanics, 2021, 42(3): 656-664.
[14] TAN Yun-zhi, ZHAN Shao-hu, SHEN Ke-jun, ZUO Qing-jun, MING Hua-jun, . Effects of hardening and intergranular cementation on the surface of treated aggregate laterite [J]. Rock and Soil Mechanics, 2021, 42(2): 361-368.
[15] WU Fei-peng, FAN Xian-zhang, XU Er-si, YANG Tao, YAN Bing-fu, LIU Jing, . Micromechanical analysis of damage evolution of sandstone matrix by high pressure infiltration of fracturing fluid [J]. Rock and Soil Mechanics, 2021, 42(12): 3238-3248.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] YAO Yang-ping, HOU Wei. Basic mechanical behavior of soils and their elastoplastic modeling[J]. , 2009, 30(10): 2881 -2902 .
[2] XU Jin-ming, QIANG Pei, ZHANG Peng-fei. Texture analysis of photographs of silty clay[J]. , 2009, 30(10): 2903 -2907 .
[3] XIANG Tian-bing, FENG Xia-ting, CHEN Bing-rui, JIANG Quan, ZHANG Chuan-qing. Rock failure mechanism and true triaxial experimental study of specimens with single structural plane under three-dimensional stress[J]. , 2009, 30(10): 2908 -2916 .
[4] SHI Yu-ling, MEN Yu-ming, PENG Jian-bing, HUANG Qiang-bing, LIU Hong-jia. Damage test study of different types structures of bridge decks by ground-fissure[J]. , 2009, 30(10): 2917 -2922 .
[5] XIA Dong-zhou, HE Yi-bin, LIU Jian-hua. Study of damping property and seismic action effect for soil-structure dynamic interaction system[J]. , 2009, 30(10): 2923 -2928 .
[6] XU Su-chao, FENG Xia-ting, CHEN Bing-rui. Experimental study of skarn under uniaxial cyclic loading and unloading test and acoustic emission characteristics[J]. , 2009, 30(10): 2929 -2934 .
[7] ZHANG Li-ting, QI Qing-lan, WEI Jing HUO Qian, ZHOU Guo-bin. Variation of void ratio in course of consolidation of warping clay[J]. , 2009, 30(10): 2935 -2939 .
[8] ZHANG Qi-yi. Study of failure patterns of foundation under combined loading[J]. , 2009, 30(10): 2940 -2944 .
[9] YI Jun, JIANG Yong-dong, XUAN Xue-fu, LUO Yun, ZHANG Yu. A liquid-solid dynamic coupling modelof ultrasound enhanced coalbed gas desorption and flow[J]. , 2009, 30(10): 2945 -2949 .
[10] TAO Gan-qiang, YANG Shi-jiao, REN Feng-yu. Experimental research on granular flow characters of caved ore and rock[J]. , 2009, 30(10): 2950 -2954 .
Copyright © Rock and Soil Mechanics, All Rights Reserved.
Tel: 027-87198484, 87199252, 87199253, 87198752 E-mail: ytlx@whrsm.ac.cn
Powered by Beijing Magtech Co. Ltd