Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Investigation on the microstructural characteristics of lime-stabilized soil after freeze–thaw cycles
https://orcid.org/0000-0001-7853-3454
https://orcid.org/0000-0001-6210-6415
Highlights The microstructure of quicklime-treated saline soil is systematically investigated. The analysis is conducted in conjunction with macro and micro experimental data. The mechanism of freeze–thaw cycles on quicklime-treated saline soil is revealed. MIP and SEM test results were compared and the detection ranges are advised.
Abstract Saline soil in Northwest China is susceptible to frequent and severe freeze–thaw cycles (FTC), resulting in railway and pavement disasters, emphasizing the need for stabilizing inadequately constructed soils. The engineering characteristics of soils can be changed after FTCs, which results from the variation of microstructure. Physisorption experiments (BET), mercury intrusion porosimetry (MIP), and scanning electron microscopy (SEM) were employed in this research to investigate how FTCs affected the micro-characteristics of lime-stabilized saline soil. According to the results, at the beginning of FTCs, the specific surface area (SSA) increased and then reduced after 3 FTCs. Moreover, the pores presented a bimodal characteristic and could be divided into inter- and intra-aggregate pores. The pore size distribution of the stabilized saline soil was altered by the FTCs. Additionally, the FTCs reduced the porosity of pores between 2 ∼ 22 μm and increased their complexity, while also creating more directional pore orientation. The results of this paper are believed to help advance soil stabilization methods and offer useful insights into the microstructural characteristics of lime-stabilized saline soil.
Investigation on the microstructural characteristics of lime-stabilized soil after freeze–thaw cycles
https://orcid.org/0000-0001-7853-3454
https://orcid.org/0000-0001-6210-6415
Highlights The microstructure of quicklime-treated saline soil is systematically investigated. The analysis is conducted in conjunction with macro and micro experimental data. The mechanism of freeze–thaw cycles on quicklime-treated saline soil is revealed. MIP and SEM test results were compared and the detection ranges are advised.
Abstract Saline soil in Northwest China is susceptible to frequent and severe freeze–thaw cycles (FTC), resulting in railway and pavement disasters, emphasizing the need for stabilizing inadequately constructed soils. The engineering characteristics of soils can be changed after FTCs, which results from the variation of microstructure. Physisorption experiments (BET), mercury intrusion porosimetry (MIP), and scanning electron microscopy (SEM) were employed in this research to investigate how FTCs affected the micro-characteristics of lime-stabilized saline soil. According to the results, at the beginning of FTCs, the specific surface area (SSA) increased and then reduced after 3 FTCs. Moreover, the pores presented a bimodal characteristic and could be divided into inter- and intra-aggregate pores. The pore size distribution of the stabilized saline soil was altered by the FTCs. Additionally, the FTCs reduced the porosity of pores between 2 ∼ 22 μm and increased their complexity, while also creating more directional pore orientation. The results of this paper are believed to help advance soil stabilization methods and offer useful insights into the microstructural characteristics of lime-stabilized saline soil.
Investigation on the microstructural characteristics of lime-stabilized soil after freeze–thaw cycles
https://orcid.org/0000-0001-7853-3454
https://orcid.org/0000-0001-6210-6415
Highlights The microstructure of quicklime-treated saline soil is systematically investigated. The analysis is conducted in conjunction with macro and micro experimental data. The mechanism of freeze–thaw cycles on quicklime-treated saline soil is revealed. MIP and SEM test results were compared and the detection ranges are advised.
Abstract Saline soil in Northwest China is susceptible to frequent and severe freeze–thaw cycles (FTC), resulting in railway and pavement disasters, emphasizing the need for stabilizing inadequately constructed soils. The engineering characteristics of soils can be changed after FTCs, which results from the variation of microstructure. Physisorption experiments (BET), mercury intrusion porosimetry (MIP), and scanning electron microscopy (SEM) were employed in this research to investigate how FTCs affected the micro-characteristics of lime-stabilized saline soil. According to the results, at the beginning of FTCs, the specific surface area (SSA) increased and then reduced after 3 FTCs. Moreover, the pores presented a bimodal characteristic and could be divided into inter- and intra-aggregate pores. The pore size distribution of the stabilized saline soil was altered by the FTCs. Additionally, the FTCs reduced the porosity of pores between 2 ∼ 22 μm and increased their complexity, while also creating more directional pore orientation. The results of this paper are believed to help advance soil stabilization methods and offer useful insights into the microstructural characteristics of lime-stabilized saline soil.
Investigation on the microstructural characteristics of lime-stabilized soil after freeze–thaw cycles
Nan, Jiyun (Autor:in) / Chang, Dan (Autor:in) / Liu, Jiankun (Autor:in) / Chen, Haohua (Autor:in) / Lee, Jong-Sub (Autor:in) / Kim, Sang Yeob (Autor:in)
08.12.2023
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
Effect of Freeze—Thaw Cycles on Mechanical Behavior of Lime-Stabilized Soil
| Online Contents | 2016
Effect of Freeze—Thaw Cycles on Mechanical Behavior of Lime-Stabilized Soil
| British Library Online Contents | 2016
Effect of Freeze—Thaw Cycles on Mechanical Behavior of Lime-Stabilized Soil
| Online Contents | 2016