In seasonal frozen zones, reinforced soil (RS) slopes are susceptible to uneven settlement or potential slope instability due to prolonged freeze-thaw (FT) cycles. To investigate the effects of cycle number, soil moisture content, and reinforcement type on the performance of RS slopes under FT conditions, five model tests on RS slopes were conducted. The test results indicated that as the number of FT cycles increased, the amplitude of temperature fluctuations within the slope gradually decreased, moisture gradually accumulated near the slope surface and bottom, and slope deformation and reinforcement strain progressively accumulated. With an increase in the initial soil moisture content, the temperature changes within the slope slowed, the amplitude of temperature fluctuations reduced, internal moisture migration gradually intensified, and slope deformation and reinforcement strain increased progressively. Differences in stiffness, permeability, and soil-reinforcement interface behavior among reinforcement types led to variations in the performance of reinforced soil slopes with different reinforcement materials. Additionally, based on theoretical analysis, the influence of FT cycles on the thermal conductivity coefficient of RS slopes was studied. The results indicated that as the number of FT cycles increased, the soil thermal conductivity coefficient gradually rose under the combined effects of FT cycles and external loads.
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14 July 2026
Technical Paper|
March 04 2026
Influencing factors for geosynthetic-reinforced slope performance under freeze-thaw cycles
X. Wei;
X. Wei
1Department of Geotechnical Engineering, College of Civil Engineering,
Tongji University
, Shanghai, China
, E-mail: 2330588@tongji.edu.cn
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C. Xu;
C. Xu
2Department of Geotechnical Engineering, College of Civil Engineering,
Tongji University
, Shanghai, China
, E-mail: c_axu@tongji.edu.cn
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Y. Meng;
3Department of Geotechnical Engineering, College of Civil Engineering,
Tongji University
, Shanghai, China
Corresponding author Y. Meng (2011181@tongji.edu.cn)
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Y. Yang;
Y. Yang
4Department of Geotechnical Engineering, College of Civil Engineering,
Tongji University
, Shanghai, China
, E-mail: 2011yang@tongji.edu.cn
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G. Li;
G. Li
5School of Environment and Safety Engineering,
North University of China
, Taiyuan, China
, E-mail: 20230210@nuc.edu.cn
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B. Jia
B. Jia
6
East China Electric Power Design Institute Co., Ltd. of China Power Engineering Consulting Group
, Shanghai, China
, E-mail: 1962374131@qq.com
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Corresponding author Y. Meng (2011181@tongji.edu.cn)
CONFLICT OF INTEREST The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
Publisher: Emerald Publishing
Received:
March 07 2025
Accepted:
December 11 2025
Online ISSN: 1751-7613
Print ISSN: 1072-6349
Funding
Funding Group:
- Award Group:
- Funder(s): National Natural Science Foundation of China
- Award Id(s): 41772284,42502281
- Funder(s):
- Award Group:
- Funder(s): Scientific Research Program of State Grid Co., Ltd. UHV Construction Branch of China
- Award Id(s): SGTYHT/23-JS-001
- Funder(s):
- Award Group:
- Funder(s): Scientific Research Program of the East China Electric Power Design Institute Co., Ltd. of China Power Engineering Consulting Group
- Award Id(s): 30-K2023-G01
- Funder(s):
- Funding Statement(s): This study was supported by the National Natural Science Foundation of China (Grant Nos. 41772284, 42502281); the Scientific Research Program of State Grid Co., Ltd. UHV Construction Branch of China (SGTYHT/23-JS-001); the Scientific Research Program of the East China Electric Power Design Institute Co., Ltd. of China Power Engineering Consulting Group(30-K2023-G01).
© 2026 Emerald Publishing Limited
2026
Emerald Publishing Limited
Licensed re-use rights only
Geosynthetics International (2026) 33 (4): 668–682.
Article history
Received:
March 07 2025
Accepted:
December 11 2025
Citation
Wei X, Xu C, Meng Y, Yang Y, Li G, Jia B (2026), "Influencing factors for geosynthetic-reinforced slope performance under freeze-thaw cycles". Geosynthetics International, Vol. 33 No. 4 pp. 668–682, doi: https://doi.org/10.1680/jgein.25.00038
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