Abstract:To enhance the long-term service performance of solidified soft soil in plateau regions, this study employed ordinary Portland cement for stabilization. A series of unconfined compression tests, direct shear tests, and microstructural characterization techniques (XRD, SEM, NMR) were utilized to systematically investigate the strength deterioration patterns of cement-stabilized soil under freeze-thaw cycles and elucidate the intrinsic relationship between macroscopic mechanical behavior and microscopic mechanisms. The results show that the strength deterioration of cement-stabilized soil exhibits distinct stage characteristics. The first five freeze-thaw cycles result in the most significant strength reduction, with markedly diminished effects observed thereafter, identifying this initial phase as the critical period for strength degradation. A predictive model based on a 30-year service life established strength deterioration thresholds. The stress-strain curves reveal a three-stage evolution, with specimens demonstrating similar strength development trends in the linear elastic stage across all cement contents, followed by a sharp stress drop post-peak, indicating a notable transition from plastic to brittle failure. The incorporation of cement significantly enhances soil strength, with the unconfined compressive and shear strengths of specimens containing 4%–10% cement after 10 freeze-thaw cycles substantially exceeding those of untreated soil. The increase in cohesion was significantly more pronounced than that of the internal friction angle. Microstructural analysis indicates that repeated freeze-thaw cycles weaken interparticle bonding, reduce particle contacts, and promote pore evolution and development, thereby providing a microscopic interpretation of the macroscopic strength deterioration mechanisms. These findings offer theoretical and technical support for the application of soil stabilization technologies in cold plateau regions.
[1] 尤昌龙,赵成刚,张焕城,等. 高原斜坡软土地基处理实践[J]. 岩石力学与工程学报,2003,22(1):126–130.(YOU Chonglong,ZHAO Chenggang,ZHANG Huancheng,et al. Subgrade treatment practice of the plateau slope on soft clay[J]. Chinese Journal of Rock Mechanics and Engineering,2003,22(1):126–130.(in Chinese))
[2] 李保琦,张楚楚,周毓彦,等. 1960—2023年我国东北典型季节性冻土区冻融指数及冻土退化影响因素分析[J]. 水利水电技术(中英文),2024,55(8):161–173.(LI Baoqi,ZHANG Chuchu,ZHOU Yuyan,et al. Correlation analysis of freezing and thawing index and factors affecting frozen soil degradation in typical seasonally frozen ground in Northeast China during 1960—2023[J]. Water Resources and Hydropower Engineering,2024,55(8):161–173.(in Chinese))
[3] 刘红平,李 昊,魏 进,等. 考虑细颗粒含量的季冻区公路路基水分迁移特性[J]. 长安大学学报:自然科学版,2024,44(4):27–37.(LIU Hongping,LI Hao,WEI Jin,et al. Water migration characteristics of highway subgrade in seasonal frozen areas considering fine particle content[J]. Journal of Chang′an University:Natural Science,2024,44(4):27–37.(in Chinese))
[4] 朱剑锋,汪正清,陶燕丽,等. 电石渣–草木灰复合固化剂固化废弃软土微观特性研究[J]. 土木工程学报,2023,56(10):180–189.(ZHU Jianfeng,WANG Zhenqing,TAO Yanli,et al. Study on micro characteristics of waste soft solidified by calcium carbide slag plant ash composite curing agent[J]. China Civil Engineering Journal,2023,56(10):180–189.(in Chinese))
[5] 朱晨俊,温小栋,吴佳育,等. 基于MICP技术的海上风电场滩涂软土固化试验研究[J]. 太阳能学报,2024,45(11):467–476.(ZHU Chenjun,WEN Xiaodong,WU Jiayu,et al. Experimental investigation on consolidation of soft soil in mudflat of offshore wind farm based on MICP technology[J]. Acta Energiae Solaris Sinica,2024,45(11):467–476.(in Chinese))
[6] 王 欢,张佳伟,郭合家. EICP改良膨胀土的物理力学性质试验研究[J]. 土木与环境工程学报(中英文),2024,46(5):109–116.(WANG Huan,ZHANG Jiawei,GUO Hejia. Experimental study on physical and mechanical properties of expansive soil improved by EICP[J]. Journal of Civil and Environmental Engineering,2024,46(5):109–116.(in Chinese))
[7] 贾敏才,刘 波,周训军. 滨海含软土夹层粉细砂地基高能级强夯加固试验研究[J]. 建筑结构学报,2019,40(11):240–246.(JIA Mincai,LIU Bo,ZHOU Xunjun. Field test study of high energy dynamic compaction on marine silty fine sand deposits with soft interlayers[J]. Journal of Building Structures,2019,40(11):240–246.(in Chinese))
[8] 金佳旭,秦志发,刘 磊,等.工业固废–水泥固化腐殖土的力学响应和微观机制[J]. 岩土工程学报,2024,46(11):2 410–2 419. (JIN Jiaxu,QIN Zhifa,LIU Lei,et al. Mechanical response and micro-mechanism of humus soil solidified by industrial solid waste-cement[J]. Chinese Journal of Geotechnical Engineering,2024,46(11):2 410–2 419.(in Chinese))
[9] 王东星,许凤丽,泮晓华,等. GGBS-MICP协同固化淤泥质砂土工程特性研究[J]. 岩石力学与工程学报,2025,44(5):1 349–1 362. (WANG Dongxing,XU Fengli,PAN Xiaohua,et al. Study on the engineering properties of GGBS-MICP synergistic solidification of silty-sandy soil[J]. Chinese Journal of Rock Mechanics and Engineering,2025,44(5):1 349–1 362.(in Chinese))
[10] 张淼鑫,孙剑飞,张晓东,等. 应用木质素磺酸钙–粉煤灰对寒区碳酸盐渍土力学性能的改良[J]. 东北林业大学学报,2022,50(10):96–100.(ZHANG Miaoxin,SUN Jianfei,ZHANG Xiaodong,et al. Applying calcium lignosulfonate-fly ash to improve mechanical properties of carbonate stained soil in cold areas[J]. Journal of Northeast Forestry University,2022,50(10):96–100.(in Chinese))
[11] 魏 丽,柴寿喜,薛美玲. 以抗剪性能与结构损伤评价纤维加筋土的冻融耐久性[J]. 岩石力学与工程学报,2022,41(增2):3 453–3 463. (WEI Li,CHAI Shouxi,XUE Meiling. Evaluation of freeze-thaw durability of fiber reinforced soil by shear performances and structural damage[J]. Chinese Journal of Rock Mechanics and Engineering,2022,41(Supp.2):3 453–3 463.(in Chinese))
[12] 陈 诚,郭 伟,任宇晓. 冻融循环条件下木质素纤维改良土性质研究及微观分析[J]. 岩土工程学报,2020,42(增2):135–140.(CHEN Cheng,GUO Wei,REN Xiaoyu. Properties and microscopic analysis of lignin fiber-reinforced soils under freeze–thaw cycles[J]. Chinese Journal of Geotechnical Engineering,2020,42(Supp.2):135–140.(in Chinese))
[13] 谢嘉豪,李建东,王 旭,等. 冻融循环作用对F1加固黄土强度与微观结构的影响研究[J]. 防灾减灾工程学报,2023,43(6):1 445–1 453. (XIE Jiahao,LI Jiandong,WANG Xu,et al. Effects of freeze?thaw cycles on the strength and microstructure of f1?solidified loess[J]. Journal of Disaster Prevention and Mitigation Engineering,2023,43(6):1 445–1 453.(in Chinese))
[14] 李新明,张浩扬,武 迪,等. 石灰–偏高岭土改良遗址土强度劣化特性的冻融循环效应[J]. 岩土力学,2023,44(6):1 593–1 603. (LI Xinming,ZHANG Haoyang,WU Di,et al. Strength deterioration characteristics of lime-metakaolin improved earthen site soil under freeze-thaw cycles[J]. Rock and Soil Mechanics,2023,44(6):1 593–1 603.(in Chinese))
[15] CHEN,Z F,CHEN H E,MA W L. Study on the changing rules of silty Clay?s pore structure under freeze-thaw cycles[J]. Journal of Engineering,2019,2019:7493872.
[16] 齐吉琳,张建明,朱元林. 冻融作用对土结构性影响的土力学意义[J]. 岩石力学与工程学报,2003,22(增2):2 690–2 694.(QI Jiling,ZHANG Jianming,ZHU Yuanlin. Influence of freezing- thawing on soil structure and its soil mechanics significance[J]. Chinese Journal of Rock Mechanics and Engineering,2003,22(Supp.2):2 690–2 694.(in Chinese))
[17] 刘 宽,叶万军,景宏君,等. 季冻区黄土微观损伤识别与宏观力学响应研究[J]. 岩土工程学报,2021,43(增1):192–197.(LIU Kuan,YE Wanjun,JING Hongjun,et al. Microscopic damage identification and macroscopic mechanical response of loess in seasonal frozen areas[J]. Chinese Journal of Geotechnical Engineering,2021,43(Supp.1):192–197.(in Chinese))
[18] FAN W H,YANG P,WANG S F,et al. Freeze-thaw effects on pore structure of clay by 3D X-ray computed tomography and mercury intrusion porosimetry[J]. Cold Regions Science and Technology,2024,225:104276.
[19] 王天亮,刘建坤,田亚护. 冻融作用下水泥及石灰改良土静力特性研究[J]. 岩土力学,2011,32(1):193–198.(WANG Tianliang,LIU Jiankun,TIAN Yahu,Static properties of cement and lime-modified soil subjected to freeze-thaw cycles[J]. Rock and Soil Mechanics,2011,32(01):193–198.(in Chinese))
[20] 汤怡新,刘汉龙,朱 伟. 水泥固化土工程特性试验研究[J]. 岩土工程学报,2000,22(5):549–554.(TANG Yixin,LIU Hanlong,ZHU Wei. Study on engineering properties of cement-stabilized soil[J]. Chinese Journal of Geotechnical Engineering,2000,22(5):549–554.(in Chinese))
[21] 马冬冬,马芹永,黄 坤,等. 基于NMR的地聚合物水泥土孔隙结构与动态力学特性研究[J]. 岩土工程学报,2021,43(3):572–578.(MA Dongdong,MA Qinyong,HUANG Kun,et al. Pore structure and dynamic mechanical properties of geopolymer cement soil based on nuclear magnetic resonance technique[J]. Chinese Journal of Geotechnical Engineering,2021,43(3):572–578.(in Chinese))
[22] 叶万军,李长清,杨更社,等.冻融环境下黄土体结构损伤的尺度效应[J]. 岩土力学,2018,39(7):2 336–2 343.(YE Wanjun,LI Changqing,YANG Gengshe,et al. Scale effects of damage to loess structure under freezing and thawing conditions[J]. Rock and Soil Mechanics,2018,39(7):2 336–2 343.(in Chinese))
[23] XU F,WEI H,QIAN W CX,et al. Composite alkaline activator on cemented soil:Multiple tests and mechanism analyses[J]. Construction and Building Materials,2018,188:433–443.