Your search keyword '"Mingtang Chai"' showing total 28 results

1. Evolution of Secondary Periglacial Environment Induced by Thawing Permafrost near China–Russia Crude Oil Pipeline Based on Airborne LiDAR, Geophysics, and Field Observation

Author

Kai Gao, Guoyu Li, Fei Wang, Yapeng Cao, Dun Chen, Qingsong Du, Mingtang Chai, Alexander Fedorov, Juncen Lin, Yunhu Shang, Shuai Huang, Xiaochen Wu, Luyao Bai, Yan Zhang, Liyun Tang, Hailiang Jia, Miao Wang, and Xu Wang

Subjects

China–Russia crude oil pipeline (CRCOP), airborne LiDAR, permafrost, periglacial phenomena, icing, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

The China–Russia crude oil pipeline (CRCOP) operates at a temperature that continuously thaws the surrounding permafrost, leading to secondary periglacial phenomena along the route. However, the evolution and formation mechanisms of these phenomena are still largely unknown. We used multi-temporal airborne light detection and ranging (LiDAR), geophysical, and field observation data to quantify the scale of ponding and icing, capture their dynamic development process, and reveal their development mechanisms. The results show that the average depth of ponding within 5 m on both sides of the pipeline was about 31 cm. The volumes of three icings (A–C) above the pipeline were 133 m3, 440 m3, and 186 m3, respectively. Icing development can be divided into six stages: pipe trench settlement, water accumulation in the pipe trench, ponding pressure caused by water surface freezing, the formation of ice cracks, water overflow, and icing. This study revealed the advantages of airborne LiDAR in monitoring the evolution of periglacial phenomena and provided a new insight on the development mechanisms of the phenomena by combining LiDAR with geophysics and field observation. The results of our study are of great significance for developing disaster countermeasures and ensuring the safe operation of buried pipelines.

Published

2024

2. Variation of water bodies along highways in the Qinghai–Tibet Plateau over the past 20 years: A case study of G109 and G219

Author

Yu Gao, Mingtang Chai, Wei Ma, Yangyang Li, Weidong Chen, and Yanhu Mu

Subjects

air temperature, climate change, permafrost, precipitation, qinghai–tibet plateau, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350

Abstract

The water bodies existing along highways in the high altitude areas of the Qinghai–Tibet Plateau (QTP) will aggravate subgrade settlement and road damage, and affect the long-term stability of road networks. Based on remote sensing and geographic information system (GIS) techniques, this study analyzed the changes in the number and area of water bodies along the G109 and G219 highways in the QTP in the past 20 years. The results showed that between 2000 and 2019, the number of water bodies along the two highways increased by 24 and 19%, respectively, and their area increased by 26 and 19%, respectively. The area and the number of water bodies >1 km2 in the permafrost area and those

Published

2022

3. Preliminary Study on InSAR-Based Uplift or Subsidence Monitoring and Stability Evaluation of Ground Surface in the Permafrost Zone of the Qinghai–Tibet Engineering Corridor, China

Author

Qingsong Du, Dun Chen, Guoyu Li, Yapeng Cao, Yu Zhou, Mingtang Chai, Fei Wang, Shunshun Qi, Gang Wu, Kai Gao, and Chunqing Li

Subjects

InSAR, Qinghai–Tibet engineering corridor, permafrost zone, big data and cloud computing, disaster prevention and mitigation, Science

Abstract

Against the background of global warming, permafrost areas are facing increasing thawing, and the threat to the surface of the Qinghai–Tibet Engineering Corridor (QTEC) is serious. It is imperative to understand the current surface deformation and analyze the changes spatiotemporal characteristics for future warnings. At present, observation of a long time series and overall coverage of vertical ground deformation in QTEC are lacking. This paper takes the permafrost deformation of the QTEC as its research object. It uses the pretreated LiCSAR product and combines it with the LiCSBAS package to obtain monitoring results of the long time series deformation of the engineering corridor’s surface. The SAR image acquisition date is taken as the constraint, the results covering the whole processing area are selected, and then the vertical deformation information covering the entire engineering corridor area by ignoring the north–south displacement is calculated. The results show that the surface of the study area, as a whole, slightly subsided between May 2017 and March 2022, and the vertical deformation rate was mostly distributed at −27.068 mm/yr − 18.586 mm/yr, with an average of −1.06 mm/yr. Vertical deformation dominated at 52.84 percent of the study area, of which settlement accounted for 27.57 percent and uplift accounted for 25.27 percent. According to the statistics of the normal distribution of deformation velocity per pixel, a total of 77% of the engineering corridor was stable, with a vertical deformation rate between −6.964 mm/yr and −4.844 mm/yr, and 17.7% of the region was sub-stable, with a settling rate of −12.868 mm/yr − –6.964 mm/yr. The unstable regions included areas with settlement rates greater than 12.868 mm/yr and uplift rates greater than 10.748 mm/yr, representing 4.4 percent and 0.9 percent of the total area, respectively, for a total of 5.3 percent. The results of this paper can be used as the theoretical basis and as basic data for decision making and scientific research in various departments, and they are of great significance for surface stability assessment and early warnings along engineering corridors and traffic projects.

Published

2023

4. Research on the Characteristics of Thermosyphon Embankment Damage and Permafrost Distribution Based on Ground-Penetrating Radar: A Case Study of the Qinghai–Tibet Highway

Author

Shunshun Qi, Guoyu Li, Dun Chen, Fujun Niu, Zhizhong Sun, Gang Wu, Qingsong Du, Mingtang Chai, Yapeng Cao, and Jianwei Yue

Subjects

ground-penetrating radar, Qinghai–Tibet highway, permafrost, multi-source data, thermosyphon embankment, embankment damage, Science

Abstract

In order to research the special embankment (thermosyphon embankment) damages and the distribution of permafrost under the Qinghai–Tibet Highway (QTH) embankment. The section K2952–K2953, which is a typical representative of the QTH, was chosen for the detection and research of the permafrost and embankment damages in order to determine the sources of the damages. In this study, the performance characteristics of the embankment, the active layer, and the permafrost table found in ground-penetrating radar (GPR) images were researched, combined with multi-source. According to the research findings, the construction of the embankment in this section has stabilized the effect on the permafrost table. Under the embankment of the unemployed thermosyphon section, the permafrost distribution has good structural integrity and continuity, with the permafrost table at a depth of around 5 m. The continuity of the permafrost distribution under the embankment in the thermosyphon section was poor, and there was localized degradation, with the permafrost table being approximately 6 m deep. The main cause of the irregular settlement and other damage in this section is the presence of a loose area at the base of the embankment. Although the thermosyphon on both sides of the embankment also plays a role in lifting the permafrost table, it is not ideal for managing the damage to high embankments where the type of permafrost under the embankment is high-temperature permafrost with a high ice content and where the sunny–shady slope effect is obvious. The research results described in this article can therefore provide a crucial foundation for the detection of highway damage and permafrost under embankments in permafrost regions in the future.

Published

2023

5. Analysis of Necessity and Feasibility for Ground Improvement in Warm and Ice-Rich Permafrost Regions

Author

Honglei Wang, Hu Zhang, Mingtang Chai, Jianming Zhang, Zhizhong Sun, and Guoyu Li

Subjects

Engineering (General). Civil engineering (General), TA1-2040

Abstract

Characterized by low bearing capacity and high compressibility, warm and ice-rich frozen soil is a kind of problematic soil, which makes the original frozen ground formed by of that unreliable to meet the stability requirements of engineering infrastructures and foundations in permafrost regions. With the design and construction of major projects along the Qinghai-Tibet Engineering Corridor (QTEC), such as expressway and airport runway, it is a great challenge to favor the stability of overlying structures by formulating the proper engineering design principles and developing the valid engineering supporting techniques. The investigations carried out in recent years indicated that warm and ice-rich permafrost foundations were widespread, climate warming was significant, and the stability of existing engineering structures was poor, along the QTEC. When the warm and ice-rich frozen ground is used as the foundation soil, the implementation of ground improvement is an alternative measure to enhance the bearing capacity of foundation soil and eliminate the settlement of structures during operation, in order to guarantee the long-term stability of the structures. Based on the key factors determining the physicomechanical properties of frozen soil, an innovative idea of stabilizing the warm and ice-rich frozen soil based on chemical stabilization is proposed in this study, and then, an in situ ground improvement technique is introduced. This study intends to explore the feasibility of ground improvement in warm and ice-rich permafrost regions along the QTEC based on in situ chemical stabilization and provide the technical support and scientific reference to prevent and mitigate the hazards in the construction of major projects in the future.

Published

2022

6. SBAS-InSAR-Based Analysis of Surface Deformation in the Eastern Tianshan Mountains, China

Author

Qingsong Du, Guoyu Li, Dun Chen, Yu Zhou, Shunshun Qi, Gang Wu, Mingtang Chai, Liyun Tang, Hailiang Jia, and Wanlin Peng

Subjects

surface deformation, Eastern Tianshan Mountains, SBAS-InSAR, environmental impact, cold alpine and high-altitude regions, disaster prevention and mitigation, Science

Abstract

Due to the unique geographical characteristics of cold alpine and high-altitude regions, glaciers, permafrost, ground ice, rock glaciers, and other periglacial geomorphology have developed with fragile habitats, and these areas are often the birthplaces of many river basins and natural hazards. With global warming and the extensive cryogenesis and physical weathering, the thermal state of permafrost and the mass balance of glaciers have been changed, and thus it can be deduced that the surface deformation is of great concern. To obtain ground subsidence or uplift over a large area to understand local surface changes, the small baseline subset interferometric synthetic aperture radar (SBAS-InSAR) technique was applied to process 89-scene of Sentinel-1A images ranging from December 25, 2017 to January 2, 2021 to obtain surface deformation for these 3 years for the eastern Tianshan Mountains, China. The surface deformation characteristics of the area were analyzed to provide a basic dataset for environmental protection policies and mitigation or reduction of natural hazards in this region, and to verify the applicability of SBAS-InSAR technology in alpine and high-altitude areas. The results show that the SBAS-InSAR technique processing with sentinel-1A dataset cannot be effectively used to acquire ground deformation in areas covered by trees, scrub/shrub, glaciers, snow, and ground ice, where the decohered phenomenon is serious. In other regions, SBAS-InSAR can effectively measure surface subsidence or uplift. Surface deformation is significant throughout the study area, with rates ranging from −70.7 to 50.8 mm/a and with an average rate of 1.1 mm/a. There are obvious regions of uplift in the northwest, northeast, and central sections of the study area, with uplift greater than 155.73 mm in 3 years, and three obvious regions of subsidence in the northeast and west sections of the study area, with subsidence of at least −125.20 mm in 3 years. The remaining areas of deformation are scattered, with smaller amounts of settlement and uplift and with an isolated and sporadic distribution. Areas with elevations of 3,150 to 4,275 m.a.s.l., slopes of 15°–50°, and southwest, west, and northwest aspects are geologic disaster-prone regions and should receive more attention and more field monitoring. The results of this study have important implications for local environmental protection and hazard prevention.

Published

2021

7. Route Plans for UAV Aerial Surveys according to Different DEMs in Complex Mountainous Surroundings: A Case Study in the Zheduoshan Mountains, China

Author

Qingsong Du, Guoyu Li, Yu Zhou, Dun Chen, Mingtang Chai, Shunshun Qi, Yapeng Cao, Liyun Tang, and Hailiang Jia

Subjects

InSAR, UAV field survey, practicability analysis, topographic mapping, undulating mountainous terrain, Sentinel-1a, Science

Abstract

Accurate and error-free digital elevation model (DEM) data are a basic guarantee for the safe flight of unmanned aerial vehicles (UAVs) during surveys in the wild, especially in moun-tainous areas with large topographic undulations. Existing free and open-source DEM data gen-erally cover large areas, with relatively high spatial resolutions (~90, 30, and even 12.5 m), but they do not have the advantage of timeliness and cannot accurately reflect current and up-to-date topographical information in the survey area. UAV pre-scanning missions can provide highly accurate and recent terrain data as a reference for UAV route planning and ensure security for subsequent aerial survey missions; however, they are time consuming. In addition, being limited to the electric charge of the UAV, pre-scanning increases the human, financial, and time consumption of field missions, and it is not applicable for field aerial survey missions in reality, unless otherwise specified, especially in harsh environments. In this paper, we used interferometric synthetic aper-ture radar (InSAR) technology to process Sentinel-1a data to obtain the DEMs of the survey area, which were used for route planning, and other free and open-source DEMs were also used for flightline plans. The digital surface models (DSMs) were obtained from the structure of the UAV pre-scan mission images, applying structure for motion (SfM) technology as the elevation reference. Comparing the errors between the InSAR-derived DEMs and the four open-source DEMs based on the reference DSM to analyze the practicability of flight route planning, the results showed that among the four DEMs, the SRTM DEM with a spatial resolution of 30 m performed best, which was considered as the first reference for UAV route plans when the survey area in complex mountainous regions is covered with a poor or inoperative network. The InSAR-derived DEMs from the Sentinel-1 images have great potential value for UAV flight planning, with a large perpendicular baseline and short temporal baseline. This work quantitatively analyzed the errors among the different DEMs and provided a discussion regarding UAV flightline plans based on external DEMs. This can not only effectively reduce the manpower, materials, and time consumption of field operations, improving the efficiency of UAV survey tasks, but it also broadens the use of InSAR technology. Furthermore, with the launch of high-resolution SAR satellites, InSAR-derived DEMs with high spatial and temporal resolutions provide an optimistic and credible strategy for UAV route planning with small errors.

Published

2022

8. A Calculation Model for Ground Surface Temperature in High-Altitude Regions of the Qinghai-Tibet Plateau, China

Author

Mingtang Chai, Nan Li, Furong Liu, Yu Gao, Yanhu Mu, and Wei Ma

Subjects

solar radiation, conversion coefficient, MODIS, ground surface temperature, Science

Abstract

As a major parameter in the energy balance of the ground surface, temperature represents the level of exchange of energy and moisture between the ground and air. The Qinghai-Tibet Plateau (QTP) has the permafrost region with the highest altitude and the largest area in low–middle latitude of the world. The variation in ground surface temperature has an impact on the existence and development of the permafrost. Therefore, the analysis of the ground surface temperature in the QTP is significant to reflect the energy exchange in permafrost regions. This paper collected solar radiation data and calculated the conversion coefficient from total solar radiation to long-wave radiation of the ground surface on different underlying surfaces. The ground surface temperature was inversely calculated and modified based on the reception of solar radiation on different underlying surfaces. A simplified calculation model of ground surface temperature was built to reflect the ground surface temperature on different underlying surfaces of the QTP. The calculation results were compared with MODIS and showed good fitness, providing a systematic and reliable method for calculating the ground surface temperature on the QTP. The above model plays a significant role in the estimation of soil moisture, ground surface energy and water balance.

Published

2022

9. Deformation Monitoring in an Alpine Mining Area in the Tianshan Mountains Based on SBAS-InSAR Technology

Author

Qingsong Du, Guoyu Li, Yu Zhou, Mingtang Chai, Dun Chen, Shunshun Qi, and Gang Wu

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The fragile habitat of alpine mining areas can be greatly affected by surface disturbances caused by mining activities, particularly open-pit mining activities, which greatly affect the periglacial environment. SBAS-InSAR technology enables the processing of SAR images to obtain highly accurate surface deformation information. This paper applied SBAS-InSAR technology to obtain three years of surface subsidence information based on the 89-scene Sentinel-1A SLC products, covering a mining area (tailings and active areas) in the Tianshan Mountains and its surroundings from 25th December 2017 to 2nd January 2021. The data were adopted to analyze the characteristics of deformation in the study region and the mining areas, and the subsidence accumulation was compared with field GNSS observation results to verify its accuracy. The results showed that the study area settled significantly, with a maximum settlement rate of −44.80 mm/a and a maximum uplift rate of 28.04 mm/a. The maximum settlement and accumulation of the whole study area over the three-year period were −129.39 mm and 60.49 mm, respectively. The mining area had a settlement value of over 80 mm over the three years. Significantly, the settlement rates of the tailings and active areas were −35 mm/a and −40 mm/a, respectively. Debris accumulation in the eastern portion of the tailings and active areas near the mountain was serious, with accumulation rates of 25 mm/a and 20 mm/a, respectively, and both had accumulation amounts of around 70 mm. For mine tailing pile areas with river flows, the pile locations and environmental restoration should be appropriately adjusted at a later stage. For gravel pile areas, regular cleaning should be carried out, especially around the mining site and at the tunnel entrances and exits, and long-term deformation monitoring of these areas should be carried out to ensure safe operation of the mining site. The SBAS-InSAR measurements were able to yield deformations with high accuracies over a wide area and cost less human and financial resources than the GNSS measurement method. Furthermore, the measurement results were more macroscopic, with great application value for surface subsidence monitoring in alpine areas.

Published

2021

10. Damage Properties of the Block-Stone Embankment in the Qinghai–Tibet Highway Using Ground-Penetrating Radar Imagery

Author

Shunshun Qi, Guoyu Li, Dun Chen, Mingtang Chai, Yu Zhou, Qingsong Du, Yapeng Cao, Liyun Tang, and Hailiang Jia

Subjects

ground-penetrating radar, Qinghai–Tibet highway, block-stone embankment, permafrost, embankment ratios, Science

Abstract

The block-stone embankment is a special type of embankment widely used to protect the stability of the underlying warm and ice-rich permafrost. Under the influence of multiple factors, certain damages will still occur in the block-stone embankment after a period of operation, which may weaken or destroy its cooling function, introducing more serious damages to the Qinghai–Tibet Highway (QTH). Ground-penetrating radar (GPR), a nondestructive testing technique, was adopted to investigate the damage properties of the damaged block-stone embankment. GPR imagery, together with the other data and methods (structural characteristics, field survey data, GPR parameters, etc.), indicated four categories of damage: (i) loosening of the upper sand-gravel layer; (ii) loosening of the block-stone layer; (iii) settlement of the block-stone layer; and (iv) dense filling of the block-stones layer. The first two conditions were widely distributed, whereas the settlement and dense filling of the block-stone layer were less so, and the other combined damages also occurred frequently. The close correlation between the different damages indicated a causal relationship. A preliminary discussion of these observations about the influences on the formation of the damage of the block-stone embankment is included. The findings provide some points of reference for the future construction and maintenance of block-stone embankments in permafrost regions.

Published

2022

11. The Outburst of a Lake and Its Impacts on Redistribution of Surface Water Bodies in High-Altitude Permafrost Region

Author

Zekun Ding, Fujun Niu, Guoyu Li, Yanhu Mu, Mingtang Chai, and Pengfei He

Subjects

climate warming and wetting, lake outburst, surface water body, continuous permafrost regions, Tibetan Plateau, Science

Abstract

The lakes distributed in permafrost areas on the Tibetan Plateau (TP) have been experiencing significant changes during the past few decades as a result of the climate warming and regional wetting. In September 2011, an outburst occurred on an endorheic lake (Zonag Lake) in the interior of the TP, which caused the spatial expansion of three downstream lakes (Kusai Lake, Haidingnor Lake and Salt Lake) and modified the four independent lake catchments to one basin. In this study, we investigate the changes in surficial areas and water volumes of the outburst lake and related downstream water bodies 10 years after the outburst. Based on the meteorological and satellite data, the reasons for the expansion of downstream lakes were analyzed. Additionally, the importance of the permafrost layer in determining hydrological process on the TP and the influence of from lake expansion on engineering infrastructures were discussed. The results in this study showed the downstream lakes increased both in area and volume after the outburst of the headwater. Meanwhile, we hope to provide a reference about surface water changes and permafrost degradation for the management of lake overflow and flood on the TP in the background of climate warming and wetting.

Published

2022

12. Assessment of Freeze–Thaw Hazards and Water Features along the China–Russia Crude Oil Pipeline in Permafrost Regions

Author

Mingtang Chai, Guoyu Li, Wei Ma, Yapeng Cao, Gang Wu, Yanhu Mu, Dun Chen, Jun Zhang, Zhiwei Zhou, Yu Zhou, and Qingsong Du

Subjects

hazard probability, ponding, water erosion, logistic regression, spatial autocorrelation, Science

Abstract

The China–Russia crude oil pipeline (CRCOP) traverses rivers, forests, and mountains over permafrost regions in northeastern China. Water accumulates beside the pipe embankment, which disturbs the hydrothermal balance of permafrost underlying the pipeline. Ground surface flows along the pipeline erode the pipe embankment, which threatens the CRCOP’s operational safety. Additionally, frost heave and thaw settlement can induce differential deformation of the pipes. Therefore, it is necessary to acquire the spatial distribution of water features along the CRCOP, and analyze the various hazard probabilities and their controlling factors. In this paper, information regarding the permafrost type, buried depth of the pipe, soil type, landforms, and vegetation were collected along the CRCOP every 2 km. Ponding and erosive damage caused by surface flows were measured via field investigations and remote sensing images. Two hundred and sixty-four pond sites were extracted from Landsat 8 images, in which the areas of 46.8% of the ponds were larger than 500 m2. Several influential factors related to freeze–thaw hazards and erosive damage were selected and put into a logistic regression model to determine their corresponding risk probabilities. The results reflected the distributions, and forecasted the occurrences, of freeze–thaw hazards and erosive damage. The sections of pipe with the highest risks of freeze–thaw and erosive damage accounted for 2.4% and 6.7%, respectively, of the pipeline. Permafrost type and the position where runoff encounters the pipeline were the dominant influences on the freeze–thaw hazards, while the runoff–pipe position, buried depth of the pipe, and landform types played a dominant role in erosive damage along the CRCOP. Combined with the geographic information system (GIS), field surveys, image interpretation and model calculations are effective methods for assessing the various hazards along the CRCOP in permafrost regions.

Published

2020

13. Damage characteristics of the Qinghai-Tibet Highway in permafrost regions based on UAV imagery

Author

Mingtang Chai, Guoyu Li, Wei Ma, Dun Chen, Qingsong Du, Yu Zhou, Shunshun Qi, Liyun Tang, and Hailiang Jia

Subjects

Mechanics of Materials, Civil and Structural Engineering

Published

2022

14. Characteristics of Micro-structure of Warm and Ice-Rich Frozen Soil Improved by Cement and Additives

Author

Zhenhua Yin, Jianming Zhang, Hu Zhang, and Mingtang Chai

Subjects

Geopolymer, Cement, Materials science, Hydration reaction, Composite material, Deformation (engineering), Porosity, Compression (physics), Curing (chemistry), Metakaolin, Civil and Structural Engineering

Abstract

In permafrost regions, the warm and ice-rich frozen soil (WIRFS) underlying the embankment has a low strength and large compressibility, which threatens the engineering stability. The addition of cement and its additives can improve the mechanical properties of the WIRFS. During the curing and the thawing compression, the micro-structure of the improved WIRFS was changed by hydration reaction and deformation. In this paper, the porosity and directionality of soil were selected as indicators to reflect the variation of micro-structure in the improved WIRFS. Two image processing methods, fuzzy C-means clustering and image segmentation, were introduced to quantitatively calculate the porosity and the directionality of soil particles. The arrangement variation of soil aggregates can reflect the characteristics of micro-structure during the soil improvement. The results indicate that, the addition of cement and additives reduced the directionality of sample before the thawing compression. After the compression, except for the super absorbent polymer, ironic agent, EN-1, Toogood and geopolymer, the addition of antifreeze agent, early strength agent and metakaolin increased the directionality. The average porosity is negatively relevant to the compressibility coefficient. This paper has connected the micro-structure with deformation parameter of the improved frozen soil, which can reflect the improvement mechanism with cement and additives.

Published

2021

15. Seepage influence of supra-permafrost groundwater on thermal field of embankment on Qinghai-Tibet Plateau, China.

Author

MingTang Chai, Yuan Luo, Yu Gao, Wei Ma, and YanHu Mu

Subjects

WATER seepage, GROUNDWATER, EMBANKMENTS, PERMAFROST, THAWING, HYDROTHERMAL vents

Abstract

As a unique hydro-geological phenomenon in permafrost regions, the seepage of supra-permafrost groundwater will carry a large amount of heat and cause differential settlement in the embankment. This paper presents the results of a field study monitoring the supra-permafrost groundwater levels on both sides of an embankment in permafrost regions. It describes a two-dimensional coupled hydro-thermal model and uses it to analyze the influence of seepage on its temperature field considering climate warming. The results show that seepage exacerbates permafrost thawing and thickens the active layer. The thermal influence on the sunny side of the embankment toe is more significant than that on the shady side, which will cause differential settlement in the embankment. After 50 years of operation, the embankment soil temperature with seepage during freezing is 0.2 (C warmer than that without seepage, and the thermal influence diminished with the increase in depth. Additionally, seepage influences the thermal regime in vertical and horizontal directions of the embankment. During freezing seasons, the thaw depth increases, and the horizontal thaw range decreases. During thawing seasons, the thaw range grows both vertically and horizontally. [ABSTRACT FROM AUTHOR]

Published

2023

16. Mechanical behavior of frozen soil improved with sulphoaluminate cement and its microscopic mechanism

Author

Zhenhua Yin, Jianming Zhang, Hu Zhang, and Mingtang Chai

Subjects

Magnesium phosphate, Cement, Multidisciplinary, Materials science, lcsh:R, 0211 other engineering and technologies, lcsh:Medicine, 020101 civil engineering, 02 engineering and technology, Permafrost, Compression (physics), 0201 civil engineering, law.invention, Portland cement, law, 021105 building & construction, Particle-size distribution, Soil water, lcsh:Q, Deformation (engineering), Composite material, lcsh:Science

Abstract

The foundation of constructions built in the permafrost areas undergo considerable creeping or thawing deformation because of the underlying ice-rich permafrost. Soil improvement may be of advantage in treating ice-rich permafrost at shallow depth. Sulphoaluminate cement was a potential material to improve frozen soil. Simultaneously, two other cements, ordinary Portland cement and Magnesium phosphate cement were selected as the comparison. The mechanical behavior of modified frozen soil was studied with thaw compression tests and unconfined compression strength tests. Meanwhile, the microscopic mechanism was explored by field emission scanning electron microscopy, particle size analysis and X-ray diffractometry. The results showed Sulphoaluminate cement was useful in reducing the thaw compression deformation and in enhancing the strength of the frozen soil. The improvement of the mechanical behavior depended mainly on two aspects: the formation of structural mineral crystals and the agglomeration of soil particles. The two main factors contributed to the improvement of mechanical properties simultaneously. The thicker AFt crystals result in a higher strength and AFt plays an important role in improving the mechanical properties of frozen soils.The study verified that Sulphoaluminate cement was an excellent stabilizer to improve ice-rich frozen soils.

Published

2020

17. Effectiveness of Ionic Polymer Soil Stabilizers on Warm Frozen Soil

Author

Mingtang Chai, Jianming Zhang, Hu Zhang, and Zhilong Zhang

Subjects

chemistry.chemical_classification, Chemistry, 0211 other engineering and technologies, Ionic bonding, 02 engineering and technology, Polymer, urologic and male genital diseases, complex mixtures, Response to treatment, Animal science, 021105 building & construction, Mechanical strength, Water content, Curing (chemistry), 021101 geological & geomatics engineering, Civil and Structural Engineering

Abstract

Warm frozen soil has characteristics such as low shear strength and high compressibility. To improve its mechanical strength, the ionic polymer soil stabilizers (IPSS): named XRH stabilizer and acid cation exchange resin (CER) were adopted for reinforcing the warm frozen soil from the Beiluhe region of the Qinghai-Tibetan Plateau. To evaluate the effects of IPSS on warm frozen soil and analyze the mechanisms responsible, measurements were made of the physical, chemical and mechanical properties of warm frozen soil, both untreated and following treatment with IPSS. The addition of IPSS to the soil resulted in a significant decrease in the plasticity index, freezing temperature, and cation-exchange capacity of soil. The warm frozen soil were reinforced with XRH and CER, the cohesion increased by 87.9% and 43.1%, respectively, and the compressibility decreased by 44.5% and 41.1%, respectively. The trends of mechanical strength and unfrozen water content of reinforced warm frozen soil were the same, with extreme values being observed in response to treatment with an IPSS content of about 1% (optimal proportion). In addition, the curing mechanism of IPSS on warm frozen soil was analyzed. Overall, applying IPSS to the soil was an effective and feasible measure for reinforcing a warm frozen soil foundation.

Published

2019

18. Thermal influences of stabilization on warm and ice-rich permafrost with cement: Field observation and numerical simulation

Author

Hu Zhang, Jianming Zhang, Mingtang Chai, Zhenhua Yin, Yanhu Mu, and Wei Ma

Subjects

Cement, Curing (food preservation), Materials science, Field (physics), 020209 energy, Mixing (process engineering), Energy Engineering and Power Technology, Soil science, 02 engineering and technology, Radius, Thermal conduction, Permafrost, Industrial and Manufacturing Engineering, 020401 chemical engineering, Thermal, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering

Abstract

In this paper, the dry cement was mixed with warm and ice-rich permafrost to improve its mechanical and physical properties. The changes of temperature of improved soil with different cement dosage were measured by in-situ test. Then, the temperature field of the improved soil in-situ test was calculated by mathematical model of heat conduction and hydration equation with consideration of temperature effect. Based on the built calculation model, we have simulated the radius of thermal disturbance and refreezing time in the process of improvement on warm and ice-rich permafrost with deep mixing method. It can be concluded from the results that, (1) heat transfer model with temperature effect can precisely calculate the changes of temperature field during the curing of cemented frozen soil; (2) in the field test, when the cement dosage is less than 15% by weight of frozen soil, the increase of temperature in cemented soil is not obvious, the peak of temperature increase appears only when the dosage is more than 20%; (3) when the dry deep mixing method with is adopted to improve the warm and ice-rich permafrost, the maximum radius of thermal disturbance increases exponentially with the decrease of mean annual ground temperature, the refreezing time decreases hyperbolically with the decrease of mean annual ground temperature.

Published

2019

19. Deformation Monitoring in an Alpine Mining Area in the Tianshan Mountains Based on SBAS-InSAR Technology

Author

Guoyu Li, Mingtang Chai, Dun Chen, Shunshun Qi, Wu Gang, Qingsong Du, and Yu Zhou

Subjects

Materials science, 010504 meteorology & atmospheric sciences, GNSS augmentation, Article Subject, Settlement (structural), 0211 other engineering and technologies, General Engineering, Subsidence, 02 engineering and technology, 01 natural sciences, Debris, Tailings, Deformation monitoring, Mining engineering, Interferometric synthetic aperture radar, Groundwater-related subsidence, TA401-492, General Materials Science, Materials of engineering and construction. Mechanics of materials, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

The fragile habitat of alpine mining areas can be greatly affected by surface disturbances caused by mining activities, particularly open-pit mining activities, which greatly affect the periglacial environment. SBAS-InSAR technology enables the processing of SAR images to obtain highly accurate surface deformation information. This paper applied SBAS-InSAR technology to obtain three years of surface subsidence information based on the 89-scene Sentinel-1A SLC products, covering a mining area (tailings and active areas) in the Tianshan Mountains and its surroundings from 25th December 2017 to 2nd January 2021. The data were adopted to analyze the characteristics of deformation in the study region and the mining areas, and the subsidence accumulation was compared with field GNSS observation results to verify its accuracy. The results showed that the study area settled significantly, with a maximum settlement rate of −44.80 mm/a and a maximum uplift rate of 28.04 mm/a. The maximum settlement and accumulation of the whole study area over the three-year period were −129.39 mm and 60.49 mm, respectively. The mining area had a settlement value of over 80 mm over the three years. Significantly, the settlement rates of the tailings and active areas were −35 mm/a and −40 mm/a, respectively. Debris accumulation in the eastern portion of the tailings and active areas near the mountain was serious, with accumulation rates of 25 mm/a and 20 mm/a, respectively, and both had accumulation amounts of around 70 mm. For mine tailing pile areas with river flows, the pile locations and environmental restoration should be appropriately adjusted at a later stage. For gravel pile areas, regular cleaning should be carried out, especially around the mining site and at the tunnel entrances and exits, and long-term deformation monitoring of these areas should be carried out to ensure safe operation of the mining site. The SBAS-InSAR measurements were able to yield deformations with high accuracies over a wide area and cost less human and financial resources than the GNSS measurement method. Furthermore, the measurement results were more macroscopic, with great application value for surface subsidence monitoring in alpine areas.

Published

2021

20. A method for calculating unfrozen water content of silty clay with consideration of freezing point

Author

Yanhu Mu, Zhenhua Yin, Jianming Zhang, Gaochen Sun, Mingtang Chai, and Hu Zhang

Subjects

Materials science, 010504 meteorology & atmospheric sciences, Water activity, Capillary action, 0211 other engineering and technologies, Thermodynamics, Geology, 02 engineering and technology, 01 natural sciences, Kelvin equation, Freezing point, symbols.namesake, Volume (thermodynamics), Geochemistry and Petrology, symbols, Bound water, Negative temperature, Water content, Physics::Atmospheric and Oceanic Physics, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

A physical calculation model for the content of unfrozen water of silty clay was proposed with a consideration of freezing point. The freezing point of bulk water, capillary water and bound water was calculated. The freezing point of bulk water was assumed to be constant in the calculation. The Kelvin equation and the theory of water activity were used to calculate the freezing-point changes of the capillary and bound water during the volume decrease, respectively. The influence of soil-particle size on the freezing point was taken into account in the model. In the calculation, the unfrozen water content at a negative temperature was defined as the sum of the volume of capillary and bound water whose freezing point was lower than the given temperature. By using silty clay from the Qinghai-Tibet Plateau as an example, the results of the model calculations were validated by using the measured data from time-domain reflection and nuclear magnetic resonance. The calculations for four existing models as proposed by other scholars were listed for comparison with our model. The results show that the calculated results of our model are precise and reflect the hysteresis effect of the unfrozen water content during freezing and thawing. The model validated an order of freezing in soil: bulk water froze first, most capillary water froze next, and most bound water froze last. This paper explains the existence of unfrozen water from the perspective of freezing-point change and provides a theoretical basis for the calculation.

Published

2018

21. Effect of cement additives on unconfined compressive strength of warm and ice-rich frozen soil

Author

Mingtang Chai, Hu Zhang, Jianming Zhang, and Zhilong Zhang

Subjects

Cement, Materials science, 010504 meteorology & atmospheric sciences, Silica fume, Sodium lignosulfonate, 0211 other engineering and technologies, Sodium silicate, 02 engineering and technology, Building and Construction, 01 natural sciences, chemistry.chemical_compound, Compressive strength, chemistry, Soil water, General Materials Science, Composite material, Water content, Metakaolin, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Civil and Structural Engineering

Abstract

The effect of nine cement additives on the unconfined compressive strength (UCS) of warm and ice-rich frozen soils was analyzed. After 7 days of curing at −1 °C, the UCS at −1 °C, the freezing-point depression and changes in the water content of soil samples were measured to explore the additive effect and mechanism. The optimum additive dosage was determined to improve engineering applications. The conclusions were: (1) attapulgite, metakaolin, nano-silicon dioxide (SiO2), silica fume and hardener accelerator increased the UCS by reducing the water content of frozen soils; (2) sodium hydroxide (NaOH), sodium silicate (Na2SiO3) and sodium lignosulfonate thawed the ice and reduced the UCS of frozen soil samples; (3) when frozen soil with a water content of 30% and 90% was mixed with 15% cement, the optimum dosages were 2% and 8% metakaolin and 0.49% and 0.62% hardening accelerator, respectively.

Published

2017

22. Analysis of thermal regime under riverbank in permafrost region

Author

Hu Zhang, Enliang Wang, Jianming Zhang, Mingtang Chai, Mingyi Zhang, and Zhilong Zhang

Subjects

Convection, Computer simulation, 0211 other engineering and technologies, Energy Engineering and Power Technology, 02 engineering and technology, 010502 geochemistry & geophysics, Thermal conduction, Permafrost, 01 natural sciences, Industrial and Manufacturing Engineering, Hydraulic structure, Heat transfer, Thermal, Geotechnical engineering, Geothermal gradient, Geology, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

A riverbank was constructed on ice-rich permafrost in the far north of China in 2015, and its performance is closely related to the thermal stability of the permafrost foundation. To investigate the thermal regime evolution of the foundation, a numerical simulation using a coupled hydro-thermal model that involves concrete hydration, heat transfer by conduction and convection is performed over 20 years in this paper. The monitored ground temperatures help confirm the accuracy of the simulation. A dramatic thaw penetration in the permafrost foundation is anticipated in the future under current geological and structural conditions. Moreover, this paper highlights the importance of concrete hydration, backfilled soil temperature, seepage and the mean annual ground temperature in effecting the geothermal evolution. These discussions suggest a requirement for some measures in construction and maintenance of hydraulic structures over permafrost.

Published

2017

23. Distribution Characterization Study of the Heavy Metals for a Mining Area of East Tianshan Mountain in Xinjiang Based on the Kriging Interpolation Method

Author

Qingsong Du, Guoyu Li, Yu Zhou, Gang Wu, Mingtang Chai, and Fayong Li

Abstract

In order to understand the impact of mining development on the environment, a metal mine at east Tianshan Mountain in Xinjiang province was used as the object of study. The heavy metal content data were obtained from field sampling and indoor measurements, and the data were compared with the heavy metal background values, applying the geostatistic method and Kriging spatial interpolation theory to map the heavy metal distribution in the study area. The results show that the overall heavy metal contamination in the mining area is serious, with significant accumulation of As, Cd and Cr, which is a threat to local human and animal health. And there are obvious correlations and synergies between the distribution of these heavy metals, mostly showing positive correlations, which should be taken into more account in the subsequent environmental rehabilitation of the mine site.

Published

2021

24. Measuring the long-term deformation of in-situ ice-rich permafrost using a plate loading test

Author

Zhilong Zhang, Hu Zhang, Jianming Zhang, and Mingtang Chai

Subjects

In situ, geography, Plateau, geography.geographical_feature_category, Settlement (structural), Applied Mathematics, 020208 electrical & electronic engineering, 010401 analytical chemistry, 02 engineering and technology, Deformation (meteorology), Condensed Matter Physics, Permafrost, 01 natural sciences, Permafrost Region, 0104 chemical sciences, Ground temperature, 0202 electrical engineering, electronic engineering, information engineering, Table (landform), Geotechnical engineering, Electrical and Electronic Engineering, Instrumentation, Geology

Abstract

In order to determine the long-term deformation behavior of in-situ ice-rich permafrost under natural conditions, three deformation setups utilizing a plate loading method were built in a permafrost region on the Qinghai–Tibetan Plateau. The loading plates were installed just below the permafrost table, and loads were applied via platforms that were held constant throughout. Variations in permafrost deformation and ground temperatures were recorded over a period of five years. Test results show that ground temperature at the loading plate depth fluctuated seasonally within a warm range between −3.0 °C and −0.2 °C, while the frozen ground settled over a considerable range, between 60 mm and 230 mm. Deformation was observed to be step-like in behavior, given an external load of 0.25 MPa. The amount of settlement observed during deformation was significantly influenced by ground temperature and ice content.

Published

2020

25. Characteristics of Asphalt Pavement Damage in Degrading Permafrost Regions: Case Study of the Qinghai–Tibet Highway, China

Author

Ge Liu, Mingtang Chai, Jianbing Chen, Jianming Zhang, Yanhu Mu, and Wei Ma

Subjects

010504 meteorology & atmospheric sciences, Serviceability (structure), Global warming, 0211 other engineering and technologies, 02 engineering and technology, Geotechnical Engineering and Engineering Geology, Permafrost, 01 natural sciences, Industrial and Manufacturing Engineering, Permafrost degradation, Asphalt pavement, Environmental science, Geotechnical engineering, China, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

In the context of climate warming, damage to road pavements and embankments in permafrost regions caused by thawing of underlying permafrost severely reduces the serviceability of roads. In...

Published

2018

26. Improvement of Compressibility and Thaw-Settlement Properties of Warm and Ice-Rich Frozen Soil with Cement and Additives

Author

Mingtang Chai and Jianming Zhang

Subjects

Materials science, Scanning electron microscope, 0211 other engineering and technologies, 02 engineering and technology, Permafrost, lcsh:Technology, Article, chemistry.chemical_compound, scanning electron microscope (SEM), 021105 building & construction, General Materials Science, calcium silicate hydrate, Composite material, Calcium silicate hydrate, lcsh:Microscopy, Water content, Curing (chemistry), lcsh:QC120-168.85, 021101 geological & geomatics engineering, Cement, thaw strain, lcsh:QH201-278.5, lcsh:T, compression coefficient, Microstructure, chemistry, lcsh:TA1-2040, Soil water, lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, lcsh:Engineering (General). Civil engineering (General), lcsh:TK1-9971, permafrost

Abstract

The warm and ice-rich frozen soil (WIRFS) that underlies roadway embankments in permafrost regions exhibit large compression and thaw deformation, which can trigger a series of distresses. Cement and additives were used in this study to improve the compressibility and thaw-settlement properties of WIRFS. We, therefore, selected optimum additives and studied the improvement effect on the frozen soil with 30% water content based on our previous research. Given constant load and variable temperatures, compression coefficients, thaw strains, and water content changes were obtained at temperatures of &minus, 1.0 &deg, C, &minus, 0.5 &deg, C, and 2.0 &deg, C to evaluate the effect of improvements. A scanning electron microscope (SEM) was then used to observe the microstructure of improved soils and analyze causal mechanisms. Data show that hydration reactions, physical absorptions, cement, and additives formed new structures and changed the phase of water in frozen soil after curing at &minus, C for 28 days. This new structure, cemented with soil particles, unfrozen water, and ice, filled in the voids of frozen soil and effectively decreased the WIRFS compression coefficient and thaw strain.

Published

2019

27. Investigation of the Pore-Water Pressure of Saturated Warm Frozen Soils Under a Constant Load

Author

Mingtang Chai, Hu Zhang, Jianming Zhang, and Zhilong Zhang

Subjects

010504 meteorology & atmospheric sciences, Mechanical Engineering, 0211 other engineering and technologies, Ocean Engineering, 02 engineering and technology, 01 natural sciences, Pore water pressure, Permeability (earth sciences), Soil water, Environmental science, Constant load, Geotechnical engineering, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

A series of compression experiments was conducted to observe the pore-water pressure variations of saturated warm frozen soils over time. The results indicate that saturated warm frozen soils can exhibit excess pore-water pressure when subjected to external loads. The pore-water pressure fluctuates rather than varying monotonically, and it gradually increases with increasing compressive deformation as the pores are compressed. Furthermore, the permeability of the soil allows pressure dissipation. Thus, the pore-water pressure is continuously changing because of the interactions between these two opposing processes. The peak pore-water pressure follows an exponential relationship with the soil temperature and decreases to a steady value as the temperature decreases. A dissipation trend is observed after the peak pressure is reached. This trend reflects the influence of consolidation in the deformation of warm frozen soils. As the temperature increases, the role of the consolidation becomes more significant.

Published

2016

28. Investigation of the Pore-Water Pressure of Saturated Warm Frozen Soils Under a Constant Load.

Author

Hu Zhang, Jianming Zhang, Zhilong Zhang, and Mingtang Chai

Published

2016