Study of Structural and Compression Properties of Soft Soils in Kunming at Different Moisture Contents

Te structure of soil refers to the properties and arrangement of soil particles and pores, as well as their interactions, which have a signifcant impact on the mechanical behavior of soil. Clarifying the strengths and weaknesses of soil structure can efectively ensure engineering safety during designing. In this study, the structural soft soil in the Wujiaba area of Kunming City was studied. A comprehensive structural parameter c was proposed by analyzing one-dimensional consolidation test data, which consider both the moisture content and yield stress. Due to its high moisture content and lacustrine features, the soft soil in Kunming possessed obvious structural characteristics. As the moisture content increased, the structural characteristics of the soft soil gradually weakened, making it more prone to compression failure. Moreover, the initial consolidation pressure decreased with the increase in moisture content. And the soft soil was more susceptible to deformation failure with higher moisture content. Te conclusions drawn from this study have important implications for predicting the settlement of layered soft soil foundations.


Introduction
Soil exhibits structural characteristics in a broad sense [1].At the microscopic level, these characteristics refer to the properties and arrangement of soil particles and pores, as well as their interactions.Macroscopically, structural characteristics can be described as the mechanical efects of soil structure.When exposed to external forces, the structural characteristics of soil play a crucial role in determining its mechanical behavior, making them a critical parameter for studying soil strength.Structural soft soil is widely distributed worldwide, including the southern coast of South Korea, Mexico City, and other regions.In China, structural soft soil is primarily found in Shanghai, Guangzhou, and Kunming.Structures built on soft soil layers with structural characteristics are highly susceptible to severe settlement deformation, such as buildings, bridges, tunnels, and other constructions.Due to the presence of silty clay layers on the site, the design did not consider the worst geological conditions, combined with heavy rainfall, which resulted in the collapse of a deep foundation pit project in the northwest of Shenzhen in 2018.Furthermore, a collapse occurred at the Nicoll Highway subway station in Singapore in April 2004 because of the rupture of the retaining wall caused by the soft clay layer underlying the excavation when the excavation reached a depth of 34.2 m [2].
Extensive research has been conducted on structuresensitive soft soil from various angles in recent decades.As such, Li and Shou-yi determined the preconsolidation pressure of soil by studying disturbed soil samples and formulated relevant mathematical equations [3,4].Whereas, the general applicability of this formula in structured soil is relatively low.Yu et al. investigated in depth a timedependent deformation mechanism obtained the viscoelastic-plastic deformation of soft soil using a nonassociated fow rule and an improved Nishihara model [5].However, the complexity of the constitutive model makes it challenging to obtain the parameters, increasing the difculty of its application in engineering.Jian-qing et al. analyzed the creep characteristics of Dongting Lake's structured soft soil through triaxial tests and established a calculation model that considered the infuence of confning pressure and consolidation state [6].Tis conclusion is widely used in the low moisture content of the structured soft soils in the region, while its applicability in areas with high moisture content soft soils is mediocre.Currently, most research on structured soft soil focuses on solids, but changes in conditions such as moisture content and vibration can also alter the mechanical properties of soft soil, sometimes exhibiting fow characteristics [7][8][9].From a mechanism analysis perspective, there are signifcant variations in the structure of the soil across diferent regions, which also result in variations in the mechanical properties of the soil.Structural soft soil in the same region exhibits signifcant diferences in mechanical properties at diferent moisture contents.Te soft soil in Kunming area belongs to lacustrine sedimentary soil and contains multiple layers of peat soil with high organic matter content, low shear strength, high compressibility, poor seismic performance, and a tendency to uneven settlement.Currently, limited research has been conducted on high moisture content areas of structure-sensitive soft soil, which are mostly marine or river sedimentary soft soil [10,11].Terefore, conducting research on structure-sensitive soft soil in the Wujiaba area of Kunming is of signifcant importance.
Tis paper focuses on studying the soft soil in the Wujiaba area of Kunming and introduces the concept of structural parameter c, which is obtained through onedimensional consolidation tests, feld measurements, mathematical calculations, and analysis.In particular, compared with traditional formulas, this parameter can intuitively refect the impact of soil structure on compressibility by analyzing the one-dimensional compression curve.Te study analyzes the structural strength and preconsolidation pressure of soft clay with diferent moisture content from multiple perspectives, providing critical insights for predicting the settlement of structural soft clay buildings and foundations after construction.

Experimental Section
2.1.Materials.Located in the middle Yunnan Plateau, Kunming is a typical inland faulted basin, primarily consisting of lacustrine sediments, swamp sediments, and river fat deposits.Soft soil deposits of the Holocene period, predominantly peaty soil, which are distributed mainly from the southern city of Kunming to the north of Dianchi Lake.Te study area and soil samples are situated in the western part of Baisha River Road in the Wujiaba area of Kunming City, which is generally fat and open.Te soil in this area is structurally soft and widely distributed.Based on geological data from the Kunming region and analogous engineering strata, the drilled soil layers can be classifed into 10 major layers and 16 sublayers, primarily consisting of clay, silt, and peaty soil.Peaty soil exists in seven of the exposed geological layers and is widely distributed in the study area in the form of interlayers, or lenticels.It possesses relatively poor engineering mechanical properties.

Moisture Content Test.
Te soil used for this experiment was obtained from the interior of the excavation foundation pit.Te moisture content of the initial soil was measured using the oven-drying method.Specifcally, 15-30 g of representative soil samples were placed in a weighing box, and the wet soil mass was measured.Te samples were then dried in a 105 °C oven for 8-10 h until the weight stabilized, and the dry soil mass was measured.Te moisture content of the soil sample was calculated as the ratio of the diference between the wet and dry soil masses to the dry soil mass.

One-Dimensional Consolidation Test.
To investigate the structural yield characteristics of Kunming soft soil under various moisture contents and loads, indoor onedimensional consolidation tests were conducted.Five natural moisture content samples (79%, 116%, 118%, 126%, and 169%) were specifcally chosen to examine the efect of moisture content on the structural behavior of Kunming soft soil.
Te indoor one-dimensional consolidation experiment was conducted in strict accordance with the soil testing method standard (GBT50123-2019) using a conventional consolidation apparatus.Te sample had an initial height of 20.0 mm and an inner diameter of 61.8 mm.Prior to sample installation, the inner wall of the consolidation apparatus was coated with silicone oil to reduce friction.To ensure double-side drainage and sample stability, absorbers with a flter paper were placed at both ends of the sample.Te test involved loading at increments of 12.5 kPa, 25 kPa, 50 kPa, 100 kPa, 200 kPa, 400 kPa, 800 kPa, 1200 kPa, 1600 kPa, and 3200 kPa, respectively.In addition, a load-unload-reload consolidation test was also performed.In this test, the reloading was carried out step by step according to the loading mode described above until it reached 800 kPa and then unloaded to 100 kPa.After the deformation stabilized, the sample was loaded to 800 kPa at the same rate as the initial loading.Te consolidation or rebound stabilization time for each stage of loading or unloading in the test was 24 h.

Research Methods and Ideas
Soft soil is generally characterized by a certain structure, high sensitivity, low strength, and low structural strength.After the excavation of foundation pits, perimeter unloading or dynamic loads can reduce the strength of soft soil and increase deformation, which has an adverse efect on the surrounding environment around the pit inversely [12].To fully investigate the changes in mechanical parameters, such as yield stress, undrained shear strength, compression index, and consolidation coefcient of soft soil in the Kunming area after disturbance, the structural properties of soft soil were analyzed by using the e − log p curve, the e − p curve, and compression index data.Alternatively, the correlation between the moisture content and the structural properties of soft soil was deduced.

2
Shock and Vibration

Compression Deformation Analysis of Soft Soil in the Study
Area.After studying the structural soft soil samples, it was discovered that the physical and mechanical characteristics of the soil layers signifcantly difered based on their moisture content.Among them, the moisture content of peaty soil layers ranges from 75% to 180%, with a natural porosity ratio of over 2 and a standard penetration number of less than 6.Although the compressive strength is low, the organic matter content is around 30%.And the bearing capacity is poor.Te structural response of peaty soils to vibration is distinct from that of clay and silt (as shown in Figure 1).Tis study exclusively focuses on the analysis of peat-like soil samples with distinctive properties in the stratum.
Te compression p − s curves and e − log p curves were obtained through a one-dimensional consolidation test on soil samples with varying moisture content (Figure 2).It is evident that the compression response of soil remains consistent across diferent moisture contents, and the trend of soil deformation is consistent as well.With the increase in vertical pressure, the deformation gradually increases.Te p − s curve (Figure 2(b)) indicates that the sample with 169% moisture content undergoes a deformation of approximately 10 mm at the same stress level.Te e − log p curve (Figure 2(c)) exhibits a clear infection point for soft soil with large pore spaces, corroborating the characteristics of overconsolidated soil.When the vertical stress is less than the corresponding value at the infection point, the soil undergoes predominantly elastic deformation.But beyond this point, the unrecoverable plastic deformation of the soil increases sharply, which is manifested by a signifcant reduction in strength and a greater compressibility and yielding of the soil.Moreover, the e − log p curve reveals an early appearance of the infection point with increasing moisture content.Te infection point pressure value of the 169% soil sample is approximately 200 kPa, while that of the 79% soil sample is as high as 880 kPa.Tese results indicate that high moisture content induces lower yielding loadbearing capacity in the soft soil structure.Furthermore, the load causing the structural failure of soil and its yielding force are negatively correlated with the moisture content.After the load exceeds the yield stress, the e − log p curve of diferent moisture content soil samples closely approximates a straight line, and the slope of the straight line is the compression index C c of the undisturbed soil.Te pore ratio at the infection point represents the yield pore ratio e y .
Observations derived from Figure 2(d) indicate that, at the same vertical pressure levels, an increase in the moisture content of soil samples leads to a reduction in compression modulus, while the strength and stifness of the soft soil with lower moisture content are greater.Te vertical pressure curve exhibits a negligible attenuation process up to 2000 kPa, primarily attributable to the resilient structural properties of soft soil.Initially, the soil's inherent structural components oppose external forces, and upon exceeding yield stress, the pores get compressed, causing a steady escalation in compression modulus with increasing pressure.Tis phenomenon is consistent with Li et al.'s observations, indicating that the soft soil in Kunming belongs to the category of high-moisture-content structured soft soil [13].
Drawing upon the fndings of the aforementioned experimental outcomes and the distinct properties of soft soil prevalent, this paper establishes the moisture contentcompression index correlation as a key indicator for evaluating soil structural integrity.Figure 3 illustrates the resultant curve and ftting equation C c � 2.91 − 0.045e + 2.37×10 − 4 e 2 (R 2 � 0.99).A higher compression index signifes greater compressibility and enhanced deformation capacity of the soft soil.Te data presented in Figure 3 confrm that C c values are 2.03 and 0.831 at moisture contents of 169% and 79%, respectively, thereby lowering the stress threshold for soft soil structural Shock and Vibration 3 yielding.Te data also highlight that the structural yield stress decreases with an increase in soil moisture content, and consequently, even small loads can result in compression deformation.

Structural Parameters.
According to the onedimensional compression e − log p curves, Liu and Carter et al. studied the diference in porosity corresponding to specifc vertical pressure values, and they believed that this diference could refect the diference between the undisturbed soil and the disturbed soil [14][15][16][17][18].To further refne the evaluation of soil structural properties, Xie and Qi introduced the concept of integrated structural potential parameters, which allows the concept of structural properties to be better expressed [19].In a subsequent study, Cun-li et al. verifed a correlation between vertical pressure, vertical deformation, and pore ratio, culminating in the development of a structural parameter m c [20].Meanwhile, Zai-qiang et al. performed dynamic triaxial tests on relic soils subjected to varied glutinous rice slurry admixtures following dry-wet cycles and obtained the dynamic and structural properties of artifcially prepared relic soils [21].Normalized ftting equations were then formulated to capture the response of soil samples under dry-wet conditions.
In order to comprehensively consider the efects of void ratio and yield stress, this paper introduces the structural index W. Specifcally, W is calculated as the defnite integral of ∆e 1 over the interval [0, logp y ], denoting the area confned by the e − log p curve of a given soil sample and its corresponding idealized remodeling curve (see Table 1) For structured soils, the region bounded by the compression curve and the hypothetical reshaped curve following reduction is termed as the intrinsic structural index W * .It is mathematically represented by the integral of ∆e 2 over the interval [0, logp y ] W * �  P y 0 ∆e 1 dp. (2) Equation ( 1) provides a means to derive the structural parameter c, which is informed by two distinct indices, namely, those depicted in Figure 4 c � W W * . (3)

Validity Verifcation.
To validate the efectiveness of the proposed structural parameters c, this study conducted statistical analysis on compression characteristic data collected from prior research.Te diference in these values indicates that c can refect the changes in structural behavior during compression based on the characteristics of the soil sample and comprehensively refect the variability and stability of soft soil.Tese data also demonstrate the efectiveness of the parameter.

Calculation Results and Discussion
. Te current feld sampling methods and various external factors contribute to a certain degree of soil sample disturbance.Strictly speaking, the results of structural soil analysis using feld test data may not accurately refect the actual soil conditions.Li and Shouyi developed a mathematical model specifcally for in-situ samples, yet it remains inadequate for analyzing structural soils [3].In light of this, Shen proposed replacing the concept of overconsolidation ratio for structural soils with the structural stress ratio s [26].Furthermore, the prior consolidation pressure calculated by the code should be referred to as the structural yield stress σ.Building upon this, Guoxin et al. improved the mathematical model by incorporating the structural yield pressure in place of the original overburden pressure P 0 [27].Tis modifcation enables the calculation of the compression curve relationship for in-situ soil, as expressed in the following equation: where e 1 represents the pore ratio at a pressure of 1 kPa, which may be substituted with the initial pore ratio e 0 ; C r denotes the compression index of the perfectly reshaped sample, which is defned as the slope of the compression curve of the said sample; C s is the rebound index of the reshaped sample, which is defned as the slope of the line connecting the end points of the rebound hysteresis circle of the reshaped sample; σ k signifes the yield pressure of the structure in its original state; and P L represents the pressure value at the intersection of the compression curve of the reshaped sample and the original sample, which is taken as the pressure value corresponding to the compression curve at 0.59e 0 according to previously established literature.A represents the reduction coefcient that characterizes the compression curve following reduction.Utilizing equations ( 4) and ( 5), the present study selected data from a soil sample with a moisture content of 169% to demonstrate the principal calculation process and explained  (1) Te compression index C r and rebound index C s , calculated from the one-dimensional consolidation test compression and rebound curves, were found to be 0.108 and 0.052, respectively.Te corresponding pressure P L � 1355 kPa was obtained at the intersection point of ideal remolded soil.(2) Initial pore ratio e 0 � 3.658 and σ k � 336.6 kPa, the abovementioned calculated values of C r , C s , and P L , were substituted into equation ( 5) to calculate the reduced compression curve and to derive the calculated equation e � 3.658 − 0.0028(log p) 4.2 .Tis equation was plotted to produce a graph, as illustrated in Figure 5. (3) Using the Casagrande method, the compression curve after reduction was computed, resulting in a prior consolidation pressure value of P c � 183.5 kpa.

Shock and Vibration
From equations ( 4) and ( 5), as well as the compression curves illustrated in Figure 6, the structural parameter c corresponding to diferent moisture contents can be obtained.Te results show that as the moisture content increases from 79% to 169%, the value of the structural index W increases continuously, but the normalized structural parameter c gradually decreases.Tese results suggest a negative correlation between the structural parameters and the moisture content of soft soil.Considering the relevant defnitions of structural parameters, it becomes apparent that as the moisture content of soft soil increases, the yield stress decreases, and that higher levels of moisture content may result in the soil being more susceptible to deformation under relatively low loads.
After ftting the data, a relationship between the structural parameters and the moisture content was established, as illustrated in Figure 7. Te equation for this relationship is c � 2.09 − 0.021e + 6.52 × 10 − 5 e 2 (R 2 � 0.97).Since soft soils possess structural properties, their mechanical deformation is signifcantly infuenced by structural yielding damage.Figure 7 demonstrates that the structural parameter is only 0.42 at a moisture content of 169%, and it fuctuates around 0.5 at a moisture content near 120%.Te structural parameter of the soft soil decreases exponentially with the increase of moisture content.Tis trend can be attributed to the elevated internal moisture content of soft soils, which reduces the solidifcation association between soil particles and weakens the structural properties of the soil.
From the information presented in Figure 6, the prior consolidation pressure values for soft soils with diferent moisture contents can be calculated using the Casagrande method, as shown in Table 3. Tese values of P c provide a clearer insight into the connection between moisture content and yield stress.Te correlation is shown in Figure 8 and can be represented by the ftted equation P c � 2021.8 − 11.9e − 0.006e 2 (R 2 � 0.91).It is important to note that P c is a key parameter in the analysis of soft soil deformation behavior, as it refects the initial consolidation state of the soil and is an indicator of the soil's bearing capacity.Shock and Vibration Te incorporation of structural parameters and the analysis of P c values discovered the inference that the yield stress of soft soils is inversely proportional to their moisture content.Te parameter c is a direct refection of the correlation between moisture content and vertical pressure in soft soils.As illustrated in the preceding section, the higher the moisture content, the smaller the value of c, making the soil more prone to failure under the same load.Te formula can be used along with onedimensional consolidation test data to calculate the value of the structural parameter expressed in void ratio form in any state.In engineering design, the soil's structural strength can be estimated, and its compressive strength predicted by integrating the moisture content and vertical pressure of the area.Hence, when constructing buildings or tunnels in areas with high moisture content, extra caution must be exercised in designing and selecting support methods to prevent potential safety hazards.

Conclusion
Tis paper presents the following conclusions based on the analysis of soft soils with high moisture content in the Wujiaba area of Kunming: (1) With increasing moisture content, the structural properties of soft soils weaken, resulting in a higher susceptibility to deformation under relatively low loads.(2) Te structural parameter c can comprehensively consider the efects of void ratio and yield stress.By analyzing the one-dimensional consolidation tests and prior consolidation pressure values, an obvious decay of c with increasing moisture content was observed in the study area.
(3) Soft soils in Kunming exhibit unique characteristics, such as a high organic matter content of 30% and moisture content ranging from 75% to 180%, and a pore ratio exceeding 2, indicating high structural properties.(4) Te soft soil compression index generally increases with moisture content, while this increase decreases the pressure value corresponding to the yield of the soft soil structure.
In summary, the fndings highlight the of considering the structural properties of soft soils when designing and constructing buildings or tunnels in areas with high moisture content.

Figure 1 :
Figure 1: Soil layer distribution and main physical and mechanical parameters of the site.

Figure 3 :
Figure 3: Fitting curve of compression index and moisture content of soft soil.

Table 1 :S
Quantitative structural parameters for soft soils.deformation at the same leve Cun-li et al.[20] the same level of pressure Zai-qiang et al.[21] (2022) Dry-wet cycle structural parameters M cycle τ dry-wet cycle dynamic shear stress 6 Shock and Vibration the main calculation process of the initial consolidation pressure in structural soft soil.

Figure
Figure Schematic diagram of structural indices and structural parameters in a one-dimensional compression e − log p curve.

Table 2
Further analysis revealed that the plasticity index of soil is directly proportional to its structural strength, possibly the increased fne particle content, which in turn enhances interparticle forces by expanding soil particle-specifc surface areas.Notably, the e − log p curve of the remolded soil sample No.
c � 0.27), which signifes the soil's greater susceptibility to compression owing to its unstable arrangement of soil particles after yielding and poor cementation.Te enhanced structural features of sample No. 2 are attributed to its higher structural yield stress (σ k � 365 kPa), implying stronger interparticle cementation and stability.Sample No. 3 retrieved from a soil layer at a depth of 11 m, exhibited relatively low plasticity index and low structural characteristics.

Table 2 :
Statistics of basic parameters of soft soil.