Home Evaluation of dynamic behavior of varved clays from the Warsaw ice-dammed lake, Poland
Article Open Access

Evaluation of dynamic behavior of varved clays from the Warsaw ice-dammed lake, Poland

  • Krzysztof Nielepkowicz EMAIL logo , Paweł Dobak and Anna Bąkowska
Published/Copyright: March 7, 2023
Download Article (PDF)
Become an author with De Gruyter Brill
Submit Manuscript Author Information
Open Geosciences
From the journal Open Geosciences Volume 15 Issue 1

Abstract

Soil stiffness degradation due to dynamic loading may result in damage to engineering structures. Therefore, dynamic soil properties gained importance in recent years in the areas where vibrations of different origins are transmitted to the ground. The aim of the study was to determine the stiffness properties of the Warsaw varved clay (central Poland), as a measure of its response to dynamic loading. A set of triaxial tests were conducted. Undisturbed samples were subjected to initial deviator stress of 100 kPa, reflecting vertical stress due to construction load, and then to three dynamic stages under axial displacement control conditions. Secant shear modulus G was adopted as a parameter of soil stiffness during dynamic loading. Main methodological result of the study is application of coefficient α (gradient of logarithmic change in stiffness with time) indicating type of soil behavior under dynamic loading. Negative α values (ranging from −0.48 to −0.91) indicated a weakening effect of the applied vibrations (decrease in stiffness), while positive α values (ranging from 0.11 to 0.21) indicated soil strengthening (increase in stiffness). Results of the study may be applied to compare an impact of several factors influencing soil stiffness during dynamic loading

Keywords: varved clays; shear modulus; dynamic strengthening

1 Introduction

Dynamic behavior and strength properties of cohesive soils gained importance in recent time due to fast development of transport infrastructure, in particular, roads and railways. Increasing number of roads and railways have to be built in difficult ground conditions, including soft cohesive soils of low stiffness and strength [1,2,3,4]. Thus numerous studies are required: means of mitigating vibrations, techniques for strengthening the ground, and determination of soil mechanical parameters [5,6,7,8,9].

The influence of road or railway traffic on soft cohesive soils can be assessed by combination of both field and laboratory methods. The main objective of field investigations is to collect vibration intensity data (amplitude, acceleration, and frequency values), characteristic for urban transport [10,11]. Collected data can be further applied for laboratory investigations, i.e., shear strength test under cyclic loading.

Shear modulus (G) is a parameter which can be efficiently used for assessment of strength and compressibility of soil under small strain range [12]. There is also a common approach predicting long-term behavior of clayey soils throughout the evaluation of hysteresis loop parameters and calculation of permanent strain [3,13,14]. Some investigations also concern the comparison of applicability of various methods used for predicting stiffness and deformability of soil [15,16,17].

The main objective of this study is to evaluate the behavior of varved clay subjected to road vibration. According to Myślińska [18,19], weakening of varved clays is expected under additional dynamic loading, particularly due to the structural and textural properties of varved clay. We designed a laboratory program of triaxial strength tests to determine the mechanical parameters of varved clay under static and dynamic conditions. It allows us to study shear modulus variation and its dependence on different factors.

Shear modulus can be adopted as a relevant parameter of a long-term behavior of a soft clay, that is more accurate for predicting the magnitude of foundation settlement than commonly used deformation moduli [15]. The applicability of triaxial tests for determining value of shear modulus has more advantages than classical shear strength or deformation tests, and is comparable with other methods like resonant column or bender element test [12]. The tests conducted in this study were executed in the small to medium strain interval (γ = 3.0 × 10−4 to 4.7 × 10−3), which corresponds to the typical geotechnical and engineering situations: retaining walls, foundations, and tunnels. Thus, the results of our investigation can be applied for calculations of bearing capacity of soil subjected not only to static load but also dynamic load, as in case of traffic or the other sources of vibrations.

Triaxial tests were executed under axial displacement control (ADC) method of dynamic loadings, thus our investigations focused on the stiffness degradation (the reduction in stiffness with the increase in the loading cycles), and the factors affecting this process.

2 Methods

2.1 Material origin and properties

Varved clay originates in specific conditions, including existence of ice sheet front, periglacial climate, variation in material supply due to the seasonal conditions, and variation in sedimentation rate. Varved clay occurs in many locations in the northern hemisphere (USA, Poland, Sweden, Estonia, etc.), and the description of their geological properties has been presented by many researchers, e.g., Merta [20], Młynarek and Horvath [21], De Groot and Lutenegger [22], Lu et al. [23], Tankiewicz and Kawa [24], Kalvāns et al. [25], Johnson et al. [26], etc.

Varved clay of the Warsaw ice-dammed basin (Figure 1) is of heterogeneous provenance, structure, and properties which demonstrate substantial variability in both the vertical and horizontal directions [9,16,17,18,19,20]. The Warsaw ice-dammed basin was formed at the younger Pleistocene and covered most of the Mazovia Lowland. The basin was supplied with the material from the south and east (directions opposite to the glaciated area). This means that the basin was fed by extraglacial rivers from these directions (and not by the proglacial waters). The sediment is a type of extraglacial varved deposits [20].

Figure 1 Location of the sample collection (marked in red) against the extent of Warsaw ice-dammed lake (© OpenStreetMap contributors https://www.openstreetmap.org/copyright) (Myślińska [27] after Różycki [28], modified).
Figure 1

Location of the sample collection (marked in red) against the extent of Warsaw ice-dammed lake (© OpenStreetMap contributors https://www.openstreetmap.org/copyright) (Myślińska [27] after Różycki [28], modified).

The specific structure of the varved clay is a result of variation in seasonal conditions at the front of the Vistulian Glaciation ice sheet. Each varve is composed from two alternating layers: the light one (silt) – deposited during the warm period, and the dark one (clay) – deposited during the cold period. Varved clay of the Warsaw ice-dammed lake is also characterized by significant variation in terms of facies. Three types of varves are indicated, each corresponding to different sedimentary zone, depending on the location in the sedimentary basin [20].

  1. Proximal zone – This zone consists of A-type varves (with indistinct gradual boundaries, light layers thicker than dark ones, and total thickness of a varve above 4.0 cm), which is the environment adjacent to the river mouth. Sandy sediments are dominating (with current structures, and without wave ripples), but there are also clayey layers, provided by subglacial streams. This environment is intermediate between fluviatile and basin regime.

  2. Transitional (intermediate) zone – This zone is characterized by the existence of B-type varves (with contrasting sharp boundaries, light and dark layers of equal thickness, and total thickness of a varve in the range of 2.0–4.0 cm), located between the proximal and distal zones. Both current and wave structures can be found on the surface of varves.

  3. Distal zone – This zone consists of C-type varves (with contrasting sharp boundaries, light layers thinner than dark ones, and total thickness of a varve below 2.0 cm), located far from the river mouth. It is characterized by a small amount of sandy-silty sediment and those layers are thinner than in previous zones. Turbidity currents were a main factor of deposition (greater water depths, no wave ripples).

The significant difference between dark and light layers is a proof of the different conditions of the environmental energy. The current and wave activities with bottom suspension currents were the characteristics of the light layers, while quiet sedimentations were the characteristics of the dark ones. The B- and C-type varves are suspected to be a product of suspension currents, while A-type ones are more characteristic of environments close to fluvial [20]. Many of the varves are highly variable in terms of thickness, even within the same type of varve (supernormal varves). Variability does not show any regularity. Changes in thickness are independent between light and dark layers and the clay content is more uniformly dispersed than sandy-silty sediments [20].

In some areas, in the eastern part of the Warsaw ice-dammed lake, the varved clay is covered by a thin, 1–3 m layer of Holocene sand of aeolian origin.

Varved clay is one of the most important units of the subsoil in towns located northeast from Warsaw: Radzymin, Kobyłka, and Zielonka (Figure 1). That is why soil samples for laboratory tests were collected in Kobyłka town (Figure 1). Two parallel drills at a distance of 5 m were executed. The material was collected using Shelby’s thin-walled tubes, from the depth of 1.3–2.6 m. Collected soil corresponds mainly to the A-type type of varves (as described by Merta [20]). Mean values of index properties of silty and clayey layers are presented in Table 1.

Table 1

Average values of index parameters of the varved clay

Parameters Silty layer Clayey layer
Clay content (%) 25 48
Silt content (%) 74 51
Sand content (%) 1 1
Particle density (Mg/m3) 2.69 2.76
Water content (%) 27.3 34.3
Plastic limit (%) 19.8 25.9
Liquid limit (%) 35.9 59.8

Clay content shows significant variation which is noticeable macroscopically. This may cause unusual differentiation of mechanical properties, as the horizontal shear strength along the clayey layer may be lower than the vertical shear strength of varved clay. Thus, it is of particular importance to apply adequate methods for predicting the behavior of the varved clay under different loading conditions [9].

In respect of the history of geological loads, Zawrzykraj [17] proved that varved clay of the Warsaw ice-dammed lake are normally consolidated soils, and have not been covered by either the ice sheet or the large amount of younger deposits. But these deposits can demonstrate behavior comparable to some overconsolidated soils because of the post-sedimentary chemical cementation process, occurring in conditions of lowering of water table.

2.2 Test procedure

The aim of the investigation was to study the dynamic behavior of the varved clay in conditions corresponding to in situ conditions of typical construction in Kobyłka: subsoil loaded by the construction of unit stress of 100 kPa at the foundation level and additionally subjected to intermittent vibrations due to traffic. The dynamic behavior of the samples was compared to their static behavior, thus the laboratory test program included two types of triaxial CU (consolidated undrained) tests: under static conditions (monotonic loading) and under dynamic conditions (cyclic loading). All tests were conducted in GDS Ltd dynamic triaxial testing apparatus under the CU conditions (CU tests) according to the following procedure:

  • The samples were oriented in the direction corresponding to their orientation in natural conditions. The specimens were trimmed to an average dimension of D = 35.0–38.4 mm and H/D = 1.83–2.65

  • Prior shearing, each test consisted of the following stages: initial loading under effective stress, three saturation steps with three B-checks, consolidation stage, initial deviator stress increase, three dynamic stages, and final static shearing

  • Initial effective stress applied on each sample was equal to 50 kPa, in case of preventing swelling

  • After that, the back-pressure saturation was undertaken, average B-value for all the samples was 0.93

  • Next stage was isotropic consolidation under effective confining pressure, respectively, σ c = 100, 200, or 400 kPa

  • After consolidation, samples were subjected to an increase in the initial deviator stress to 100 kPa to reflect the vertical stress that is applied to the soil due to the construction load

  • Then, axial loading was applied under undrained conditions

  • For samples tested under static conditions, monotonic loading with constant rate of strain of 0.01 mm/min were executed

  • For samples tested under dynamic conditions, three consecutive stages of ADC tests were performed (Table 2)

  1. Dynamic stage I – high amplitude vibration: displacement amplitude A = 0.1 mm, frequency f = 5 Hz, and number of cycles N = 1,000

  2. Dynamic stage II – low amplitude vibration: A = 0.01 mm, f = 5 Hz, and N = 10,000

  3. Dynamic stage III – high amplitude vibration: A = 0.1 mm, f = 5 Hz, and N = 1,000

Table 2

Parameters of vibration applied in the dynamic stages

Test parameters Dynamic stage I Dynamic stage II Dynamic stage III
Amplitude A (mm) 0.1 0.01 0.1
Frequency f (Hz) 5 5 5
Number of cycles N (–) 103 104 103
Acceleration a (mm/s2) 98.7 9.9 98.7

Vibration parameters were designed with regards to correspond to the different traffic conditions in site, and the technical limitations of the triaxial apparatus.

After each dynamic stage, samples were subjected to mid-phase loadings, so that each dynamic stage started from 100 kPa of initial deviator stress. General conditions of dynamic phases were presented on the schematic graphs (Figure 2).

Figure 2 Scheme of cyclic loadings.
Figure 2

Scheme of cyclic loadings.

Since no shear failure was observed during dynamic loading, after the dynamic stage III, the monotonic shearing was executed with a constant rate of strain of 0.01 mm/min to determine the post-dynamic shear strength.

In total, 24 tests were conducted. Under dynamic conditions, 17 samples were tested: 4 samples consolidated under σ c = 100 kPa, 7 samples under σ c = 200 kPa, and 6 samples under σ c = 400 kPa. Under static conditions 7 samples were tested: 2 samples under σ c = 100 kPa, 2 samples under σ c = 200 kPa, and 3 samples under σ c = 400 kPa.

3 Results

3.1 Shear modulus parameter

Modulus of deformation was calculated on the basis of the following equation (Figure 3):

(1) E N = dev N , max dev N , min ε N , max ε N , min ,

where E N is the modulus of deformation at the Nth cycle; dev N,max and dev N,min are the maximum and minimum deviator stress at the Nth cycle; and ε N,max and ε N,min are the maximum and minimum axial strains at the Nth cycle, respectively.

Figure 3 Shear modulus on the basis of hysteresis loop of Nth cycle.
Figure 3

Shear modulus on the basis of hysteresis loop of Nth cycle.

Then, shear modulus (G) was calculated from the following equations [29]:

(2) Δ γ = ( 1 + ν ) · Δ ε ,

(3) G N = E N 2 · ( 1 + ν ) ,

where ν is the Poisson coefficient; Δε is the axial strain amplitude; Δγ is the shear strain amplitude; and G N is the shear modulus at the Nth cycle.

The Poisson coefficient equal to 0.5 was taken into calculations, as the soil samples were fully saturated prior to triaxial loading.

Characteristic loops for 1, 100, 1,000, and 10,000 cycles of dynamic stages were selected to determine the values of G (Table 3). The results of G values (Table 3) were analyzed with regards to vibration amplitude A, number of cycles N, and effective confining pressure (effective stress at consolidation) σ c .

Table 3

Statistical variability of modulus G

Number of dynamic stage/shear strain range Effective confining pressure Number of samples Number of dynamic cycles Shear modulus
Average value Standard deviation Variability coefficient Median Difference
σ c N N G av σ n–1 ν G med G maxG min
(kPa) (–) (–) (MPa) (MPa) (–) (MPa) (MPa)
Dynamic stage I/3.0 × 10−3 to 4.7 × 10−3 100 4 1 14.4 1.9 0.13 14.2 4.4
100 10.8 1.6 0.15 10.6 3.7
1,000 9.7 1.5 0.15 9.5 3.4
200 7 1 20.0 2.5 0.12 19.3 6.0
100 16.0 1.6 0.10 16.0 4.1
1,000 14.6 1.4 0.09 14.5 3.4
400 6 1 26.5 3.1 0.12 26.4 6.6
100 21.8 4.2 0.19 22.5 10.9
1,000 20.3 4.0 0.20 21.5 10.7
Dynamic stage II/3.0 × 10−4 to 4.7 × 10−4 100 4 1 18.8 2.5 0.13 18.0 5.7
1,000 20.0 2.9 0.15 18.9 6.3
10,000 20.9 3.1 0.15 19.9 7.0
200 7 1 27.1 4.6 0.17 25.3 10.9
1,000 27.9 4.4 0.16 25.4 10.7
10,000 28.3 4.2 0.15 26.2 10.8
400 6 1 36.7 3.2 0.09 38.5 7.7
1,000 37.2 3.6 0.10 37.6 11.0
10,000 37.9 3.9 0.10 38.7 10.8
Dynamic stage III/3.0 × 10−3 to 4.7 × 10−3 100 4 1 13.3 2.2 0.17 12.7 5.1
100 10.9 1.9 0.17 10.4 4.4
1,000 10.0 1.7 0.17 9.6 3.9
200 7 1 19.5 2.3 0.12 19.6 6.5
100 16.4 1.9 0.12 15.9 5.1
1,000 15.1 1.6 0.11 14.6 4.3
400 6 1 27.2 2.9 0.11 27.8 6.5
100 23.3 2.9 0.13 23.9 6.1
1,000 21.4 3.1 0.15 22.3 7.3

3.2 Vibration amplitude

The results can indicate two qualitatively different ways of soil response to dynamic loading applied at the same frequency of vibrations but with different amplitudes:

  • In the dynamic stages I and III, when the amplitude was higher (A = 0.1 mm) after 1,000 cycles, G av values decreases c.a. 25%;

  • While in the dynamic stage II, when the amplitude was lower (A = 0.01 mm), an increase in G av value by several percentage was registered.

This may indicate that a slight strengthening of soil is possible at lower vibration amplitudes, while higher vibration amplitudes cause weakening of the structure, which is expressed by the decrease in G av due to dynamic loading.

3.3 Number of cycles

The changes in G av values during dynamic loading are not linear. The dependence of G av value on the number of cycles was approximated by a logarithmic function (Figure 4a–c).

(4) G av N = α ln N + G av N = 1 ,

where G av is the average value of shear modulus, N is the number of Nth cycle, α is the gradient of logarithmic curve, and G avN=1 is the G av value at 1st cycle of a particular dynamic stage.

Figure 4 Shear modulus changes during: (a) the dynamic stage I, (b) the dynamic stage II, and (c) the dynamic stage III.
Figure 4

Shear modulus changes during: (a) the dynamic stage I, (b) the dynamic stage II, and (c) the dynamic stage III.

The value of α coefficient is an indicator of the trend of G av changes during the dynamic loading: negative values (α < 0) correspond to the decrease in G av which indicate soil weakening, while positive values (α > 0) correspond to the increase in G av which indicates soil strengthening.

Comparison of α values allows for a quantitative evaluation of G av changes. The most significant reduction in G av value (from −0.70 to −0.91) was observed in the dynamic stage I – in the samples where no dynamic loads were applied so far. The soil weakened after dynamic stage I, and the soil was then subjected to dynamic stage II with vibrations of significantly lower amplitude but much higher number of cycles. This resulted in an increase in G-value, which is expressed in positive α values (from 0.11 to 0.21). This slight strengthening influenced the quantitative changes in soil response when dynamic loads of high amplitude were applied again (dynamic stage III). Although a further reduction in G av value during the dynamic stage III was observed, the quantitative indicators of this reduction were slightly smaller (α values range from −0.48 to −0.84) compared to those observed in the dynamic stage I.

The changes in G av values were analyzed in the two intervals: during the initial cycles and during the subsequent cycles of dynamical loading. It was assumed that for the dynamic stages I and III, the initial cycles are cycles from N = 1 to N = 100, and for the dynamic stage II the initial cycles are from N = 1 to N = 1,000. The subsequent cycles are, respectively, from N = 100 to N = 1,000, and from N = 1,000 to N = 10,000. The initially rapid changes in G av values during the initial cycles and smaller changes during the subsequent cycles of each dynamic phase (Figure 4a–c) are indicated not only by the parameters of the logarithmic model G av = f(N), but also by comparisons of values of absolute changes in ΔG avN gradients.

In the dynamic stage I, ΔG avN determined in the initial cycles decreased 27–30 times faster compared to the smaller ΔG avN changes noted during the subsequent cycles.

In the dynamic stage II, the increase in ΔG avN determined in the initial cycles was only 7–19 times greater compared to much smaller increase during the subsequent cycles.

In the dynamic stage III, in the initial cycles, decreases in ΔG avN values were only 3–19 times higher than during the subsequent cycles.

Thus, varying dynamic loading conditions in subsequent dynamic stages result in less intense changes in the mechanical soil parameters.

3.4 Effective confining stress

Soil response to dynamic loading is also significantly dependent on effective confining stress at consolidation σ c (Figure 5a and b). In a particular dynamic phase, G av values increase with the increase in the effective confining pressure σ c . This relationship is well represented by the following equation:

(5) G av = β · ln ( σ c ) + b ,

where G av is the average value of shear modulus, σ c is the consolidation effective stress, β is the gradient of logarithmic curve, and b is the intercept of logarithmic curve

Figure 5 G av variation as a function of consolidation effective stress: (a) in the dynamic stages I and III and (b) in the dynamic stage II.
Figure 5

G av variation as a function of consolidation effective stress: (a) in the dynamic stages I and III and (b) in the dynamic stage II.

Coefficient of determination (R 2) ranged from 0.994 to 0.999. G av values for samples consolidated under σ c = 200 kPa and σ c = 400 kPa were, respectively, 44% and almost 100% higher than for samples consolidated under σ c = 100 kPa.

G av values are thus conditioned by the following:

  • the value of effective confining pressure σ c

  • parameters of dynamic loading in successive stages (dynamic stages I, II, and III)

  • the number of cycles for which G av values are determined

The characteristics of the variation in G av values determined as a function of σ c are illustrated in Figure 5a and b. In all analyzed cycles, G av/ σ c gradient in the range 100–200 kPa was higher and decreased in the range 200–400 kPa. This confirms the reduced response to dynamic loadings for samples consolidated at higher effective pressure.

Increase in G av value as a function of σ c is observed at both conditions when higher amplitude of vibration leads to structural weakening of the soil material, and at lower amplitude of vibration resulting in soil strengthening. G av values in the dynamic stages I and III, where the structural weakening was observed, were smaller than G av values obtained in the dynamic stage II where the soil strengthening was observed. The increase in G av = f( σ c ) in the dynamic stage II is characterized by β values ranging from 12.3 to 12.9 (Figure 5b), whereas in the dynamic stage I, by significantly smaller β values (from 7.6 to 8.7). In the dynamic stage III, the effects of the previous varying loading conditions most probably got accumulated and β values were slightly higher (from 8.2 to 10.1) than in the dynamic stage I (Figure 5a). These quantitative comparisons show how the loading history may indicate the dependence of G av values on stress in the soil mass.

The comparison of factors influencing G av changes takes into account dynamic stages for samples consolidated under particular effective confining pressure (Figure 6). The ratio of ΔG av/G avi−1, where ΔG av = G avi-G avi−1, was assumed as an indicator of the changes. ΔG av/G avi−1 ratio was analyzed in the two periods of each dynamic stage: the initial cycles and the subsequent cycles. The most significant changes in ΔG av/G avi−1 ratio were observed during the initial cycles, and thus when a given dynamic loading is applied to soil straight after the “deviatoric loading.” During subsequent cycles, much smaller changes were observed (several percent smaller than during the initial cycles). This indicates that the trend of rapidly decreasing ΔG av/G avi−1 change is continued and confirms that it is reasonable to analyze them for a larger number of cycles.

Figure 6 Change in average shear modulus in relation to effective confining pressure at each dynamic stage.
Figure 6

Change in average shear modulus in relation to effective confining pressure at each dynamic stage.

The use of vibration with different amplitudes is also reflected in the changes in ΔG avi/G avi−1 ratio. During the dynamic stage I, the initial cycles cause the most significant changes in ΔG av/G avi−1 proportional to the effective pressure at consolidation σ c . During the dynamic stage II, ΔG av/G avi−1 ratio decreases (up to few %) at higher values of effective pressure at consolidation. The least significant changes in ΔG av/G avi−1 ratio are observed during the dynamic stage III. Also, in the dynamic stage III, ΔG av/G avi−1 changes are similar in the samples consolidated at 200 and 400 kPa, thus it may indicate the unification of material characteristics of soil due to dynamic loading and application of higher values of effective pressure at consolidation σ c .

4 Discussion

Dynamic loads of amplitude A = 0.1 mm and frequency f = 5 Hz were assumed to correspond to the conditions of intensive road traffic. In these conditions, a rapid decrease in the G av modulus was observed during the initial cycles, which tends to stabilize during subsequent cycles.

In the conditions corresponding to normal road traffic, the loads of amplitude A = 0.01 mm and f = 5 Hz were applied. In these conditions, an increase in G av value was observed. This indicates a dynamically conditioned slight strengthening of the soil under dynamic loading, most probably due to the rearrangement of soil particles, advantageous for strengthening of soil structure and, at the same time, not enough to cause significant increase in pore water pressure. This trend is typical of the behavior of soils under low strain conditions [12]. Also, initial increase in the deviator stress under drained conditions before the dynamic stage II was an important factor responsible for observable strengthening.

Although the following vibration of higher amplitude (A = 0.1 mm) caused once again reduction in G av values, its absolute values are from 3.0 to 5.4% higher in comparison with the corresponding data from the dynamic stage I. The lower amplitude vibration in combination with the increase in the deviatoric static loading to 100 kPa between the dynamic stages (Figure 2) result in soil strengthening. This may be explained as a consequence of the reorientation of soil particles during dynamic conditions, and an increase in the density of the soil due to particle compaction during deviatoric static loading.

G av values show an increasing tendency to stabilize at higher effective confining pressures (Figure 6). This may be interpreted as an effect of the earlier strengthening of soil strength at the stage of isotropic consolidation when the excess pore water pressure was dissipated and the soil particles were precompacted. Also, short stages of mid-phase under drained loading conditions right before the dynamic stage II and the dynamic stage III led to the dissipation of excess pore water pressure generated in the previous dynamic stage and, in consequence, increasing of the effective stress and strengthening of the soil structure increased. This type of behavior of Warsaw varved clay during the dynamic stages I and III may be compared with the other clayey soils which show rapid decrease in shear modulus during the first dozens of cycles and its stability after large number of cycles [3,30].

Comparing G av values dependence on consolidation effective stress (Figure 5), we can indicate a few important factors. Geological loading history and diagenetic processes, including actual or apparent overconsolidation of the soil [17] may indicate the dependence of G av on the stress in the soil mass. The rate of G av increase as a function of consolidation effective stress represented by β coefficient also depends on the strain level. For the dynamic stage II (strain range of: 3.0 × 10−4 to 4.7 × 10−4), G av increase is distinctly higher (β ranging from 12.3 to 12.9) than for the dynamic stage I and the dynamic stage III (strain range: 3.0 × 10−3 to 4.7 × 10−3 and β ranging from 7.6 to 10.1). This indicates the important role of nonlinearity of G av in the function of consolidation effective stress.

5 Conclusion

Test results lead to the following methodical conclusions:

  1. G modulus is a convenient parameter for evaluation of stiffness changes during the different dynamic loading conditions;

  2. Investigations of soils subjected to dynamic loads should be focused on evaluation of factors influencing the changes in stiffness, such as different amplitudes of vibrations, number of loading cycles, increase in pore water pressure, and confining pressure;

  3. The quantitative change in G av in logarithmic dependence on the number of cycles during dynamic loading allows the introduction of α coefficient, which differentiates the soil behavior. The threshold value of the amplitude A at α = 0 is an important indicator of the changes in the vibration influence on the behavior of soils of a given origin. Negative α values indicate a weakening effect of the applied vibrations (stiffness decreasing), while positive α values indicate a soil strengthening (stiffness increasing);

  4. The quantitative change in G av in logarithmic dependence on the effective confining pressure can be characterized by the β coefficient. This parameter may be applied for the assessment of impact of the confining stress on soil reaction to dynamic loading;

  5. During dynamic loading, ΔG av/G avi−1 ratio has a decreasing tendency, which may indicate achieving reversible quasi-elastic behavior of the soil;

  6. Application of similar test program on the soils of different genesis may give a comparative, new understanding of the behavior of soils.

Acknowledgments

We would like to thank Dr eng. Kamil Kiełbasiński and the Geological-Drilling Company PAWLAK for its technical assistance during the soil sampling. The authors also wish to express their greatest gratitude to Reviewers for their insightful suggestions and valuable comments on the manuscript.

  1. Funding information: This study was supported by funds of the University of Warsaw – Faculty of Geology: 501-D113-01-1130302 (Department of Engineering Geology and Geomechanics) and 501-D113-01-1130103 (Laboratory of Applied Geology).

  2. Author Contributions: conceptualization: K.N.; methodology: K.N. and A.B.; validation: A.B. and P.D.; formal analysis: K.N. and P.D.; investigation: K.N.; resources: K.N.; writing – original draft preparation: K.N. and P.D.; writing – review and editing: A.B. and P.D.; visualization: K.N., A.B., and P.D.; supervision: P.D. All authors have read and agreed to the published version of the manuscript.

  3. Conflict of interest: The authors declare no conflict of interest.

References

[1] Tang YQ, Cui ZQ, Zhang X, Zhao SK. Dynamic response and pore pressure model of the saturated soft clay around the tunnel under vibration loading of Shanghai subway. Eng Geol. 2008;98(3/4):126–32.10.1016/j.enggeo.2008.01.014Search in Google Scholar

[2] Li LL, Dan HB, Wang LZ. Undrained behavior of natural marine clay under cyclic loading. Ocean Eng. 2011;38(16):1792–1805.10.1016/j.oceaneng.2011.09.004Search in Google Scholar

[3] Guo L, Wang J, Cai Y, Liu H, Gao Y, Sun H. Undrained deformation behavior of saturated soft clay under long-term cyclic loading. Soil Dyn Earthq Eng. 2013;50:28–37.10.1016/j.soildyn.2013.01.029Search in Google Scholar

[4] Lin B, Zhang F, Feng D. Long-term resilient behaviour of thawed saturated silty clay under repeated cyclic loading: experimental evidence and evolution model. Road Mater Pavement Des. 2019;20(3):608–22.10.1080/14680629.2017.1407819Search in Google Scholar

[5] Athanasopoulos GA, Pelekis PC. Ground vibrations from sheetpile driving in urban environment: measurements, analysis and effects on buildings and occupants. Soil Dyn Earthq Eng. 2000;19(5):371–87.10.1016/S0267-7261(00)00008-7Search in Google Scholar

[6] Hao H, Ang TC, Shen J. Building vibration to traffic-induced ground motion. Build Environ. 2001;36:321–36.10.1016/S0360-1323(00)00010-XSearch in Google Scholar

[7] Nam BH, Kim JY, An JW, Kim BJ. A review on the effects of earthborne vibrations and the mitigation measures. Int J Railw. 2013;6(3):95–106.10.7782/IJR.2013.6.3.095Search in Google Scholar

[8] Bąkowska A, Dobak P, Gawriuczenkow I, Kiełbasiński K, Szczepański T, Trzciński J, et al. Stress-strain behaviour analysis of Middle Polish glacial tills from Warsaw (Poland) based on the interpretation of advanced field and laboratory tests. Acta Geol Pol. 2016;66(3):561–85.10.1515/agp-2016-0026Search in Google Scholar

[9] Dobak P, Kiełbasiński K, Szczepański T, Zawrzykraj P. Verification of compressibility and consolidation parameters of varved clays from Radzymin (Central Poland) based on direct observations of settlements of road embankment. Open Geosci. 2018;10:911–24.10.1515/geo-2018-0072Search in Google Scholar

[10] Nielepkowicz K, Bąkowska A, Maślakowski M. The influence of train-induced ground motion in assessments of dynamic impact on structures. Arch Civ Eng. 2018;64(4):49–63.10.2478/ace-2018-0062Search in Google Scholar

[11] Gao M, Song YS, Wang Y, Chen QS. Effect of geological conditions on vibration characteristics of ground due to subway tunnel: Field investigation. Geotech Geol Eng. 2021;39:4689–96.10.1007/s10706-021-01767-2Search in Google Scholar

[12] Jastrzębska M. Investigations of the behaviour of cohesive soils subjected to cyclic loads in the range of small deformations. Gliwice, Poland: Silesian University of Technology Publisihing; 2010 (in Polish with English summary).Search in Google Scholar

[13] Hyodo M, Yamamoto Y, Sugiyama M. Undrained cyclic shear behaviour of normally consolidated clay subjected to initial static shear stress. Soils Found. 1994;34(4):1–11.10.3208/sandf1972.34.4_1Search in Google Scholar

[14] Hu C, Liu H. A new bounding-surface plasticity model for cyclic behaviors of saturated clay. Commun Nonlinear Sci Numer Simul. 2015;22(1–3):101–19.10.1016/j.cnsns.2014.10.023Search in Google Scholar

[15] Godlewski T, Szczepański T. Non-linear soil stiffness characteristic (G0) – methods of determination, examples of application. Min Geoengin. 2011;35(2):243–50 (in Polish).Search in Google Scholar

[16] Zawrzykraj P. Deformability parameters of the varved clays from the Iłów (Central Poland) area based on the selected field tests. Studia Geotech et Mech. 2017;39(1):89–100.10.1515/sgem-2017-0009Search in Google Scholar

[17] Zawrzykraj P. Variability of physical and mechanical properties of varved clays of Warsaw ice-dammed lake in light of in situ tests. Warsaw, Poland: University of Warsaw Publishing; 2019 (in Polish).Search in Google Scholar

[18] Myślińska E. Influence of sedimentation conditions and diagenesis of the varved deposits of the Central Poland Glaciation in Mazovia region area on their engineering-geological properties. Univ Wars Geol Bull. 1965;7:3–106 (in Polish).Search in Google Scholar

[19] Myślińska E. Physical-mechanical properties of varved deposits of the Central Poland Glaciation on the background of their lithology and stratigraphy and conditions of occurrence. Bull Geol Inst. 1967;198:151–73 (in Polish).Search in Google Scholar

[20] Merta T. Extraglacial varved deposits of the Warsaw Ice-Dammed Lake (younger Pleistocene), Mazovia Lowland, Central Poland. Acta Geol Pol. 1978;28:241–72.Search in Google Scholar

[21] Młynarek Z, Horvath G. Shear parameters of varved clay. Periodica Polytechnica. Civ Eng. 1990;34(3–4):215–23.Search in Google Scholar

[22] De Groot DJ, Lutenegger AJ. Characterization by sampling and in-situ testing – Connecticut Valley Varved Clay. Studia Geotech et Mech. 2005;27(3–4):107–20.Search in Google Scholar

[23] Lu Y, Tan Y, Lin G. Characterization of thick varved-clayey-silt deposits along the Delaware River by field and laboratory tests. Environ Earth Sci. 2013;69:1845–60.10.1007/s12665-012-2020-5Search in Google Scholar

[24] Tankiewicz M, Kawa M. Identification of anisotropic criteria for stratified soil based on triaxial tests results. Studia Geotech et Mech. 2017;39(3):59–65.10.1515/sgem-2017-0030Search in Google Scholar

[25] Kalvāns A, Hang T, Kohv M. Grain-size of varved clays from the north-eastern Baltic Ice Lake: Insight to the sedimentary environment. Estuarine Coast Shelf Sci. 2017;195:51–9.10.1016/j.ecss.2016.08.009Search in Google Scholar

[26] Johnson MD, Wedel PO, Benediktsson I, Lenninger A. Younger Dryas glaciomarine sedimentation, push-moraine formation and ice-margin behavior in the Middle Swedish end-moraine zone west of Billingen, central Sweden. Quat Sci Rev. 2019;224:1–18.10.1016/j.quascirev.2019.105913Search in Google Scholar

[27] Myślińska E. Laboratory tests of soils. Warszawa, Poland: Polish Scientific Publishers; 2001 (in Polish).Search in Google Scholar

[28] Różycki SZ. From the Baltic Sea to the Tatras, part II, Vol. I. Middle Poland. Guide book of excursion VIth INQA Congress. Łódź, Poland: Polish Scientific Publishers; 1961.Search in Google Scholar

[29] Kokusho T. Cyclic triaxial test of dynamic soil properties for wide strain range. Soils Found. 1980;20(2):45–60.10.3208/sandf1972.20.2_45Search in Google Scholar

[30] Lanzo G, Pagliaroli A, Tommasi P, Chiocci FL. Simple shear testing of sensitive, very soft offshore clay for wide strain range. Can Geotech J. 2009;46(11):1277–88.10.1139/T09-059Search in Google Scholar
Received: 2022-10-29
Revised: 2023-01-12
Accepted: 2023-01-24
Published Online: 2023-03-07

© 2023 the author(s), published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

Articles in the same Issue

  1. Regular Articles
  2. Diagenesis and evolution of deep tight reservoirs: A case study of the fourth member of Shahejie Formation (cg: 50.4-42 Ma) in Bozhong Sag
  3. Petrography and mineralogy of the Oligocene flysch in Ionian Zone, Albania: Implications for the evolution of sediment provenance and paleoenvironment
  4. Biostratigraphy of the Late Campanian–Maastrichtian of the Duwi Basin, Red Sea, Egypt
  5. Structural deformation and its implication for hydrocarbon accumulation in the Wuxia fault belt, northwestern Junggar basin, China
  6. Carbonate texture identification using multi-layer perceptron neural network
  7. Metallogenic model of the Hongqiling Cu–Ni sulfide intrusions, Central Asian Orogenic Belt: Insight from long-period magnetotellurics
  8. Assessments of recent Global Geopotential Models based on GPS/levelling and gravity data along coastal zones of Egypt
  9. Accuracy assessment and improvement of SRTM, ASTER, FABDEM, and MERIT DEMs by polynomial and optimization algorithm: A case study (Khuzestan Province, Iran)
  10. Uncertainty assessment of 3D geological models based on spatial diffusion and merging model
  11. Evaluation of dynamic behavior of varved clays from the Warsaw ice-dammed lake, Poland
  12. Impact of AMSU-A and MHS radiances assimilation on Typhoon Megi (2016) forecasting
  13. Contribution to the building of a weather information service for solar panel cleaning operations at Diass plant (Senegal, Western Sahel)
  14. Measuring spatiotemporal accessibility to healthcare with multimodal transport modes in the dynamic traffic environment
  15. Mathematical model for conversion of groundwater flow from confined to unconfined aquifers with power law processes
  16. NSP variation on SWAT with high-resolution data: A case study
  17. Reconstruction of paleoglacial equilibrium-line altitudes during the Last Glacial Maximum in the Diancang Massif, Northwest Yunnan Province, China
  18. A prediction model for Xiangyang Neolithic sites based on a random forest algorithm
  19. Determining the long-term impact area of coastal thermal discharge based on a harmonic model of sea surface temperature
  20. Origin of block accumulations based on the near-surface geophysics
  21. Investigating the limestone quarries as geoheritage sites: Case of Mardin ancient quarry
  22. Population genetics and pedigree geography of Trionychia japonica in the four mountains of Henan Province and the Taihang Mountains
  23. Performance audit evaluation of marine development projects based on SPA and BP neural network model
  24. Study on the Early Cretaceous fluvial-desert sedimentary paleogeography in the Northwest of Ordos Basin
  25. Detecting window line using an improved stacked hourglass network based on new real-world building façade dataset
  26. Automated identification and mapping of geological folds in cross sections
  27. Silicate and carbonate mixed shelf formation and its controlling factors, a case study from the Cambrian Canglangpu formation in Sichuan basin, China
  28. Ground penetrating radar and magnetic gradient distribution approach for subsurface investigation of solution pipes in post-glacial settings
  29. Research on pore structures of fine-grained carbonate reservoirs and their influence on waterflood development
  30. Risk assessment of rain-induced debris flow in the lower reaches of Yajiang River based on GIS and CF coupling models
  31. Multifractal analysis of temporal and spatial characteristics of earthquakes in Eurasian seismic belt
  32. Surface deformation and damage of 2022 (M 6.8) Luding earthquake in China and its tectonic implications
  33. Differential analysis of landscape patterns of land cover products in tropical marine climate zones – A case study in Malaysia
  34. DEM-based analysis of tectonic geomorphologic characteristics and tectonic activity intensity of the Dabanghe River Basin in South China Karst
  35. Distribution, pollution levels, and health risk assessment of heavy metals in groundwater in the main pepper production area of China
  36. Study on soil quality effect of reconstructing by Pisha sandstone and sand soil
  37. Understanding the characteristics of loess strata and quaternary climate changes in Luochuan, Shaanxi Province, China, through core analysis
  38. Dynamic variation of groundwater level and its influencing factors in typical oasis irrigated areas in Northwest China
  39. Creating digital maps for geotechnical characteristics of soil based on GIS technology and remote sensing
  40. Changes in the course of constant loading consolidation in soil with modeled granulometric composition contaminated with petroleum substances
  41. Correlation between the deformation of mineral crystal structures and fault activity: A case study of the Yingxiu-Beichuan fault and the Milin fault
  42. Cognitive characteristics of the Qiang religious culture and its influencing factors in Southwest China
  43. Spatiotemporal variation characteristics analysis of infrastructure iron stock in China based on nighttime light data
  44. Interpretation of aeromagnetic and remote sensing data of Auchi and Idah sheets of the Benin-arm Anambra basin: Implication of mineral resources
  45. Building element recognition with MTL-AINet considering view perspectives
  46. Characteristics of the present crustal deformation in the Tibetan Plateau and its relationship with strong earthquakes
  47. Influence of fractures in tight sandstone oil reservoir on hydrocarbon accumulation: A case study of Yanchang Formation in southeastern Ordos Basin
  48. Nutrient assessment and land reclamation in the Loess hills and Gulch region in the context of gully control
  49. Handling imbalanced data in supervised machine learning for lithological mapping using remote sensing and airborne geophysical data
  50. Spatial variation of soil nutrients and evaluation of cultivated land quality based on field scale
  51. Lignin analysis of sediments from around 2,000 to 1,000 years ago (Jiulong River estuary, southeast China)
  52. Assessing OpenStreetMap roads fitness-for-use for disaster risk assessment in developing countries: The case of Burundi
  53. Transforming text into knowledge graph: Extracting and structuring information from spatial development plans
  54. A symmetrical exponential model of soil temperature in temperate steppe regions of China
  55. A landslide susceptibility assessment method based on auto-encoder improved deep belief network
  56. Numerical simulation analysis of ecological monitoring of small reservoir dam based on maximum entropy algorithm
  57. Morphometry of the cold-climate Bory Stobrawskie Dune Field (SW Poland): Evidence for multi-phase Lateglacial aeolian activity within the European Sand Belt
  58. Adopting a new approach for finding missing people using GIS techniques: A case study in Saudi Arabia’s desert area
  59. Geological earthquake simulations generated by kinematic heterogeneous energy-based method: Self-arrested ruptures and asperity criterion
  60. Semi-automated classification of layered rock slopes using digital elevation model and geological map
  61. Geochemical characteristics of arc fractionated I-type granitoids of eastern Tak Batholith, Thailand
  62. Lithology classification of igneous rocks using C-band and L-band dual-polarization SAR data
  63. Analysis of artificial intelligence approaches to predict the wall deflection induced by deep excavation
  64. Evaluation of the current in situ stress in the middle Permian Maokou Formation in the Longnüsi area of the central Sichuan Basin, China
  65. Utilizing microresistivity image logs to recognize conglomeratic channel architectural elements of Baikouquan Formation in slope of Mahu Sag
  66. Resistivity cutoff of low-resistivity and low-contrast pays in sandstone reservoirs from conventional well logs: A case of Paleogene Enping Formation in A-Oilfield, Pearl River Mouth Basin, South China Sea
  67. Examining the evacuation routes of the sister village program by using the ant colony optimization algorithm
  68. Spatial objects classification using machine learning and spatial walk algorithm
  69. Study on the stabilization mechanism of aeolian sandy soil formation by adding a natural soft rock
  70. Bump feature detection of the road surface based on the Bi-LSTM
  71. The origin and evolution of the ore-forming fluids at the Manondo-Choma gold prospect, Kirk range, southern Malawi
  72. A retrieval model of surface geochemistry composition based on remotely sensed data
  73. Exploring the spatial dynamics of cultural facilities based on multi-source data: A case study of Nanjing’s art institutions
  74. Study of pore-throat structure characteristics and fluid mobility of Chang 7 tight sandstone reservoir in Jiyuan area, Ordos Basin
  75. Study of fracturing fluid re-discharge based on percolation experiments and sampling tests – An example of Fuling shale gas Jiangdong block, China
  76. Impacts of marine cloud brightening scheme on climatic extremes in the Tibetan Plateau
  77. Ecological protection on the West Coast of Taiwan Strait under economic zone construction: A case study of land use in Yueqing
  78. The time-dependent deformation and damage constitutive model of rock based on dynamic disturbance tests
  79. Evaluation of spatial form of rural ecological landscape and vulnerability of water ecological environment based on analytic hierarchy process
  80. Fingerprint of magma mixture in the leucogranites: Spectroscopic and petrochemical approach, Kalebalta-Central Anatolia, Türkiye
  81. Principles of self-calibration and visual effects for digital camera distortion
  82. UAV-based doline mapping in Brazilian karst: A cave heritage protection reconnaissance
  83. Evaluation and low carbon ecological urban–rural planning and construction based on energy planning mechanism
  84. Modified non-local means: A novel denoising approach to process gravity field data
  85. A novel travel route planning method based on an ant colony optimization algorithm
  86. Effect of time-variant NDVI on landside susceptibility: A case study in Quang Ngai province, Vietnam
  87. Regional tectonic uplift indicated by geomorphological parameters in the Bahe River Basin, central China
  88. Computer information technology-based green excavation of tunnels in complex strata and technical decision of deformation control
  89. Spatial evolution of coastal environmental enterprises: An exploration of driving factors in Jiangsu Province
  90. A comparative assessment and geospatial simulation of three hydrological models in urban basins
  91. Aquaculture industry under the blue transformation in Jiangsu, China: Structure evolution and spatial agglomeration
  92. Quantitative and qualitative interpretation of community partitions by map overlaying and calculating the distribution of related geographical features
  93. Numerical investigation of gravity-grouted soil-nail pullout capacity in sand
  94. Analysis of heavy pollution weather in Shenyang City and numerical simulation of main pollutants
  95. Road cut slope stability analysis for static and dynamic (pseudo-static analysis) loading conditions
  96. Forest biomass assessment combining field inventorying and remote sensing data
  97. Late Jurassic Haobugao granites from the southern Great Xing’an Range, NE China: Implications for postcollision extension of the Mongol–Okhotsk Ocean
  98. Petrogenesis of the Sukadana Basalt based on petrology and whole rock geochemistry, Lampung, Indonesia: Geodynamic significances
  99. Numerical study on the group wall effect of nodular diaphragm wall foundation in high-rise buildings
  100. Water resources utilization and tourism environment assessment based on water footprint
  101. Geochemical evaluation of the carbonaceous shale associated with the Permian Mikambeni Formation of the Tuli Basin for potential gas generation, South Africa
  102. Detection and characterization of lineaments using gravity data in the south-west Cameroon zone: Hydrogeological implications
  103. Study on spatial pattern of tourism landscape resources in county cities of Yangtze River Economic Belt
  104. The effect of weathering on drillability of dolomites
  105. Noise masking of near-surface scattering (heterogeneities) on subsurface seismic reflectivity
  106. Query optimization-oriented lateral expansion method of distributed geological borehole database
  107. Petrogenesis of the Morobe Granodiorite and their shoshonitic mafic microgranular enclaves in Maramuni arc, Papua New Guinea
  108. Environmental health risk assessment of urban water sources based on fuzzy set theory
  109. Spatial distribution of urban basic education resources in Shanghai: Accessibility and supply-demand matching evaluation
  110. Spatiotemporal changes in land use and residential satisfaction in the Huai River-Gaoyou Lake Rim area
  111. Walkaway vertical seismic profiling first-arrival traveltime tomography with velocity structure constraints
  112. Study on the evaluation system and risk factor traceability of receiving water body
  113. Predicting copper-polymetallic deposits in Kalatag using the weight of evidence model and novel data sources
  114. Temporal dynamics of green urban areas in Romania. A comparison between spatial and statistical data
  115. Passenger flow forecast of tourist attraction based on MACBL in LBS big data environment
  116. Varying particle size selectivity of soil erosion along a cultivated catena
  117. Relationship between annual soil erosion and surface runoff in Wadi Hanifa sub-basins
  118. Influence of nappe structure on the Carboniferous volcanic reservoir in the middle of the Hongche Fault Zone, Junggar Basin, China
  119. Dynamic analysis of MSE wall subjected to surface vibration loading
  120. Pre-collisional architecture of the European distal margin: Inferences from the high-pressure continental units of central Corsica (France)
  121. The interrelation of natural diversity with tourism in Kosovo
  122. Assessment of geosites as a basis for geotourism development: A case study of the Toplica District, Serbia
  123. IG-YOLOv5-based underwater biological recognition and detection for marine protection
  124. Monitoring drought dynamics using remote sensing-based combined drought index in Ergene Basin, Türkiye
  125. Review Articles
  126. The actual state of the geodetic and cartographic resources and legislation in Poland
  127. Evaluation studies of the new mining projects
  128. Comparison and significance of grain size parameters of the Menyuan loess calculated using different methods
  129. Scientometric analysis of flood forecasting for Asia region and discussion on machine learning methods
  130. Rainfall-induced transportation embankment failure: A review
  131. Rapid Communication
  132. Branch fault discovered in Tangshan fault zone on the Kaiping-Guye boundary, North China
  133. Technical Note
  134. Introducing an intelligent multi-level retrieval method for mineral resource potential evaluation result data
  135. Erratum
  136. Erratum to “Forest cover assessment using remote-sensing techniques in Crete Island, Greece”
  137. Addendum
  138. The relationship between heat flow and seismicity in global tectonically active zones
  139. Commentary
  140. Improved entropy weight methods and their comparisons in evaluating the high-quality development of Qinghai, China
  141. Special Issue: Geoethics 2022 - Part II
  142. Loess and geotourism potential of the Braničevo District (NE Serbia): From overexploitation to paleoclimate interpretation
https://doi.org/10.1515/geo-2022-0459
Keywords for this article
varved clays; shear modulus; dynamic strengthening
Creative Commons
BY 4.0

Articles in the same Issue

  1. Regular Articles
  2. Diagenesis and evolution of deep tight reservoirs: A case study of the fourth member of Shahejie Formation (cg: 50.4-42 Ma) in Bozhong Sag
  3. Petrography and mineralogy of the Oligocene flysch in Ionian Zone, Albania: Implications for the evolution of sediment provenance and paleoenvironment
  4. Biostratigraphy of the Late Campanian–Maastrichtian of the Duwi Basin, Red Sea, Egypt
  5. Structural deformation and its implication for hydrocarbon accumulation in the Wuxia fault belt, northwestern Junggar basin, China
  6. Carbonate texture identification using multi-layer perceptron neural network
  7. Metallogenic model of the Hongqiling Cu–Ni sulfide intrusions, Central Asian Orogenic Belt: Insight from long-period magnetotellurics
  8. Assessments of recent Global Geopotential Models based on GPS/levelling and gravity data along coastal zones of Egypt
  9. Accuracy assessment and improvement of SRTM, ASTER, FABDEM, and MERIT DEMs by polynomial and optimization algorithm: A case study (Khuzestan Province, Iran)
  10. Uncertainty assessment of 3D geological models based on spatial diffusion and merging model
  11. Evaluation of dynamic behavior of varved clays from the Warsaw ice-dammed lake, Poland
  12. Impact of AMSU-A and MHS radiances assimilation on Typhoon Megi (2016) forecasting
  13. Contribution to the building of a weather information service for solar panel cleaning operations at Diass plant (Senegal, Western Sahel)
  14. Measuring spatiotemporal accessibility to healthcare with multimodal transport modes in the dynamic traffic environment
  15. Mathematical model for conversion of groundwater flow from confined to unconfined aquifers with power law processes
  16. NSP variation on SWAT with high-resolution data: A case study
  17. Reconstruction of paleoglacial equilibrium-line altitudes during the Last Glacial Maximum in the Diancang Massif, Northwest Yunnan Province, China
  18. A prediction model for Xiangyang Neolithic sites based on a random forest algorithm
  19. Determining the long-term impact area of coastal thermal discharge based on a harmonic model of sea surface temperature
  20. Origin of block accumulations based on the near-surface geophysics
  21. Investigating the limestone quarries as geoheritage sites: Case of Mardin ancient quarry
  22. Population genetics and pedigree geography of Trionychia japonica in the four mountains of Henan Province and the Taihang Mountains
  23. Performance audit evaluation of marine development projects based on SPA and BP neural network model
  24. Study on the Early Cretaceous fluvial-desert sedimentary paleogeography in the Northwest of Ordos Basin
  25. Detecting window line using an improved stacked hourglass network based on new real-world building façade dataset
  26. Automated identification and mapping of geological folds in cross sections
  27. Silicate and carbonate mixed shelf formation and its controlling factors, a case study from the Cambrian Canglangpu formation in Sichuan basin, China
  28. Ground penetrating radar and magnetic gradient distribution approach for subsurface investigation of solution pipes in post-glacial settings
  29. Research on pore structures of fine-grained carbonate reservoirs and their influence on waterflood development
  30. Risk assessment of rain-induced debris flow in the lower reaches of Yajiang River based on GIS and CF coupling models
  31. Multifractal analysis of temporal and spatial characteristics of earthquakes in Eurasian seismic belt
  32. Surface deformation and damage of 2022 (M 6.8) Luding earthquake in China and its tectonic implications
  33. Differential analysis of landscape patterns of land cover products in tropical marine climate zones – A case study in Malaysia
  34. DEM-based analysis of tectonic geomorphologic characteristics and tectonic activity intensity of the Dabanghe River Basin in South China Karst
  35. Distribution, pollution levels, and health risk assessment of heavy metals in groundwater in the main pepper production area of China
  36. Study on soil quality effect of reconstructing by Pisha sandstone and sand soil
  37. Understanding the characteristics of loess strata and quaternary climate changes in Luochuan, Shaanxi Province, China, through core analysis
  38. Dynamic variation of groundwater level and its influencing factors in typical oasis irrigated areas in Northwest China
  39. Creating digital maps for geotechnical characteristics of soil based on GIS technology and remote sensing
  40. Changes in the course of constant loading consolidation in soil with modeled granulometric composition contaminated with petroleum substances
  41. Correlation between the deformation of mineral crystal structures and fault activity: A case study of the Yingxiu-Beichuan fault and the Milin fault
  42. Cognitive characteristics of the Qiang religious culture and its influencing factors in Southwest China
  43. Spatiotemporal variation characteristics analysis of infrastructure iron stock in China based on nighttime light data
  44. Interpretation of aeromagnetic and remote sensing data of Auchi and Idah sheets of the Benin-arm Anambra basin: Implication of mineral resources
  45. Building element recognition with MTL-AINet considering view perspectives
  46. Characteristics of the present crustal deformation in the Tibetan Plateau and its relationship with strong earthquakes
  47. Influence of fractures in tight sandstone oil reservoir on hydrocarbon accumulation: A case study of Yanchang Formation in southeastern Ordos Basin
  48. Nutrient assessment and land reclamation in the Loess hills and Gulch region in the context of gully control
  49. Handling imbalanced data in supervised machine learning for lithological mapping using remote sensing and airborne geophysical data
  50. Spatial variation of soil nutrients and evaluation of cultivated land quality based on field scale
  51. Lignin analysis of sediments from around 2,000 to 1,000 years ago (Jiulong River estuary, southeast China)
  52. Assessing OpenStreetMap roads fitness-for-use for disaster risk assessment in developing countries: The case of Burundi
  53. Transforming text into knowledge graph: Extracting and structuring information from spatial development plans
  54. A symmetrical exponential model of soil temperature in temperate steppe regions of China
  55. A landslide susceptibility assessment method based on auto-encoder improved deep belief network
  56. Numerical simulation analysis of ecological monitoring of small reservoir dam based on maximum entropy algorithm
  57. Morphometry of the cold-climate Bory Stobrawskie Dune Field (SW Poland): Evidence for multi-phase Lateglacial aeolian activity within the European Sand Belt
  58. Adopting a new approach for finding missing people using GIS techniques: A case study in Saudi Arabia’s desert area
  59. Geological earthquake simulations generated by kinematic heterogeneous energy-based method: Self-arrested ruptures and asperity criterion
  60. Semi-automated classification of layered rock slopes using digital elevation model and geological map
  61. Geochemical characteristics of arc fractionated I-type granitoids of eastern Tak Batholith, Thailand
  62. Lithology classification of igneous rocks using C-band and L-band dual-polarization SAR data
  63. Analysis of artificial intelligence approaches to predict the wall deflection induced by deep excavation
  64. Evaluation of the current in situ stress in the middle Permian Maokou Formation in the Longnüsi area of the central Sichuan Basin, China
  65. Utilizing microresistivity image logs to recognize conglomeratic channel architectural elements of Baikouquan Formation in slope of Mahu Sag
  66. Resistivity cutoff of low-resistivity and low-contrast pays in sandstone reservoirs from conventional well logs: A case of Paleogene Enping Formation in A-Oilfield, Pearl River Mouth Basin, South China Sea
  67. Examining the evacuation routes of the sister village program by using the ant colony optimization algorithm
  68. Spatial objects classification using machine learning and spatial walk algorithm
  69. Study on the stabilization mechanism of aeolian sandy soil formation by adding a natural soft rock
  70. Bump feature detection of the road surface based on the Bi-LSTM
  71. The origin and evolution of the ore-forming fluids at the Manondo-Choma gold prospect, Kirk range, southern Malawi
  72. A retrieval model of surface geochemistry composition based on remotely sensed data
  73. Exploring the spatial dynamics of cultural facilities based on multi-source data: A case study of Nanjing’s art institutions
  74. Study of pore-throat structure characteristics and fluid mobility of Chang 7 tight sandstone reservoir in Jiyuan area, Ordos Basin
  75. Study of fracturing fluid re-discharge based on percolation experiments and sampling tests – An example of Fuling shale gas Jiangdong block, China
  76. Impacts of marine cloud brightening scheme on climatic extremes in the Tibetan Plateau
  77. Ecological protection on the West Coast of Taiwan Strait under economic zone construction: A case study of land use in Yueqing
  78. The time-dependent deformation and damage constitutive model of rock based on dynamic disturbance tests
  79. Evaluation of spatial form of rural ecological landscape and vulnerability of water ecological environment based on analytic hierarchy process
  80. Fingerprint of magma mixture in the leucogranites: Spectroscopic and petrochemical approach, Kalebalta-Central Anatolia, Türkiye
  81. Principles of self-calibration and visual effects for digital camera distortion
  82. UAV-based doline mapping in Brazilian karst: A cave heritage protection reconnaissance
  83. Evaluation and low carbon ecological urban–rural planning and construction based on energy planning mechanism
  84. Modified non-local means: A novel denoising approach to process gravity field data
  85. A novel travel route planning method based on an ant colony optimization algorithm
  86. Effect of time-variant NDVI on landside susceptibility: A case study in Quang Ngai province, Vietnam
  87. Regional tectonic uplift indicated by geomorphological parameters in the Bahe River Basin, central China
  88. Computer information technology-based green excavation of tunnels in complex strata and technical decision of deformation control
  89. Spatial evolution of coastal environmental enterprises: An exploration of driving factors in Jiangsu Province
  90. A comparative assessment and geospatial simulation of three hydrological models in urban basins
  91. Aquaculture industry under the blue transformation in Jiangsu, China: Structure evolution and spatial agglomeration
  92. Quantitative and qualitative interpretation of community partitions by map overlaying and calculating the distribution of related geographical features
  93. Numerical investigation of gravity-grouted soil-nail pullout capacity in sand
  94. Analysis of heavy pollution weather in Shenyang City and numerical simulation of main pollutants
  95. Road cut slope stability analysis for static and dynamic (pseudo-static analysis) loading conditions
  96. Forest biomass assessment combining field inventorying and remote sensing data
  97. Late Jurassic Haobugao granites from the southern Great Xing’an Range, NE China: Implications for postcollision extension of the Mongol–Okhotsk Ocean
  98. Petrogenesis of the Sukadana Basalt based on petrology and whole rock geochemistry, Lampung, Indonesia: Geodynamic significances
  99. Numerical study on the group wall effect of nodular diaphragm wall foundation in high-rise buildings
  100. Water resources utilization and tourism environment assessment based on water footprint
  101. Geochemical evaluation of the carbonaceous shale associated with the Permian Mikambeni Formation of the Tuli Basin for potential gas generation, South Africa
  102. Detection and characterization of lineaments using gravity data in the south-west Cameroon zone: Hydrogeological implications
  103. Study on spatial pattern of tourism landscape resources in county cities of Yangtze River Economic Belt
  104. The effect of weathering on drillability of dolomites
  105. Noise masking of near-surface scattering (heterogeneities) on subsurface seismic reflectivity
  106. Query optimization-oriented lateral expansion method of distributed geological borehole database
  107. Petrogenesis of the Morobe Granodiorite and their shoshonitic mafic microgranular enclaves in Maramuni arc, Papua New Guinea
  108. Environmental health risk assessment of urban water sources based on fuzzy set theory
  109. Spatial distribution of urban basic education resources in Shanghai: Accessibility and supply-demand matching evaluation
  110. Spatiotemporal changes in land use and residential satisfaction in the Huai River-Gaoyou Lake Rim area
  111. Walkaway vertical seismic profiling first-arrival traveltime tomography with velocity structure constraints
  112. Study on the evaluation system and risk factor traceability of receiving water body
  113. Predicting copper-polymetallic deposits in Kalatag using the weight of evidence model and novel data sources
  114. Temporal dynamics of green urban areas in Romania. A comparison between spatial and statistical data
  115. Passenger flow forecast of tourist attraction based on MACBL in LBS big data environment
  116. Varying particle size selectivity of soil erosion along a cultivated catena
  117. Relationship between annual soil erosion and surface runoff in Wadi Hanifa sub-basins
  118. Influence of nappe structure on the Carboniferous volcanic reservoir in the middle of the Hongche Fault Zone, Junggar Basin, China
  119. Dynamic analysis of MSE wall subjected to surface vibration loading
  120. Pre-collisional architecture of the European distal margin: Inferences from the high-pressure continental units of central Corsica (France)
  121. The interrelation of natural diversity with tourism in Kosovo
  122. Assessment of geosites as a basis for geotourism development: A case study of the Toplica District, Serbia
  123. IG-YOLOv5-based underwater biological recognition and detection for marine protection
  124. Monitoring drought dynamics using remote sensing-based combined drought index in Ergene Basin, Türkiye
  125. Review Articles
  126. The actual state of the geodetic and cartographic resources and legislation in Poland
  127. Evaluation studies of the new mining projects
  128. Comparison and significance of grain size parameters of the Menyuan loess calculated using different methods
  129. Scientometric analysis of flood forecasting for Asia region and discussion on machine learning methods
  130. Rainfall-induced transportation embankment failure: A review
  131. Rapid Communication
  132. Branch fault discovered in Tangshan fault zone on the Kaiping-Guye boundary, North China
  133. Technical Note
  134. Introducing an intelligent multi-level retrieval method for mineral resource potential evaluation result data
  135. Erratum
  136. Erratum to “Forest cover assessment using remote-sensing techniques in Crete Island, Greece”
  137. Addendum
  138. The relationship between heat flow and seismicity in global tectonically active zones
  139. Commentary
  140. Improved entropy weight methods and their comparisons in evaluating the high-quality development of Qinghai, China
  141. Special Issue: Geoethics 2022 - Part II
  142. Loess and geotourism potential of the Braničevo District (NE Serbia): From overexploitation to paleoclimate interpretation
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 26.9.2025 from https://www.degruyterbrill.com/document/doi/10.1515/geo-2022-0459/html?lang=en
Scroll to top button