Superabsorbent polymers (SAPs) are widely applied in dryland agriculture. However, their functional property of repeated absorption and release of soil water exerts periodic effects on the hydraulic parameters and water-retention properties of soil, and as this property gradually diminishes with time, its effects tend to be unstable. During the 120-day continuous soil cultivation experiment described in this paper, horizontal soil column infiltration and high-speed centrifugation tests were conducted on SAP-treated soil to measure unsaturated diffusivity D and soil water characteristic curves. The experimental results suggest that the SAP increased the water retaining capacity of soil sections where the suction pressure was between 0 and 3,000 cm. The SAP significantly obstructed water diffusion in the soil in the early days of the experiment, but the effect gradually decreased in the later period. The average decrease in water diffusivity in the treatment groups fell from 76.6% at 0 days to 1.2% at 120 days. This research also provided parameters of time-varying functions that describe the unsaturated diffusivity D and unsaturated hydraulic conductivity K of soils under the effects of SAPs; in future research, these functions can be used to construct water movement models applicable to SAP-treated soil.
the National Natural Science Foundation of China51379210National Science and Technology Project2015BAD20B03Beijing Science and Technology PlanD1511000041150021. Introduction
The application of superabsorbent polymers (SAPs) for the purpose of enhancing soil water retention represents an important nonengineering water conservation technique for dryland farming. This technique is widely used in producing crops such as apples, grapes, wheat, and maize [1–4], and it has proven to be effective in saving water and increasing yields. In many farming areas with limited water supplies, crop growth relies completely on rainwater. However, the uneven spatiotemporal distribution of precipitation and the soil’s poor ability to conserve moisture keep rainwater use efficiency low in these areas, exerting a direct impact on crop growth [5–7]. Applying SAPs to the soil is effective in improving rainwater use efficiency in dryland farming areas [8, 9], because SAPs can repeatedly absorb and retain rainwater entering the soil to reduce deep seepage losses and then gradually release the water to the plants as the soil dries and the plants’ root pressure increases. This mechanism ensures a continuous water supply for plants during their growth periods [10, 11].
After treatment with SAPs, soil demonstrates remarkable changes in its hydraulic parameters and water holding properties. Han et al. [12] found that the periodic absorption and release of water by SAPs exert time-varying effects on the soil’s properties, causing the hydraulic parameters in SAP-treated soil to vary irregularly with time. Bai et al. [13] discovered that, during wet-dry soil cycles, the application of SAPs can reduce soil’s bulk density, with a higher SAP dosage producing a greater effect. Other studies [14–17] have revealed that the repeated water absorption and release mechanism of SAPs not only ensures water supply for plants, but also alters the pattern of soil water movement by influencing the soil’s mechanical and chemical properties, local microbial communities, and root growth. This adds to the difficulty and complexity inherent in modeling water movement in soil to which SAPs have been applied.
Accurate characterization of soil’s hydraulic parameters and water retention properties is a key step in modeling water movement [18–20]. However, only a few studies have provided quantitative descriptions of the dynamic characteristics of SAP-treated soil’s hydraulic parameters [12, 21, 22]. The dynamic effects of SAPs on soil’s hydraulic parameters and water retention properties are not yet clear, obstructing in-depth research into water movement models that are applicable to SAP-treated soils, as well as other related research.
In this context, a 120-day soil cultivation experiment was carried out, with horizontal soil column infiltration and high-speed centrifugation tests conducted to investigate the patterns of dynamic variation in the hydraulic parameters and water holding properties of SAP-treated soil. Time-varying functions were obtained to describe the unsaturated diffusivity and unsaturated hydraulic conductivity of soil, providing a basis for constructing relevant models, such as a model of soil water movement under the influence of SAPs.
2. Methods2.1. Materials
This experiment tested a cross-linked soil SAP with particle sizes between 0.02 and 0.05 mm, manufactured from polyacrylamide and acrylic acid by Dongying Huaye New Material Co., Ltd., in Shandong. The soil tested was sand loam containing 52.4% sand, 36.1% silt, and 11.5% clay, taken from topsoil in the greenhouses and fields at the International Seed Industry Park in Yujiawu Town, Tongzhou District, Beijing. In terms of nutrients, the tested soil contained total nitrogen of 1.06±0.11 g/kg, available nitrogen of 47.20±0.14 mg/kg, total phosphorus of 0.74±0.01 g/kg, available phosphorus of 26.45±2.33 mg/kg, total potassium of 18.65±1.34 g/kg, rapidly available potassium of 106.00±5.66 mg/kg, and organic content of 10.85±0.21 g/kg. The soil was cultivated in round polyvinyl chloride pots with a height of 35 cm and a diameter of 25 cm.
2.2. Process2.2.1. Treatment
The soil was divided into a control group and three treatment groups. No SAP was applied to the soil in the control sample. In the first treatment group, labeled P-S1, SAP at a polymer concentration of 0.06% was applied to the soil. In the second treatment group, P-S2, 0.03% SAP was applied to the soil. In the third treatment group, P-S3, the soil was treated with 0.01% SAP. Each treatment process was repeated 12 times.
2.2.2. Methods
First, the SAP was evenly mixed with air-dried soil. The mixtures were then put into pots and compacted layer by layer, with each layer being 4 to 5 cm thick, to achieve a bulk density of 1.28 g/cm3. At the bottom of each pot, under the soil mixtures, a 2 cm thick filter bed of gravel was laid upon the drainage hole. After the soil thickness in the pots reached 28 cm, a 2 cm thick layer of quartz sand was applied on the soil surface to reduce evaporation, leaving a 3 cm hydraulic head above the quartz sand for irrigation. After these preparations, the field capacity (FC) of the soil was measured using the cutting ring method, yielding a result of 0.37 cm3/cm3. Every two to three days, four pots were randomly chosen from each sample group and weighed to measure average soil water content. During the experiment, the soil’s volumetric water content was maintained between 60% and 100% of FC. If the volumetric water content of the soil in a pot neared 60% of FC, the soil was irrigated until the value reached 100% of FC.
2.3. Sampling and Testing
Soil in the pots was sampled using cutting rings at 0, 5, 10, 15, 20, 25, 30, 40, 50, 60, 90, and 120 days. Part of each soil sample was packaged in filter paper and tested in the lab using a high-speed centrifugation method to analyze the water characteristic curves. After the remainders of the sampled soils were air-dried, a horizontal soil column infiltration test was conducted to measure their unsaturated diffusivity [12]. Soil’s unsaturated hydraulic conductivity can be calculated from the unsaturated diffusivity measurement according to the following relationships: θ=θr+(θs-θr)/1+αhnm and K(θ)=C(θ)D(θ).
2.4. Data Analysis
The software RETC analyzed the soil water characteristic data to infer the values of unsaturated hydraulic conductivity. The parameters of time-varying functions for unsaturated diffusivity and unsaturated hydraulic conductivity were obtained by R programming and curve fitting.
3. Results and Analysis3.1. Effect of SAP on Unsaturated Soil Water Diffusivity
Figure 1 displays the three-dimensional distribution of unsaturated diffusivity for each of the four groups at 0, 5, 10, 15, 20, 25, 30, 40, 50, 60, 90, and 120 days. The unsaturated diffusivity of the control group changed slightly throughout the experiment, and the population variance of the control group’s data at different times was 0.144. By contrast, all the SAP-treated groups demonstrated significant decreases in unsaturated diffusivity during the early period of the experiment, and the rate of the decreases increased with SAP concentration, such that P-S1 > P-S2 > P-S3. The treatment groups’ unsaturated diffusivities gradually increased with time and were nearly equal to the control group’s at the end of the experiment. The population variances of the unsaturated diffusivity data of the treatment groups were between 0.387 and 0.398.
3D unsaturated diffusivity at different times. (a) Control group; (b) P-S1; (c) P-S2; (d) P-S3. Note: the SAP application time at a point is equal to its y-axis value multiplied by 100.
Also, Figure 1 shows that soil water diffusion was significantly obstructed during the early period. At 0 days, the average decreases in unsaturated diffusivity were between 70.1% and 76.6%. These values fell to between 30.6% and 46.9% at 5 days and reached 49.5% to 68.1% at 10 days. After repeated absorption and release of water, the SAP incurred some structural damage, and SAP water absorbency decreased with time. As a result, the effect on water diffusion in the soil gradually weakened. The average decrease in unsaturated diffusivity dropped to between 9.5% and 25.5% at 60 days and between 9.4% and 26.1% at 90 days. At 120 days, the unsaturated diffusivities of the treatment groups were very close to the control group, and the average decreases in unsaturated diffusivity were 1.2% to 16.0%.
Table 1 presents the curves fitted to the unsaturated diffusivity data and their corresponding degrees of correlation (coefficient of determination, R2) for the four groups at different times (T = 0, 5, 10, 15, 20, 25, 30, 40, 50, 60, 90, and 120 d). A comprehensive regression analysis of the data yielded time-varying functional equations for calculating the unsaturated diffusivity of soil under the effect of SAP. The regression equations show that the time-varying functions include the time variable t, and the goodness of fit of each regression attains extremely high significance (P<0.01), indicating that these functions can accurately describe the relationship between time and the unsaturated diffusivity of soil under the effect of SAPs.
Unsaturated diffusivity of four groups at different times and fitted time-varying functions.
Time (d)
Sample group
CG
P-S1
P-S2
P-S3
T=0
y=0.0394e10.3x
y=0.0813e6.4727x
y=0.0839e5.9665x
y=0.0871e6.3951x
R2=0.89428
R2=0.906
R2=0.87945
R2=0.842
T=5
y=0.0476e9.374x
y=0.0226e9.9152x
y=0.0192e10.363x
y=0.0107e11.545x
R2=0.88238
R2=0.90912
R2=0.9138
R2=0.92577
T=10
y=0.0298e10.589x
y=0.0841e6.9179x
y=0.0568e6.7552x
y=0.0521e8.0808x
R2=0.85276
R2=0.82682
R2=0.87724
R2=0.80069
T=15
y=0.0389e10.067x
y=0.0312e9.6729x
y=0.0586e7.5697x
y=0.0582e8.1997x
R2=0.89588
R2=0.88509
R2=0.85454
R2=0.86273
T=20
y=0.0341e10.412x
y=0.0525e7.8393x
y=0.0335e8.8144x
y=0.0561e7.7954x
R2=0.88312
R2=0.84682
R2=0.90142
R2=0.79191
T=25
y=0.028e10.676x
y=0.0484e8.2939x
y=0.0235e9.3367x
y=0.0489e8.5751x
R2=0.89384
R2=0.765
R2=0.90027
R2=0.82355
T=30
y=0.0332e9.9538x
y=0.0539e8.3136x
y=0.0194e10.268x
y=0.045e8.6653x
R2=0.83787
R2=0.84295
R2=0.89589
R2=0.85636
T=40
y=0.0336e10.385x
y=0.045e8.7363x
y=0.0417e8.2729x
y=0.0336e9.3069x
R2=0.85256
R2=0.84868
R2=0.83049
R2=0.87273
T=50
y=0.0232e11.378x
y=0.0217e11.079x
y=0.0129e11.668x
y=0.0204e10.845x
R2=0.89875
R2=0.90882
R2=0.94285
R2=0.86495
T=60
y=0.0238e11.387x
y=0.0175e11.924x
y=0.023e10.564x
y=0.0285e10.528x
R2=0.8949
R2=0.88716
R2=0.91468
R2=0.83412
T=90
y=0.0323e10.511x
y=0.028e10.634x
y=0.0253e10.414x
y=0.0135e12.467x
R2=0.84247
R2=0.87298
R2=0.90481
R2=0.89243
T=120
y=0.0135e12.467x
y=0.0249e10.86x
y=0.025e10.582x
y=0.0259e11.156x
R2=0.89243
R2=0.89367
R2=0.84869
R2=0.83914
Overall
y=e10.3885x-0.00093t-3.3756
y=e8.80401x+0.00289t-3.42063
y=e8.7892x+0.002612t-3.20427
y=e8.9388x+0.002882t-3.27933
R2=0.8709∗∗
R2=0.857∗∗
R2=0.8415∗∗
R2=0.8185∗∗
∗∗ indicated significant correlation at the 0.01 level.
3.2. Effect of SAP on Soil Water Characteristic Curves
Figure 2 shows the soil water characteristic curves of the four sample groups at 0, 15, 30, 50, 90, and 120 days. The trends of the curves suggest that the SAP improved the water retention properties of the treated soil during the early period. A comparison of the soil water content at different suction pressure ranges demonstrated that the improvement in soil water retention mainly occurred in the suction pressure range of 0 to 3,000 cm, and it was especially marked in the 100 to 800 cm range. At 0 days, the soil in the P-S1, P-S2, and P-S3 groups showed water content increases of 10.6% to 26.4%, 14.2% to 17.0%, and 7.7% to 10.6%, respectively, compared to the control group; the P-S1 group experienced the increase of 26.4% at a suction pressure of 300 cm. By 15 days, the soil water content in the P-S1, P-S2, and P-S3 groups increased by 15.4% to 26.5%, 14.8% to 21.6%, and 9.7% to 14.7%, respectively; the largest increase of 26.5% occurred in the P-S1 group at a suction pressure of 500 cm. After a duration of 30 days, the soil water content in the three treatment groups increased by 11.8% to 20.7%, 10.2% to 14.4%, and 5.1% to 9.2%, respectively, with the largest increase of 20.7% occurring in the P-S1 group at a suction pressure of 500 cm. By 50 days, the soil water content increases in each of the three treatment groups were 8.3% to 23.2%, 12.4% to 18.3%, and 8.8% to 14.1%, respectively; the maximum of 23.2% occurred in the P-S1 group at a suction pressure of 100 cm. By 90 days, these values were 10.3% to 13.0%, 7.3% to 11.6%, and 7.1% to 10.4%, with the maximum of 13.0% occurring in the P-S1 group at a suction pressure of 500 cm. At 120 days, the soil water content in the treatment groups was only 5.6% to 7.7%, 3.4% to 4.0%, and 2.7% to 4.2% higher than in the control group, and the P-S1 group saw the highest soil water content increase of 7.7% at a suction pressure of 100 cm. Those soil water characteristic curves were used for predicting specific moisture capacity C(θ) to calculate unsaturated hydraulic conductivities of the soil. Finally, time-varying functions for the unsaturated hydraulic conductivity under the effect of SAP were derived from a series of calculated unsaturated hydraulic conductivities.
Soil water characteristic curves at different times. (a) T = 0 d; (b) T = 15 d; (c) T = 30 d; (d) T = 50 d; (e) T = 90 d; (f) T = 120 d.
3.3. Effect of SAP on Unsaturated Hydraulic Conductivity
Figures 3–8 show the unsaturated hydraulic conductivities of the control group and the treatment groups at 0, 15, 30, 50, 90, and 120 days, respectively. Compared to the control group, we can see the unsaturated hydraulic conductivities of treated soil sample were greatly decreased after SAP application during the early period, similar to the effect of SAP on unsaturated diffusivity. The average decreases in unsaturated hydraulic conductivity were 85.5% to 94.1% at 0 days, 75.1% to 82.9% at 30 days, and 65.6% to 76.2% at 50 days. Notably, abnormalities were observed in regions with high water content in all treatment groups at 30, 90, and 120 days. It was therefore impossible to calculate K values for these regions.
Unsaturated hydraulic conductivity of the four groups at 0 days. (a) Control group; (b) P-S1; (c) P-S2; (d) P-S3.
Unsaturated hydraulic conductivity of the four groups at 15 days. (a) Control group; (b) P-S1; (c) P-S2; (d) P-S3.
Unsaturated hydraulic conductivity of the four groups at 30 days. (a) Control group; (b) P-S1; (c) P-S2; (d) P-S3.
Unsaturated hydraulic conductivity of the four groups at 50 days. (a) Control group; (b) P-S1; (c) P-S2; (d) P-S3.
Unsaturated hydraulic conductivity of the four groups at 90 days. (a) Control group; (b) P-S1; (c) P-S2; (d) P-S3.
Unsaturated hydraulic conductivity of the four groups at 120 days. (a) Control group; (b) P-S1; (c) P-S2; (d) P-S3.
Table 2 displays the curves fitted to unsaturated hydraulic conductivity data at different times (T = 0, 15, 30, 50, 90, and 120 d), as well as corresponding degrees of correlation. Time-varying functional equations describing soil’s unsaturated hydraulic conductivity were constructed through a comprehensive regression analysis. As the regression equations show, these functions include the time variable t, and each regression’s goodness of fit attained extremely high significance (P<0.01), demonstrating that these functions can precisely reflect the relationships of unsaturated hydraulic conductivity varying with the test time under the influence of SAP.
Unsaturated hydraulic conductivity at different times and fitted time-varying functions.
Time (d)
Sample group
CG
P-S1
P-S2
P-S3
T=0
y=1E-08e30.9x
y=1E-07e20.96x
y=2E-07e20.482x
y=2E-08e26.611x
R2=0.98014
R2=0.94428
R2=0.90433
R2=0.95688
T=15
y=7E-08e26.55x
Y=4E-08e24.663x
y=2E-07e20.871x
y=1E-07e23.141x
R2=0.9592
R2=0.96746
R2=0.94507
R2=0.93723
T=30
y=8E-08e24.229x
y=1E-07e21.68x
y=2E-08e25.708x
y=4E-08e25.779x
R2=0.96186
R2=0.95621
R2=0.93738
R2=0.96299
T=50
y=4E-08e28.525x
y=3E-08e26.353x
y=2E-08e27.173x
y=3E-08e26.771x
R2=0.97868
R2=0.94403
R2=0.97353
R2=0.96353
T=90
y=6E-08e25.988x
y=4E-08e25.597x
y=3E-08e26.226x
y=1E-08e28.494x
R2=0.96934
R2=0.95079
R2=0.95412
R2=0.9598
T=120
y=2E-08e27.958x
y=4E-08e25.532x
Y=3E-08e26.751x
y=2E-08e29.285x
R2=0.96096
R2=0.97013
R2=0.94311
R2=0.91343
Parameter
y=eax+bt+cx2+dt2+f
Overall
a
4.02E+01
5.49E+01
4.67E+01
5.17E+01
b
1.80E-03
2.74E-03
8.14E-03
-2.16E-03
c
-2.08E+01
-4.98E+01
-3.71E+01
-4.29E+01
d
-5.62E-05
-8.69E-06
-3.88E-05
1.62E-05
f
-1.86E+01
-2.11E+01
-2.00E+01
-2.04E+01
R2
0.9659∗∗
0.9708∗∗
0.9702∗∗
0.9702∗∗
∗∗ indicated significant correlation at the 0.01 level.
4. Discussion4.1. Water Retention Properties of SAP-Treated Soil
Normally, the water retention properties of soil are closely correlated with the pore size, while the water characteristic curve of a soil sample represents the relationship between its porosity and water content. When soil is treated with SAP, its water retention properties are related to both porosity and the SAP’s water absorbency. An in-depth analysis of the SAP-treated soil in this study revealed that the SAP had the greatest effect on water retention in soil sections with suction pressure between 100 and 800 cm, because these areas exhibited the greatest increases in water content compared to the control group and other sections in the treatment groups. This result was generally consistent with the conclusion drawn by Han [23], who stated that SAPs have the most dramatic water conservation effects in soil sections with suction pressure between 0 and 1000 cm. It is widely accepted that water stored in the suction pressure range of 0 to 15,000 cm is available water that can be used by plants, and 50% to 70% of the available water content is retained in the suction pressure range of 0 to 800 cm [24]. Therefore, the water held by SAPs in this range was considered to be available for growing plants in this study.
4.2. Hydraulic Parameters of SAP-Treated Soils
The Richards equation-based modeling of soil water movement relies on functions that can accurately characterize a soil’s hydraulic parameters. Normally, the water diffusivity of unsaturated soil only depends on its water content (θ); however, SAP-treated soil’s unsaturated diffusivity is strongly correlated with the duration of the SAP’s presence in the soil (t), in addition to soil water content (θ). The experimental results presented in this paper suggest that the SAP had a strong effect on water diffusion during the early testing period. However, because the SAP’s water-absorbing membrane structure was gradually damaged by microbial decomposition and electrostatic interactions with highly charged ions, fertilizers, and pesticides dissolved in the soil solution [25, 26], the effects of enhancing soil water retention and obstructing soil water movement weakened with time, consistent with the research finding by Han et al. [12]. This suggests that the hydraulic parameters of SAP-treated soil are time-varying and dynamic, a finding that should be fully considered in constructing water movement models.
The variation in unsaturated hydraulic conductivity K under the effect of SAP was similar to the variation in unsaturated diffusivity D, and the fitted functions were also functions of both water content θ and duration t. In this paper, K values were estimates obtained from the measurements of D according to the formula θ=θr+(θs-θr)/1+αhnm rather than real data. The experimental results indicate that when the difference between the fitted saturated water content (θs) and fitted wilting point (θr) was smaller than the difference between the measured water content (θ) and fitted wilting point (θr), error could occur in calculating the hydraulic head (h), thus impeding the accurate characterization of K values in regions with high water content. The lack of K values in these regions has an adverse impact on the accuracy of the fitted time-varying functions; therefore, special attention should be paid to this phenomenon in modeling. The aforementioned error can be reduced by improving the stability and precision of test instruments, such as high-speed centrifuge and electronic scale.
5. Conclusions
During the early testing period, water diffusion in the SAP-treated soil samples was significantly impacted by the presence of SAP. During the period from 0 to 10 days, the average decreases in unsaturated diffusivity decreased were measured at between 30.6% and 76.6%. As the SAP’s water absorbency declined over time, the effect of obstructing soil water movement gradually weakened. During the period between 60 and 120 days, the average decreases in unsaturated diffusivity fell to 1.2% to 26.1%. In contrast, the unsaturated diffusivity of the control group exhibited little variation throughout the experiment; the population variance of the control group’s data at different times was 0.144, compared to 0.387 to 0.398 for the treatment groups.
The experimental SAP greatly decreased the treated soil samples’ unsaturated hydraulic conductivities during the early period, similar to its effect on unsaturated diffusivity. During the period between 0 and 50 days, the average decreases in unsaturated hydraulic conductivity were 65.6% to 94.1%. The K values obtained based on the measurement of D and the formula θ=θr+(θs-θr)/1+αhnm were dramatically affected by the accuracy of the fitted parameters of the soil water characteristic curve.
The experimental SAP improved the water retaining capacity of soil sections where the suction pressure was between 0 and 3,000 cm, resulting in an average increase of 2.7% to 26.5% in soil water content in the treatment groups. The improvement in soil water retention was especially marked in sections with suction pressure ranging from 100 to 800 cm, and the water stored in this section was considered to be available water.
Competing Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
This work was financially supported by the National Natural Science Foundation of China (51379210), National Science and Technology Project (2015BAD20B03), and Beijing Science and Technology Plan (D151100004115002).
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