The Combined Effects of Moss-Dominated Biocrusts and Vegetation on Erosion and Soil Moisture and Implications for Disturbance on the Loess Plateau, China

Chongfeng Bu; Shufang Wu; Fengpeng Han; Yongsheng Yang; Jie Meng

doi:10.1371/journal.pone.0127394

Abstract

Biological soil crusts (BSCs, or biocrusts) have important positive ecological functions such as erosion control and soil fertility improvement, and they may also have negative effects on soil moisture in some cases. Simultaneous discussions of the two-sided impacts of BSCs are key to the rational use of this resource. This study focused on the contribution of BSCs while combining with specific types of vegetation to erosion reduction and their effects on soil moisture, and it addressed the feasibility of removal or raking disturbance. Twelve plots measuring 4 m × 2 m and six treatments (two plots for each) were established on a 15° slope in a small watershed in the Loess Plateau using BSCs, bare land (as a control, BL), Stipa bungeana Trin. (STBU), Caragana korshinskii Kom. (CAKO), STBU planted with BSCs (STBU+BSCs) and CAKO planted with BSCs (CAKO+BSCs). The runoff, soil loss and soil moisture to a depth of 3 m were measured throughout the rainy season (from June to September) of 2010. The results showed that BSCs significantly reduced runoff by 37.3% and soil loss by 81.0% and increased infiltration by 12.4% in comparison with BL. However, when combined with STBU or CAKO, BSCs only made negligible contributions to erosion control (a runoff reduction of 7.4% and 5.7% and a soil loss reduction of 0.7% and 0.3%). Generally, the soil moisture of the vegetation plots was lower in the upper layer than that of the BL plots, although when accompanied with a higher amount of infiltration, this soil moisture consumption phenomenon was much clearer when combining vegetation with BSCs. Because of the trivial contributions from BSCs to erosion control and the remaining exacerbated consumption of soil water, moderate disturbance by BSCs should be considered in plots with adequate vegetation cover to improve soil moisture levels without a significant erosion increase, which was implied to be necessary and feasible.

Citation: Bu C, Wu S, Han F, Yang Y, Meng J (2015) The Combined Effects of Moss-Dominated Biocrusts and Vegetation on Erosion and Soil Moisture and Implications for Disturbance on the Loess Plateau, China. PLoS ONE 10(5): e0127394. https://doi.org/10.1371/journal.pone.0127394

Academic Editor: Wenping Yuan, Beijing Normal University, CHINA

Received: August 10, 2014; Accepted: April 14, 2015; Published: May 20, 2015

Copyright: © 2015 Bu et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited

Data Availability: The authors confirm that all data underlying the findings are fully available without restriction. All relevant data are within the paper and its Supporting Information files.

Funding: The National Natural Science Foundation of China (grant nos. 41071192 & 40701096), the Foundation of State Key Laboratory of Soil Erosion and Dryland Farming on the Loess Plateau (K318009902-1405), and the Chinese Universities Scientific Fund (grant no. 2014YQ006) provided funding for this research.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Biological soil crusts (BSCs, or biocrusts) are complex communities containing bacteria, fungi, lichens, and moss cemented with soil particles. These layers represent the typical ground cover in arid and semi-arid regions and have important ecological functions [1,2,3]. The presence of BSCs significantly affects the physical structure, chemical properties, and biological characteristics of soil. BSCs also impact rainfall infiltration, soil water evaporation, soil erosion, geochemical cycling and species diversity. The developmental and ecological functions of BSCs vary across spatial and temporal scales, as shown in the vast majority of studies in warm and cool deserts at 30°-60° in the middle latitudes [4]. It is widely believed that BSCs fertilize the soil [5,6], increase soil stability [7], and reduce the extent of water or wind erosion [8,9]. However, under different conditions, researchers have reported positive, negative, and neutral relations between BSCs and rainfall infiltration, water evaporation, and vegetation succession [10]. Many studies have shown that BSCs influence the redistribution of rainfall in soil profiles over the long term but also increase the consumption of soil water and reduce soil moisture, which ultimately hinders plant growth [11,12,13]. Therefore, comprehensive investigations on the effects of BSCs on hydrology, soil erosion, and rainfall redistribution are highly valuable for both theoretical and practical purposes, with the aim of understanding a specific condition or region. Fully understanding the positive significance and negative effects of BSCs is the key to balancing between protection and disturbance and to realizing the efficient utilization of these resources.

The Loess Plateau in China is characterized by its unique geomorphology and soil type. Drought and severe soil and water loss are considered to be major environmental issues in this area. The implementation of the “Grains for Green Project” since 1999 has generated substantial environmental benefits and has greatly improved the degraded ecosystems in the Loess Plateau [14]. BSCs are indicative of ecological recovery and are widely distributed. They have a surface coverage of >70% in certain areas of the Loess Plateau [15]. BSCs may affect water erosion and soil moisture in the Loess Plateau region in various ways because of the unique types of BSCs, vegetation communities and soil. Preliminary research has indicated that moss crust covers a large proportion of the Loess Plateau, where it is known to improve soil fertility [16,17], increase infiltration, reduce runoff and greatly decrease soil erosion [18]. Unfortunately, little is known about the effects of BSCs on soil moisture in preventing soil erosion especially in combination with different types of vegetation. The present knowledge regarding the effects of BSCs in the Loess Plateau of China is not sufficient to provide theoretical support for the effective practical management of BSCs.

Based on previous studies, we hypothesized that BSCs would prevent erosion and increase the consumption of soil water on a hillslope on the Loess Plateau. An appropriate balance must therefore be established between the protection and disturbance of BSCs to optimize their positive effects and minimize their negative influences. The contribution of BSCs to erosion prevention is most likely small if they are combined with various types of vegetation. At the same time, they continue to contribute to soil water consumption. Therefore, moderate disturbance measures such as removal or raking may be necessary to improve soil water conditions while maintaining soil erosion control. These actions would positively benefit subsequent vegetation growth. Based on this hypothesis, we established 12 plots with various combinations of two dominant native plant species and BSCs and measured the runoff, soil loss, and soil moisture in 3 m soil profiles within 24 h of rainfall events. These data were used to address the following questions: (i) Do BSCs reduce soil erosion on slopes? (ii) What is the contribution of BSCs to erosion reduction if they are combined with specific types of vegetation? (iii) What are the effects of BSCs on soil moisture at different depths? (iv) Do BSCs have different effects on soil moisture in the presence of various types of vegetation? (v) Is it theoretically possible to improve soil water conditions by introducing suitable disturbance measures while avoiding soil erosion?

Materials and Methods

Study site

This study was conducted in the Liudaogou watershed in the western region of Shenmu County, Shaanxi Province, China (110°21′ to 110°23′E, 38°46′ to 38°51′N). The altitude ranges from 1094 to 1274 m, and the watershed area is 6.89 km². The primary gully (length = 4.21 km), which is the second tributary of the Kuye River, runs from north to south. The Liudaogou watershed (Fig 1) is located in the Loess Plateau on the margin of the Mu Us Desert. The vegetation type in the watershed belongs to a transitional zone from forest steppe to dry steppe. The watershed is subject to wind and water crisscross erosion of the loess soils in hilly areas, and the annual soil erosion rate is approximately 10,000 t/km² [19]. The climate is classified as sub-arid temperate zone. Spring and winter are characterized by less rain and more wind, and there is more rain in the summer and autumn, with frequent rainstorms and severe water erosion. The mean annual temperature is 8.4°C. The prevailing wind is from the northwest, and the mean annual wind speed is 2.2 m/s. The mean annual precipitation is approximately 400 mm, and the precipitation from June to September represents approximately 70–80% of the annual precipitation. Shrub vegetation is predominant and includes Caragana korshinskii Kom. (CAKO, a typical native shrub species), Stipa bungeana Trin. (STBU, a typical native grass species), Medicago sativa Linn., Lespedeza dahurica (Laxim.) Schindl., Heteropappus altaicus (Willd.) Novopokr., and various Asteraceae species. This study was approved by Northwest A & F University.

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Fig 1. The location of the watershed study site (orange and white represent sandy and loess soils, respectively) and the wind-water erosion crisscross region (gray area) in the Loess Plateau of China.

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Methods

Experimental design.

In 2008, twelve runoff plots measuring 4 m × 2 m were established on a 15° middle slope that faces northeast and were situated in the central of the catchment. The plots were located in the middle of the partially shaded slope and were arranged in a horizontal line (Fig 2). In the third year (2010) of the study, we recorded the runoff, soil loss and soil moisture in the 3 m soil profiles of these plots within 24 h of rainfall events. Collection tanks 30 cm in diameter and 100 cm in height were placed at the lower side of each plot to collect runoff and soil loss during each rainfall event. The 0–20 cm soil profile was composed of 6.33% clay (<0.002 mm), 22.11% silt (0.002–0.02 mm), and 71.57% sand (>0.02 mm), and the bulk density and saturated water content of the soil was 1.39 g/cm³ and 35.11%, respectively [16], which indicates the basic physical properties of all plots due to the relative homogeneity of Loess soil in profile [20,21]. A total of six treatments were created (Table 1), and two plots were established for each treatment. For the runoff and sediment, eighteen replicates from two plots at each treatment after 9 runoff-producing rainfall events were used for statistical analysis. All experimental plots are regulated by the Institute of Soil and Water Conservation, Chinese Academy of Sciences and Ministry of Water Resources. The individual in this manuscript has given written informed consent (as outlined in the PLOS consent form) to publish these case details.

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Fig 2. Experimental configuration and measured locations for each plot.

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Table 1. Vegetation and BSCs parameters in the experimental plots.

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For the CAKO plots, seeds were drill-sown approximately 3 cm depth during May 2008 with 50 cm of line spacing in four bare plots and thinned out to a 30 cm row spacing after emergence. For the STBU plots, seedlings in the watershed were transplanted into the four bare plots using 30 cm row spacing and 50 cm line spacing. The distance from the first sowing line in the plot to the top was 30 cm, and the distance from the last line in the plot to the bottom was 20 cm (Fig 2).

BSCs were developed using the “mosaic” method [2, 22], i.e., patches of BSCs were collected from the sampling area in the watershed and reassembled in the experimental plots to create the combined plots (i.e., STBU+BSCs and CAKO+BSCs) in July 2008. Only well-developed moss crusts were selected (with a BSCS thickness of approximately 10 mm and coverage >90%). The collected crusts, together with the substrate (the total thickness was 2–3 cm), were then transported and carefully placed manually into the plots in an irregular pattern. After three rainy seasons, the small gaps that were created while transplanting the crusts closed naturally, and the moss crust developed evenly and grew well in comparison with natural conditions. The coverage and thickness of the BSCs in each plot were measured and are listed in Table 1. The dominant species of the local moss crust included Bryum argenteum Hedw. of the Bryaceae and Didymodon constrictus (Mitt.) Saito of the Pottiaceae [23]. Two bare plots without vegetation or BSCs (BL, bare land plots) were used as controls. The weeds in all the plots were removed carefully at regular intervals without BSCs or vegetation damage. The BSCs pavement processes and a panoramic view of the experimental plots is shown in S1 Fig. When runoff, infiltration, and soil moisture measurements were performed in 2010, the BSC coverage was paved artificially by approximately 95%, and the coverage levels in the CAKO and STBU plots were 55% and 45%, respectively.

Monitoring methods.

Time domain reflectometry (TDR, IMKO Company, Germany) with intelligent microelements was used to monitor the variation in the soil moisture at depths of 0 to 300 cm (in 10 cm layers) in the middle of each plot (Fig 2) in June (early in the rainy season) and September (at the end of the rainy season) of 2010, and one probe pipe was installed before BSC transplant or vegetation planting in the middle of each plot. The values reading are obtained automatically through a probe-inserted pipe during the measurement. Ten soil moisture values from two plots within each 50 cm profile (10 cm interval) were considered as replicates of each treatment for statistical analysis. The amount of rainfall was measured using a standard rain gauge placed near the experimental plots. The runoff and eroded soil were collected using collection tanks at the lower border of each plot (Fig 2) and were measured within 24 h of each rainfall event.

Data analysis

We calculated the following indices based on field measurements: (1) (2) (3) Where RC is the Runoff coefficient, R is runoff, R_a is rainfall, IC is the Infiltration coefficient, I is infiltration, ERR is the Efficiency of runoff reduction, R_t is the runoff of a treatment, and R_b is the runoff of BL.

This index represents the efficiency of a treatment in reducing runoff in comparison with the BL plot. (4) Where CBRR is the Contribution of BSC to runoff reduction, R_tb is the runoff of the treatment with BSC, R_b is the runoff of BL, R_twb is the runoff from the treatment without BSC, E_CTRR is the Efficiency of the combined treatment in runoff reduction, and E_VTRR is the Efficiency of the vegetation-only treatment in runoff reduction.

This index describes the BSC contribution to the runoff reduction when combined with vegetation. (5) Where EII is the Efficiency of increased infiltration, I_t is the infiltration of a treatment, and I_b is the infiltration of BL.

This index represents the efficiency of a treatment in increasing infiltration in comparison with the BL plot. (6) Where CBII is the Contribution of BSC to increased infiltration, I_tb is the infiltration of the treatment with BSC, I_b is the infiltration of BL, I_twb is the infiltration of the treatment without BSC, E_CTII is the Efficiency of the combined treatment in increasing infiltration, E_VTII is the Efficiency of the vegetation-only treatment in increasing infiltration.

This index represents the BSC contribution to the increase in infiltration when combined with vegetation. (7) Where ESR is the Efficiency in soil loss reduction, S_t is the soil loss in a treatment, and S_b is the soil loss in BL.

This index represents the efficiency of a treatment in reducing soil loss in comparison with the BL plot. (8) Where CBSR is the Contribution of BSCs to soil loss reduction, S_tb is the soil loss of the treatment with BSC, S_b is the soil loss in BL, S_twb is the soil loss of the treatment without BSC, E_CTSR is the Efficiency of the combined treatment in soil loss reduction, and E_VTSR is the Efficiency of the vegetation-only treatment in soil loss reduction.

This index describes the BSC contribution to the reduction in soil loss when combined with vegetation.

The study data were analyzed with Microsoft Excel 2007. Under the nine runoff-producing rainfall events, eighteen measurements of runoff and sediment for each treatment with two replicate plots were expressed as the Mean ± SE. Ten soil moisture values from two plots within each 50 cm profile were presented as the Mean ± SE. All measured values of the same index for each treatment were compared with the difference between treatments using a one-way ANOVA and LSD tests in SPSS software (SPSS Inc. Chicago, IL, USA).

Results

Effects of BSCs and vegetation on runoff and infiltration

Nine rainfall events totaling 224.5 mm occurred during the study. The total runoff and infiltration differed significantly among treatments except STBU and STBU+BSCs (p<0.05) (Fig 3). The runoff decreased in the following order: CAKO+BSCs > CAKO > STBU+BSCs > STBU > BSCs > BL. The runoff from the BSCs plots and the BSCs plus vegetation plots was significantly lower than that of the control (BL). By contrast, the infiltration increased as the runoff decreased. Greater runoff reduction was observed in the combined BSC treatments with vegetation.

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Fig 3. The runoff and infiltration for the different treatments after the nine rainfall events.

Note: The values were presented as the Mean ± SE, different letters indicate significant differences at P< 0.05. Abbreviations: BL, bare land; BSCs, biological soil crusts; STBU, Stipa bungeana Trin.; CAKO, Caragana korshinskii Kom.

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In compared with BL, the effects of BSCs alone on the runoff reduction and infiltration increase were 37.3% and 12.4%, respectively. These effects were smaller than the corresponding effects of the STBU treatment (58.5% and 19.4%, respectively) or the CAKO treatment (90.1% and 29.9%, respectively) (Table 2). The runoff and infiltration coefficients showed the same trend as the runoff and infiltration, and there were similar significant differences among the treatments (p<0.05). The effects of vegetation on runoff and infiltration were substantially greater than the effects attributed to BSCs alone. The effects were greatest when STBU or CAKO was combined with BSCs. For example, the STBU+BSCs treatment reduced runoff by 65.9% and increased infiltration by 21.9%. The CAKO+BSCs treatment reduced runoff by 95.8% and increased infiltration by 31.8%. In the STBU+BSCs treatment, the BSCs reduced runoff by 7.4% and increased infiltration by 2.5%. In the CAKO+BSCs treatment, the BSCs reduced runoff by 5.7% and increased infiltration by 1.9%, which was smaller than the effect of the BSCs treatment (p<0.05). This finding suggests that although BSCs greatly reduced the runoff and increased infiltration relative to BL, their effects were smaller than those found if BSCs were combined with vegetation (no significant difference was observed between CAKO and STBU: p>0.05). Thus, vegetation played an important role in controlling runoff and promoting infiltration, whereas BSCs under vegetation contributed very little although BSCs alone had a substantial effect on runoff.

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Table 2. Runoff and infiltration after nine rainfall events (cumulative rainfall = 224.5 mm).

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Effects of BSCs and vegetation on erosion

During this study, the relation between runoff accumulation and soil loss in each treatment after the nine rainfall events showed that soil loss could be approximated by an exponential model of accumulated runoff (y = 3.752e^0.111x, R² = 0.978, where y is the cumulative soil loss and x is the cumulative runoff). The intensity of erosion increased sharply as a function of the runoff intensity.

Both BSCs and vegetation significantly reduced the extent of erosion (p<0.05) (Fig 4, Table 3). The erosion reduction efficiencies of different treatments were as follows: CAKO+BSCs (99.8%) and CAKO (99.5%) > STBU+BSCs (96.6%) and STBU (95.9%) > BSCs (81.0%). There were no significant differences in the erosion reduction efficiencies between the STBU and STBU+BSCs treatments or between the CAKO and CAKO+BSCs treatments (p>0.05). On average, BSCs alone reduced the soil loss by 81.0%, with a corresponding contribution to erosion reduction of 81.0%. The contribution of BSCs in the combined treatments to the reduced soil loss was only 0.7% in the STBU+BSCs treatment and 0.3% in the CAKO+BSCs treatment. This finding indicates that vegetation was responsible for most of the erosion reduction in the BSCs plus vegetation treatment. Based on these results and the analysis of runoff and infiltration described above, it can be concluded that the BSC contribution to runoff reduction or soil loss was not substantial when adequate vegetation was present.

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Fig 4. The erosion intensity for the different treatments after the nine rainfall events.

Note: The values were presented as the Mean ± SE, different letters indicate significant differences at P< 0.05. Abbreviations: BL, bare land; BSCs, biological soil crusts; STBU, Stipa bungeana Trin.; CAKO, Caragana korshinskii Kom.

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Table 3. Soil erosion in different treatments after the rainfall events.

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Effects of BSCs and vegetation on soil moisture

When compared with the same treatment in June and September (Figs 5A and 6A, Figs 5B and 6B, Figs 5C and 6C), as a whole, each treatment had higher soil moisture levels at the end of the rainy season than at the beginning in the top 100 cm of soil. At the beginning of the rainy season, the precipitation and soil water consumption were low, and the soil moisture in the six treatment plots was less than or close to 15%. In comparison with the BL plots, the soil moisture of the covered plots (with BSCs, vegetation, or both) was lower in the upper layer (0–150 cm) and higher in the lower layer (150–300 cm) (p<0.05, except for 50–100 cm and 100–150 cm in the BSC plots; Tables 4 and 5).

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Fig 5. The distribution of soil moisture in the 0–300 cm soil profile at the beginning of the rainy season (20 June 2010).

Abbreviations: BL, bare land; BSCs, biological soil crusts; STBU, Stipa bungeana Trin.; CAKO, Caragana korshinskii Kom.

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Fig 6. The distribution of soil moisture in the 0–300 cm soil profile at the end of the rainy season (21 September 2010).

Abbreviations: BL, bare land; BSCs, biological soil crusts; STBU, Stipa bungeana Trin.; CAKO, Caragana korshinskii Kom.

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Table 4. The soil water content in each treatment at 50-cm intervals on June 20, 2010 (at the start of the rainy season, which was characterized by low rainfall, low soil water consumption, and low soil water content).

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Table 5. The soil water content in each treatment at 50-cm intervals on September 21, 2010 (at the end of the rainy season, which was characterized by high rainfall, high soil water consumption, and high soil water content).

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Early in the rainy season (Fig 5A), the soil moisture in the top 50 cm of soil in the BSC plots was lower than that in the BL plots (p<0.05, Table 4), and it was higher in the soil layers below 100 cm in the BSC plots than in the BL plots. At the end of the rainy season (Fig 6A), the soil moisture was higher in the BSC plots than in the BL plots in most soil layers (p<0.05, Table 5). The BSCs treatment had higher infiltration amounts (the efficiency of the increasing infiltration was 12.4%, Table 2). The soil layers from 0–100 cm were the most affected by BSCs.

Throughout the study period, the STBU+BSCs treatment (Figs 5B and 6B) had higher soil water levels at >150 cm depth in comparison with the BL plot (p<0.05, Tables 4 and 5), whereas these levels were lower than they were in the BL plot at depths of <150 cm. The increased infiltration in the STBU+BSCs treatment (infiltration increased by 21.9%, whereas BSC alone increased infiltration by 2.5%) was slightly higher than that of the STBU treatment. These results may indicate that the combined STBU+BSCs treatment had greater water consumption in the <150 cm soil layer. The soil moisture at different depths in the CAKO plot is shown in Figs 5C and 6C. These data also suggest that there was higher water consumption in the CAKO treatment because the soil moisture at <150 cm was significantly lower than that in the BL treatment (p<0.05, Tables 4 and 5).

Discussion

The retention and consumption of soil moisture

The hydrological effects of BSCs are extremely complex. Their effects on infiltration and runoff can be influenced by rainfall properties, BSC characteristics, topography, and soil type, and the effects of various factors may vary in strength under different circumstances [24]. Several similar discussions assume that BSCs reduce the soil infiltration rate, attenuate the soil infiltration capacity, and degrade the soil water regime [25,26]. These assumptions are only partially supported by our current results and previous studies [27,28]. Many studies have suggested that the lower infiltration rate caused by BSCs may reduce the infiltration capacity, increase runoff, and intensify erosion, especially in areas prone to water erosion [29,30,31]. Our previous study [27] also showed that BSCs alone significantly reduced the initial soil infiltration rate to 53% and reduced the stable soil infiltration rate to 52% compared with bare soil. However, the amount of accumulated infiltration from the present treatment plots was higher after each rainfall event, and the corresponding runoff was significantly lower than that of the BL plot. We conclude that a decrease in the infiltration rate does not always produce a decrease in the infiltration capacity. The presence of BSCs can refine the soil particles [32], reduce the void ratio [33,34], and reduce the infiltration rate. At the same time, the soil hygroscopicity can increase with the presence of BSCs, which can enhance the soil surface roughness [10] and substantially decrease the rate of runoff in water erosion regions [35]. Therefore, the presence of BSCs can extend the water residence time on sloped surfaces. The effects caused by a reduced infiltration rate can be offset and exceeded by an increased infiltration time, which can increase the infiltration capacity after each rainfall event.

The current study showed that BSCs may have increased the soil water consumption in the upper soil layer, with moss transpiration and evaporation through the capillary system associated with a compact layer of BSCs, especially when the soil was relatively dry. A previous evaporation experiment by Xiao et al. [26] showed that a lower level of soil moisture corresponded to greater evaporation under certain circumstances. This result is consistent with our findings, and it is probable that the observed effect is related to increased plant transpiration from the soil crust. Soil moisture absorption may also increase with the presence of BSCs [10], resulting in an increased infiltration amount. Consequently, infiltrated water could persist in the upper soil layer, producing higher rates of evaporation. At the end of the growth season, lower temperatures may have led to lower observed evaporation and transpiration rates than those occurring during the growing season. Correspondingly, the soil moisture in the top layers of the BSCs treatment was greater than that of the BL plots. This finding is consistent with the results of a previous study performed in the Tengger Desert in China [25], where the infiltration depth was reduced because of the higher water-holding capacity of the BSCs, thereby increasing the topsoil moisture.

In the current experiment, the soil moisture in most cases was significantly higher in the vegetation treatments without BSCs than in those with BSCs (a difference in the soil moisture was detected at the following depths: BSCs < 0.5 m, STBU+BSCs < 1.5 m, and CAKO+BSCs < 2.0 m) although the amount of infiltration in the latter was even slightly higher than that in the former (Table 2). These findings indicate that BSCs further exacerbated soil moisture when associated with vegetation. When vegetation and BSCs coexisted, the competition for water resources between the BSC and vegetation may have caused the vegetation to use more soil water from deeper soil layers, and BSCs primarily used water from the top layers. The fertilization effects of BSCs [15] likely promoted the growth of vegetation, which led to increased water uptake by the vegetation. This fertilization effect is supported by the finding that the influence of the combined treatments on the soil moisture level was less in deeper soil layers in comparison with that of the vegetation-only treatment. A comparison of the combined treatments showed that the BSC influence on soil moisture was much stronger in the presence of a shrub species (CAKO) than with a grass species (STBU), most likely because of the difference in the rooting depths of these plants. Therefore, we propose that the BSC effect on the soil moisture is not a direct effect, but is instead realized via competition with vegetation for water resources and/or the fertilization effect of BSCs that stimulates plant growth.

Implications for disturbance and protection

Soil hydrology processes including infiltration, runoff, and evaporation and strongly depends on the crust type, soil characteristics, initial soil moisture, and rainfall intensity. Despite the complexity of these affecting factors, the runoff coefficient can be predicted over extended time scales based on the surface storage capacity [36]. Our study showed that BSCs play significant roles in reducing runoff and soil erosion during the rainy season. Soil erosion was reduced by 81% in the BSC treatment in comparison with the BL plots, and this effect was further strengthened when BSCs were combined with vegetation. These results were consistent with previous findings [17,18]. By contrast, the contribution of BSCs to erosion reduction was negligible in the combined BSC and vegetation treatments. For example, the contributions of BSCs to runoff reduction and soil loss in the STBU+BSCs plots were 7.4% and 0.7%, respectively, and 5.7% and 0.3% in the CAKO+BSCs plots, respectively. Furthermore, BSCs may influence soil moisture through competition with vegetation for water resources and fertilization effects, both of which would enhance water consumption from deeper soil layers by the plants.

Based on the effects of BSCs on soil erosion and soil moisture, we suggest that the long-term goal to support a sustainable environment can be achieved through an appropriate coverage with vegetation and BSCs. However, BSCs also have the ability to increase the infiltration capacity, reduce runoff and erosion, and facilitate plant growth through fertilization, although BSCs may compete with vegetation for water resources. Therefore, the removal disturbance of BSCs should be performed with extreme caution for the purpose of improving soil moisture levels. BSCs can be re-established rapidly, and their soil stabilization and erosion protection functions may be recovered within one rainy season after disturbance [37]. However, removing BSCs from plots with little or no vegetation cover on sloping land greatly increases the extent of soil erosion [31]. Such disturbance also significantly reduces the recharge from rainfall infiltration even though the water consumption in the surface layer is reduced slightly after removing the BSCs. From the perspective of soil and water conservation, the protection of BSCs in plots with less vegetation is of primary importance especially during the rainy season because of water erosion. The intermediate-disturbance hypothesis suggests that moderate disturbance levels will maximize the species diversity in BSCs [38]. If disturbances are deemed necessary, this work should be performed with care at the end of the rainy season to avoid severe erosion and water loss from the topsoil. For example, Li et al. (2009) proposed that low-density grazing disturbance is preferred for a sustainable ecological use [39].

It should be noted that our study was performed under simulated removal disturbance conditions. With different disturbance levels or methods, the BSCs may have different effects on erosion, infiltration, water consumption, and competition with vegetation. Sonia et al. [40] found that removing cyanobacteria-dominated or lichen-dominated BSCs led the soil moisture in the upper layer to decrease, which is inconsistent with our results likely because of the BSC type. Another report [41] demonstrated that crust removal increased water infiltration in other crust types except lichen and moss crusts on coarse-textured soil. In addition, the contradictory relations between plants and BSCs have been attributed to one or two independent processes of vascular plant population recruitment. It is necessary to understand the BSC effects by synthesizing available information at each stage, including germination, seedling survival, and seedling growth [22]. Exotic plant emergence has been found to be greater after BSC disturbance, and native plants were shown to be less likely to emerge [42]. Currently, the consequences that are aimed at different frequencies, times, and intensities of BSC disturbances such as fire, grazing, removal, and trampling are not completely understood [43].

From the analysis above, the disturbance views concluded from our experiment could not be extrapolated directly to a different region. To implement a rational disturbance as an effective management practice of BSC resources on the Loess Plateau, further studies should investigate the long-term effects of BSC and vegetation combinations on soil moisture and erosion [44]. More discussion about the manner (raking, removal, trampling, grazing, fire, etc.), intensity (light, moderate, or severe) and moment (rainy or drought season, growing or dormant period) of the disturbance must be conducted widely and deeply to determine the optimal BSC disturbance. Nevertheless, the current study demonstrates the contribution of BSCs to soil erosion reductions with and without the presence of vegetation. Our investigation reveals the combined effects of BSCs and vegetation regarding soil water utilization, thus implying that it is useful information for the effective management of BSCs.

Conclusions

Our results demonstrate that BSCs alone significantly reduced runoff by 37.3% and soil loss by 81.0% and increased infiltration by 12.4% in comparison with BL. These crusts should be proposed for protection or development for the effective control of erosion where vegetation is sparse, although BSCs exacerbate the consumption of soil water in the upper layer, especially during the drought season. However, if combined with Stipa bungeana Trin. (STBU) or Caragana korshinskii Kom. (CAKO), BSCs only contributed runoff reductions of 7.4% and 5.7%, soil loss reductions of 0.7% and 0.3%, and infiltration increases of 2.5% and 1.9%, respectively. Considering these negligible contributions from BSCs to erosion control and the remaining exacerbated consumption of soil water in the profile, removal or raking disturbances of BSCs in combination with a high vegetation cover could be considered to improve soil moisture levels and positively benefit vegetation growth without significantly increasing erosion, which is necessary and feasible.

Supporting Information

S1 Fig. The BSCs pavement processes and a panoramic view of the experimental plots during the second rainy season.

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(DOC)

Acknowledgments

The National Natural Science Foundation of China (grant nos. 41071192 & 40701096), the Foundation of the State Key Laboratory of Soil Erosion and Dryland Farming on the Loess Plateau (K318009902-1405), and the Chinese Universities Scientific Fund (grant no. 2014YQ006) provided funding for this research. The authors are grateful to Dr. Natalie Myers for a critical review and comments on earlier drafts of this manuscript.

Author Contributions

Conceived and designed the experiments: CB SW. Performed the experiments: FH YY JM. Analyzed the data: CB FH JM. Contributed reagents/materials/analysis tools: CB. Wrote the paper: CB SW YY.

References

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- Google Scholar
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- View Article
- Google Scholar
30. Coppola A, Basile A, Wang X, Comegna V, Tedeschi A, Mele G, Comegna A (2011) Hydrological behaviour of microbiotic crusts on sand dunes: Example from NW China comparing infiltration in crusted and crust-removed soil. Soil Till Res 117:34–43.
- View Article
- Google Scholar
31. Chamizo S, Cantón Y, Lázaro R, Solé-Benet A, Domingo F (2012) Crust Composition and Disturbance Drive Infiltration Through Biological Soil Crusts in Semiarid Ecosystems. Ecosystems 15:148–161.
- View Article
- Google Scholar
32. Verrecchia E, Yair A, Kidron GJ, Verrecchia K (1995) Physical properties of the psammophile cryptogamic crust and their consequences to the water regime of sandy soils, north-western Negev Desert, Israel. J Arid Environ 29:427–437.
- View Article
- Google Scholar
33. Kidron GJ, Yaalon DH, Vonshak A (1999) Two causes for runoff initiation on microbiotic crusts, hydrophobicity and pore clogging. Soil Sci 164:18–27.
- View Article
- Google Scholar
34. Eldridge DJ (2003) Biological soil crusts and water relations in Australian deserts. In: Belnap J, Lange OL (eds) Biological Soil Crusts, Structure, Function, and Management. Springer-Verlag, Berlin, pp 315–325.
35. Belnap J, Welter JR, Grimm NB, Barger NN, Ludwig JA (2005) Linkages between microbial and hydrologic processes in arid and semi-arid watersheds. Ecology 86:298–307.
- View Article
- Google Scholar
36. Rodríguez-Caballero E, Cantón Y, Chamizo S, Afana A, Solé-Benet A (2012) Effects of biological soil crusts on surface roughness and implications for runoff and erosion. Geomorphology 145–146:81–89.
- View Article
- Google Scholar
37. Dojani S, Büdel B, Deutschewitz K, Weber B (2011). Rapid succession of Biological Soil Crusts after experimental disturbance in the Succulent Karoo, South Africa. Appl Soil Ecol 48:263–269.
- View Article
- Google Scholar
38. O’Bryan KE, Prober SM, Lunt ID, Eldridge DE (2009) Frequent fire promotes diversity and cover of biological soil crusts in a derived temperate grassland. Oecologia 159:827–838. pmid:19132400
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- PubMed/NCBI
- Google Scholar
39. Liu HJ, Han XG, Li LH, Huang JH, Liu HS, Li X (2009) Grazing Density Effects on Cover, Species Composition, and Nitrogen Fixation of Biological Soil Crust in an Inner Mongolia Steppe. Rangeland Ecol Manag 62(4):321–327.
- View Article
- Google Scholar
40. Chamizo S., Cantón Y., Lázaro R., Domingo F (2013) The role of biological soil crusts in soil moisture dynamics in two semiarid ecosystems with contrasting soil textures. J Hydrol 489:74–84.
- View Article
- Google Scholar
41. Chamizo S, Cantón Y., Lázaro R., Sole´-Benet A., Domingo F (2012) Crust composition and disturbance drive infiltration through biological soil crusts in semiarid ecosystems. Ecosystems 15: 148–161.
- View Article
- Google Scholar
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- View Article
- Google Scholar
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- View Article
- Google Scholar
44. Bu CF, Wu SF, Xie YS, Zhang XC (2013) The study of biological soil crusts: hotspots and prospects. CLEAN: Soil Air Water 41:899–906.
- View Article
- Google Scholar

[ref1] 1. Belnap J (2003) The world at your feet: desert biological soil crusts. Front Ecol Environ 1:181–189.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Bowker MA, Fernando TM, Cristina E (2009) BSCs as a model system for examining the biodiversity ecosystem function relationship in soils. Soil Biol Biochem 42:1–13.
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Bu CF, Wu SF, Yang YS, Zheng MG (2014) Identification of Factors Influencing the Restoration of Cyanobacteria-Dominated Biological Soil Crusts. PLoS ONE 9(3): e90049. pmid:24625498
View Article
PubMed/NCBI
Google Scholar

[8] View Article

[9] PubMed/NCBI

[10] Google Scholar

[ref4] 4. Bu CF, Wu SF, Zhang KK, Yang YS (2013) Biological soil crusts: an eco-adaptive biological conservative mechanism and implications for ecological restoration. Plant Biosyst https://doi.org/10.1080/11263504.2013.819820

[ref5] 5. Evans RD, Lange OL (2001) Biological Soil Crusts and ecosystem nitrogen and carbon dynamics. In: Belnap J, Lange OL (eds) Biological Soil Crusts, Structure, function, and management. Berlin, Springer, pp 263–279.

[ref6] 6. Zhao HL, Guo YR, Zhou RL, Sam D (2010) Biological soil crust and surface soil properties in different vegetation types of Horqin Sand Land, China. Catena 82:70–76.
View Article
Google Scholar

[14] View Article

[15] Google Scholar

[ref7] 7. Bowker MA, Belnap J, Chaudhary VB, Nancy CJ (2008) Revisiting classic water erosion models in drylands: The strong impact of biological soil crusts. Soil Biol Biochem 40:2309–2316.
View Article
Google Scholar

[17] View Article

[18] Google Scholar

[ref8] 8. Mazor G, Kidron GJ, Vonshak A, Abeliovich A (1996) The role of cyanobacterial exopolysaccharides in structuring desert microbial crusts. FEMS Microbiol Ecol 21:121–130.
View Article
Google Scholar

[20] View Article

[21] Google Scholar

[ref9] 9. Zhang YM, Wang HL, Wang XQ, Yang WK, Zhang DY (2006) The microstructure of microbiotic crust and its influence on wind erosion for a sandy soil surface in the Gurbantunggut Desert of Northwestern China. Geoderma 132:441–449. pmid:16872984
View Article
PubMed/NCBI
Google Scholar

[23] View Article

[24] PubMed/NCBI

[25] Google Scholar

[ref10] 10. Belnap J (2006) The potential roles of biological soil crusts in dryland hydrologic cycles. Hydrol Process 20: 3159–3178.
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Li XR, Jia XH, Li QL, Stefan Z (2005) Effects of biological soil crusts on seed bank, germination and establishment of two annual plant species in the Tengger Desert (N China). Plant Soil 277:375–385.
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Ma QL, Wang JH, Zhu SJ (2007) Effects of precipitation, soil water content and soil crust on artificial Haloxylon ammodendron forest. Acta Ecol Sin 27:5057–5067 (In Chinese with English abstract).
View Article
Google Scholar

[33] View Article

[34] Google Scholar

[ref13] 13. Carmi G, Berliner P (2008) The effect of soil crust on the generation of runoff on small plots in an arid environment. Catena 74:37–42.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Yuan WP, Li XL, Liang SL, Cui XF, Dong WJ, Liu SG, Xia JZ, Chen Y, Liu D, Zhu WQ (2014) Characterization of locations and extents of afforestation from the Grain for Green Project in China. Remote Sens Lett 5(3):221–229.
View Article
Google Scholar

[39] View Article

[40] Google Scholar

[ref15] 15. Zhao YG, Xu MX, Wang QJ, Shao MA (2006) Physical and chemical properties of biological soil crust on rehabilitation grassland in the hilly Loess Plateau of China. Chin J App Ecol 17:1429–1434 (In Chinese with English abstract).
View Article
Google Scholar

[42] View Article

[43] Google Scholar

[ref16] 16. Meng J, Bu CF, Zhao YJ, Zhang XC (2010) Effects of biological soil crust on soil enzyme activities and nutrients content in wind-water erosion crisscross region, Northern Shaanxi Province, China. J Nat Resour 11:54–64 (In Chinese with English abstract).
View Article
Google Scholar

[45] View Article

[46] Google Scholar

[ref17] 17. Mirallesa I, Domingoa F, Cantónb Y, Trasar-Cepedac C, Carmen Leirósd M, Gil-Sotres F (2012) Hydrolase enzyme activities in a successional gradient of biological soil crusts in arid and semi-arid zones. Soil Biol Biochem 53:124–132.
View Article
Google Scholar

[48] View Article

[49] Google Scholar

[ref18] 18. Xiao B, Wang QH, Zhao YG, Shao MA (2011) Artificial culture of biological soil crusts and its effects on overland flow and infiltration under simulated rainfall. Appl Soil Ecol 48:11–17.
View Article
Google Scholar

[51] View Article

[52] Google Scholar

[ref19] 19. Cheng XR, Huang MB, Shao MA (2007) Vertical distribution of representative plantation’s fine root in Wind-water erosion crisscross region, Shenmu. Acta Bot Boreali-Occidentalia Sin 27:321–327 (In Chinese with English abstract).
View Article
Google Scholar

[54] View Article

[55] Google Scholar

[ref20] 20. Zhang XZ (2002). Study on the soil particle composition and texture division in Loess Plateau. Soil and Water Conservation in China 3:11–13 (In Chinese).
View Article
Google Scholar

[57] View Article

[58] Google Scholar

[ref21] 21. Zhang YX, Zhang GH, Wang ZQ (2009). Influence of Soil Particle Composition on Soil Moisture in Loess Profiles. Bulletin of Soil and Water Conservation 29(6):6–15 (In Chinese with English abstract).
View Article
Google Scholar

[60] View Article

[61] Google Scholar

[ref22] 22. Godíínez-Alvarez H, Moríín C, Rivera-Aguilar V (2012) Germination, survival and growth of three vascular plants on biological soil crusts from a Mexican tropical desert. Plant Biology 14:157–162. pmid:21973053
View Article
PubMed/NCBI
Google Scholar

[63] View Article

[64] PubMed/NCBI

[65] Google Scholar

[ref23] 23. Bu CF, Zhang P, Ye J, Meng J (2014) Spatial characteristics of Moss-dominated soil crust and its impact factors in small watershed in Wind-water Erosion Crisscross region, Northern Shaanxi Province, China. J Nat Resour 29:490–499.
View Article
Google Scholar

[67] View Article

[68] Google Scholar

[ref24] 24. Chamizo S, Cantón Y, Rodríguez-Caballero E, Domingo F, Escudero A (2012) Runoff at contrasting scales in a semiarid ecosystem: A complex balance between biological soil crust features and rainfall characteristics. J Hydrol 452:130–138.
View Article
Google Scholar

[70] View Article

[71] Google Scholar

[ref25] 25. Li XR, Tian F, Jia RL, Zhang ZS, Liu LC (2010) Do biological soil crusts determine vegetation changes in sandy deserts? Implications for managing artificial vegetation. Hydrol Process 24:3621–3630.
View Article
Google Scholar

[73] View Article

[74] Google Scholar

[ref26] 26. Xiao B, Zhao YG, Shao MA (2010) Characteristics and numeric simulation of soil evaporation in biological soil crusts. J Arid Environ 74:121–130.
View Article
Google Scholar

[76] View Article

[77] Google Scholar

[ref27] 27. Zhang KK, Bu CF, Gao GX (2011) The effect of biological soil crust on infiltration of soil water in the Loess Plateau. Arid Zone Res 28:808–812 (In Chinese with English abstract).
View Article
Google Scholar

[79] View Article

[80] Google Scholar

[ref28] 28. Lichner L, Holko L, Zhukova N, Schacht K, Rajkai K, Fodor N, Sandor R (2012) Plants and biological soil crust influence the hydrophysical parameters and water flow in an aeolian sandy soil. J Hydrol Hydromech 60: 309–318.
View Article
Google Scholar

[82] View Article

[83] Google Scholar

[ref29] 29. Wang CP, Liao CY, Sun CZ, Tian XX, Lv JL (2009) Effects of Biological Soil Crusts on Soil Water Storage Capability and Permeability in Loess Area. Agric Res Arid Area 27:54–59 (In Chinese with English abstract).
View Article
Google Scholar

[85] View Article

[86] Google Scholar

[ref30] 30. Coppola A, Basile A, Wang X, Comegna V, Tedeschi A, Mele G, Comegna A (2011) Hydrological behaviour of microbiotic crusts on sand dunes: Example from NW China comparing infiltration in crusted and crust-removed soil. Soil Till Res 117:34–43.
View Article
Google Scholar

[88] View Article

[89] Google Scholar

[ref31] 31. Chamizo S, Cantón Y, Lázaro R, Solé-Benet A, Domingo F (2012) Crust Composition and Disturbance Drive Infiltration Through Biological Soil Crusts in Semiarid Ecosystems. Ecosystems 15:148–161.
View Article
Google Scholar

[91] View Article

[92] Google Scholar

[ref32] 32. Verrecchia E, Yair A, Kidron GJ, Verrecchia K (1995) Physical properties of the psammophile cryptogamic crust and their consequences to the water regime of sandy soils, north-western Negev Desert, Israel. J Arid Environ 29:427–437.
View Article
Google Scholar

[94] View Article

[95] Google Scholar

[ref33] 33. Kidron GJ, Yaalon DH, Vonshak A (1999) Two causes for runoff initiation on microbiotic crusts, hydrophobicity and pore clogging. Soil Sci 164:18–27.
View Article
Google Scholar

[97] View Article

[98] Google Scholar

[ref34] 34. Eldridge DJ (2003) Biological soil crusts and water relations in Australian deserts. In: Belnap J, Lange OL (eds) Biological Soil Crusts, Structure, Function, and Management. Springer-Verlag, Berlin, pp 315–325.

[ref35] 35. Belnap J, Welter JR, Grimm NB, Barger NN, Ludwig JA (2005) Linkages between microbial and hydrologic processes in arid and semi-arid watersheds. Ecology 86:298–307.
View Article
Google Scholar

[101] View Article

[102] Google Scholar

[ref36] 36. Rodríguez-Caballero E, Cantón Y, Chamizo S, Afana A, Solé-Benet A (2012) Effects of biological soil crusts on surface roughness and implications for runoff and erosion. Geomorphology 145–146:81–89.
View Article
Google Scholar

[104] View Article

[105] Google Scholar

[ref37] 37. Dojani S, Büdel B, Deutschewitz K, Weber B (2011). Rapid succession of Biological Soil Crusts after experimental disturbance in the Succulent Karoo, South Africa. Appl Soil Ecol 48:263–269.
View Article
Google Scholar

[107] View Article

[108] Google Scholar

[ref38] 38. O’Bryan KE, Prober SM, Lunt ID, Eldridge DE (2009) Frequent fire promotes diversity and cover of biological soil crusts in a derived temperate grassland. Oecologia 159:827–838. pmid:19132400
View Article
PubMed/NCBI
Google Scholar

[110] View Article

[111] PubMed/NCBI

[112] Google Scholar

[ref39] 39. Liu HJ, Han XG, Li LH, Huang JH, Liu HS, Li X (2009) Grazing Density Effects on Cover, Species Composition, and Nitrogen Fixation of Biological Soil Crust in an Inner Mongolia Steppe. Rangeland Ecol Manag 62(4):321–327.
View Article
Google Scholar

[114] View Article

[115] Google Scholar

[ref40] 40. Chamizo S., Cantón Y., Lázaro R., Domingo F (2013) The role of biological soil crusts in soil moisture dynamics in two semiarid ecosystems with contrasting soil textures. J Hydrol 489:74–84.
View Article
Google Scholar

[117] View Article

[118] Google Scholar

[ref41] 41. Chamizo S, Cantón Y., Lázaro R., Sole´-Benet A., Domingo F (2012) Crust composition and disturbance drive infiltration through biological soil crusts in semiarid ecosystems. Ecosystems 15: 148–161.
View Article
Google Scholar

[120] View Article

[121] Google Scholar

[ref42] 42. Hernandez RR, Sandquist DR (2011). Disturbance of biological soil crust increases emergence of exotic vascular plants in California sage scrub. Plant Ecol 212:1709–1721.
View Article
Google Scholar

[123] View Article

[124] Google Scholar

[ref43] 43. Briggs AL, Morgan JW (2012) Post-cultivation recovery of biological soil crusts in semi-arid native grasslands, southern Australia. J Arid Environ. 77:84–89.
View Article
Google Scholar

[126] View Article

[127] Google Scholar

[ref44] 44. Bu CF, Wu SF, Xie YS, Zhang XC (2013) The study of biological soil crusts: hotspots and prospects. CLEAN: Soil Air Water 41:899–906.
View Article
Google Scholar

[129] View Article

[130] Google Scholar

Figures

Abstract

Introduction

Materials and Methods

Study site

Methods

Experimental design.

Monitoring methods.

Data analysis

Results

Effects of BSCs and vegetation on runoff and infiltration

Effects of BSCs and vegetation on erosion

Effects of BSCs and vegetation on soil moisture

Discussion

The retention and consumption of soil moisture

Implications for disturbance and protection

Conclusions

Supporting Information

S1 Fig. The BSCs pavement processes and a panoramic view of the experimental plots during the second rainy season.

Acknowledgments

Author Contributions

References