Abstract
Farming plot construction engineering in hilly areas plays an important role in the mechanization, large-scale production and industrialization of agriculture. The method is undertaken to improve water and soil conservation, enhance soil fertility and extend machinery agriculture. However, the positive effects of engineering require years to mature. The properties of newly reconstructed soil are not sufficient, i.e., with poor structure and low water holding capacity, resulting in deterioration of its physical properties and erosion. To date, most studies on plot characteristics and soil properties in farming plot construction engineering have neglected the influence of soil erosion. This paper addresses soil erosion characteristics at sites to define the appropriate slope length for newly reconstructed gentle-slope lands. Six field plots with a 10° slope gradient and different lengths (5, 10, 20, 30, 40, and 50 m) were established under natural rainfall and simulated overland flow conditions. The soil detachment rate, runoff shear stress and stream power exhibited the same trends as runoff and soil loss. The soil erosion characteristics varied at sites with different slope lengths, and the degree of soil erosion reached its minimum on gentle-slope land sites of 30 or 40 m. Therefore, 30–40 m slope lengths may be the recommended range to control soil loss from newly reconstructed gentle-slope lands. The conclusions of this study provide theoretical guidance for farming plot construction engineering, which can promote the sustainable development of cultivated land resources in hilly mountainous regions.
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Discover the latest articles, news and stories from top researchers in related subjects.Introduction
Soil erosion is one of the most challenging environmental problems faced by many countries worldwide1. To date, many studies have examined the erosion of stabilized soils; however, the erosion of newly reconstructed soil, which exhibits unstable behavior after farming plot construction, is often ignored2. Farming plot construction is the process of optimizing the reorganization of land resources. The core concept is a change in the physical form of the field, which includes the merging, and leveling of fields and the construction of ridges. As the basis of modern soil engineering, farming plot construction is a man-made disturbance of natural cultivated land that has a great influence on cultivated land and the ecological environment3,4. Sloping farmland is an important farmland resource in hilly mountainous regions in China with intense fragmentation5,6. Farming plot construction engineering was introduced into rural land development to mitigate the impact of natural conditions on plowland fragmentation7. As a soil restoration and reconstruction or soil and water conservation project, farming plot construction not only optimizes soil recovery and reorganizes land resources8 but also enhances soil agglomeration and reduces land fragmentation4. Gentle-slope land refers to farming plots with large areas in which the terrain slope is less than 10° and the land meets the requirements of agricultural mechanization or large-scale land management5. Typically, the shape of the plots after completion of the project is more conducive to mechanized agricultural farming. However, mechanical disturbance results in a variety of changes in soil ecosystem functions, such as soil erodibility and water and soil nutrient cycling9. Changes in these soil properties may alter soil hydrological properties that are closely related to runoff occurrence and sediment transport10,11, thereby making the soil more susceptible to erosion12. Soil erosion, which is caused by the slope length13,14,15, steepness, topsoil condition, rainfall16, particle size distribution, and slope aspect, is one of the main causes of soil nutrient losses and soil fertility decline. Soil erosion is also an important consideration in farming plot construction17,18. Some researchers have reported that farming plot construction may help rehabilitate the ecological environment by decreasing soil erosion, improving the agricultural environment and enhancing the ecological quality19. However, three phases should be considered when evaluating the effect of farming plot construction on soil erosion: the construction, recovery and balance periods4. Improvement of soil erosion through engineering is increasingly obvious during the balance period8. Engineering transformation measures conducted during the construction period will destroy the original soil structure of the fields. Importantly, the organic matter content of the newly reconstructed soil is low during the recovery period, and a large amount of gravel or stone is found in the soils. Soil drought is severe due to the low soil water preservation capability and the high soil water evaporation rate, which can weaken the ability of the soil to resist erosion; thus, soil erosion occurs easily20. Therefore, erosion of newly reconstructed soil during the recovery period exhibits unstable behavior after farming plot construction that cannot be ignored.
The existing literature on the effects of farming plot construction mainly focuses on four aspects: (1) these projects weaken the diversity of agricultural landscapes21,22; (2) these projects may cause a series of adverse ecological environmental impacts, while increasing the effective cultivated land area and improving the soil quality18,23; (3) the system evaluates farmland consolidation in different regions as well as, the economic, social and ecological benefits of the project24; and (4) the spatial variation in soil nutrients and the characteristics of soil quality evolution are evaluated in farming plot construction projects on a microcosmic scale. In addition, relatively few studies have investigated the relationship between soil erosion and gentle-slope lands after farming plot construction2.
Under natural rainfall and simulated overland flow conditions, this study uses newly reconstructed soils on gentle-slope lands after farming plot construction as the research objects and investigates the runoff and sediment generation processes of six plots with different gentle-slope land values (5, 10, 20, 30, 40 and 50 m). The objectives of the study were to (1) define the seriousness of soil erosion on gentle-slope lands after farming plot construction, (2) determine the appropriate slope length to control soil loss from newly reconstructed soil and (3) provide theoretical guidance for the control and monitoring of gentle-slope lands erosion after farming plot construction in hilly mountainous region.
Results
Erosive precipitation events
After monitoring the farming plots during the rainy season, six erosive precipitation events were recorded by rain gauges. The characteristics of these erosive precipitation events included the rainfall capacity, duration, intensity and hourly maximum rainfall intensity. The results are shown in Table 1.
The soil loss and runoff characteristics for sites with different slope lengths (5, 10, 20, 30, 40 and 50 m) along the gentle-slope lands under erosive precipitation events with diverse rainfall capacities are shown in Fig. 1. The ANOVA and T-test showed that the slope length had a significant effect on runoff and soil loss (p < 0.01). When the rainfall capacity and average intensity were both low, the amounts of soil loss and runoff were correspondingly reduced. Although the rainfall capacity of 32.8 mm shown in Fig. 1f was small, the soil loss and runoff were high due to the larger average rainfall intensity. Fig. 1 also showed that the change trends of soil loss and runoff with slope length were similar, with an initial increase, a subsequent decrease, and a final increase. Certain differences in soil loss and runoff were observed for the different gentle-slope land sites. Among them, the soil loss and runoff due to rainfall events shown in Fig. 1a–c,e,f reached their minimum values on the 30 m gentle-slope land site, whereas the results shown in Fig. 1d reached their maximum values at the 40 m site. In these six rainfall events, the 20 m gentle-slope land site had increased soil loss and runoff; these measures reached a minimum at 30 or 40 m, and an increasing trend was observed at 50 m.
Simulated overland flow
The amounts of soil loss and runoff at the sites with different slope lengths (5, 10, 20, 30, 40 and 50 m) along the gentle-slope lands under simulated overland flow with diverse upslope inflow rates are shown in Fig. 2. The ANOVA and T-test showed that the slope length had a significant effect on runoff and soil loss (p < 0.01). When the upslope inflow rate was 30 L min−1, the soil loss and runoff were largest at the 5 m gentle-slope land site. As the runoff flowed along the slope, it began to erode the soil and carry sediments; thus, the runoff required more energy to transport sediments on the slope. The energy required to erode the soil decreased to the minimum value at the 40 m gentle-slope land site (Fig. 2a). Under an upslope inflow rate of 15 L min−1, the soil loss and runoff initially increased and then decreased and finally increased. Both soil loss and runoff reached their maximum values at 10 m and then decreased to the 30 m gentle-slope land site; an increasing trend was noted at 30 m (Fig. 2b). Soil loss and runoff decreased with the decreasing upslope inflow rate, and no runoff and sediments were observed in 40 and 50 m gentle-slope land sites when the upslope inflow rate was 5 L min−1 (Fig. 2c). The trend of soil loss and runoff increased first and then decreased at the 10 m gentle-slope land site and reached a minimum at the 30 m gentle-slope land site (Fig. 2c).
To further account for the change tendency of soil loss and runoff at the different gentle-slope land sites, the soil detachment rate, runoff shear stress and runoff power were analyzed, as shown in Figs 3 and 4. The soil detachment rate was defined as the soil weight denuded per unit area and time25,26. The ANOVA and T-test showed that the slope length had a significant effect on the soil detachment rate, runoff shear stress and runoff power (p < 0.01) under different upslope inflow rates. When the upslope inflow rate was 30 L min−1, the runoff shear stress of the upslope inflow was too high (Fig. 4a) to produce a large soil detachment rate (Fig. 3a), which caused the occurrence and development of rapid scouring. However, the runoff sediment content was close to the sediment transport capacity of the flow as scouring persisted, causing the runoff shear stress and soil detachment to decrease. Although the soil detachment rate increased with the increasing slope length, there was little room for growth of the sediment transport capacity of the flow; thus, soil detachment presented a smaller change tendency. The soil detachment rate, runoff shear stress and runoff power of 15 and 5 L min−1 decreased gradually (Figs 3b,c and 4b,c).
The flow velocities at the sites with different slope lengths with diverse upslope inflow rates are shown in Fig. 5a. The flow velocity decreased and then increased with the increasing slope length, with a range from 0.10 to 0.22 m s−1. The fluctuation trend showed a change from strength to weakness with the increase in the slope length, and the amplitude of the velocity variation on slopes larger than 30 m was significantly weakened. Partial factor correlation analysis of the relationship between the upslope inflow rate, slope length and flow rate showed that the flow rate was significantly correlated with the upslope inflow rate (r = 0.592, p < 0.05) and slope length (r = −0.601, p < 0.05). This result showed that the slope length had a greater effect on the flow velocity of the slope than on the upslope inflow rate. The change trend of the drag coefficient shown in Fig. 5b ranged from 0.02 to 1.41. The f decreased significantly with the slope length with a slight upward trend at 30 m.
As shown in Table 2, soil loss was selected as the reference series and the parameters were selected as the comparison series. The relevancy between soil loss and correlation parameters was analyzed using the gray correlation method27. Each parameter had a correlation with the soil loss for newly reconstructed soil. The correlation order of the parameters to soil loss was ζV > ζQ > ζP > ζD > ζS > ζL > ζR > ζSS, and the range was 0.340–0.923. Specifically, the flow velocity had the largest influence on soil loss.
Discussion
In hilly or mountainous regions of China, terracing is an important technique in land consolidation projects, and level terrace construction is preferred. However, constructing large horizontal terraced fields in the mountainous area of Chongqing is difficult. Therefore, gentle-slope lands are the most common type of cultivated field in the region. Land consolidation of farming plot construction engineering in hilly mountainous regions plays an important role in the mechanization, large-scale production and industrialization of agriculture. This approach also improves water and soil conservation, enhances soil fertility and expands areas that are accessible to agricultural machinery5. However, the positive effect of construction engineering requires years. The soil properties of reconstructed soil after farm plot construction with a loose structure and poor water holding capacity result in deterioration of its physical properties and cause soil erosion20,28. Soil erosion can cause loss of soil nutrients and a decline in soil fertility, which should receive adequate attention during terrace construction17. Liu et al.8 showed that soil erosion increased significantly at steep-sloped sites without protective measures during rainstorm events after land consolidation. The results of this study revealed that the farming plots of gentle-slope lands would be eroded after precipitation events or simulated overland flow. However, the degree of soil loss is also affected by the slope length, rainfall intensity and upslope inflow rate. Under natural conditions, the rainfall intensity cannot be controlled. Protective measures can be taken after construction, but such measures are expensive. The results of this study show that different degrees of soil erosion are produced by different slope lengths.
Slope length is one crucial factor affecting soil erosion15,29, and its influence is complex. Extensive research has been conducted on the relationship between slope length and runoff and sediment11. According to previous studies, there are three main viewpoints on the impact of slope length on soil erosion, (1) Soil erosion decreases with an increasing slope length30,31. (2) Erosion increases from uphill to downhill with the slope length32. (3) Soil erosion is a dynamic process with an increasing slope length33. On one hand, soil erosion is enhanced because the downhill water yield is greater than the uphill yield. On the other hand, energy is consumed to weaken erosion34. Therefore, these factories restrict each other. Kinnell14 showed that the effect of slope length on sediment discharge was highly dependent on variations in the runoff response resulting from variations in the rainfall duration-intensity-infiltration conditions rather than the plot length per se. The change in soil loss of newly reconstructed soil with different slope lengths in this study was complicated by “runoff degradation” during the unsteady period. Under natural rainfall and simulated overland flow conditions, providing continuous runoff is more difficult for a longer plot35. Therefore, the longer slope would reduce the loss of runoff downslope, resulting in more reinfiltration36,37. The “runoff degradation” phenomenon was observed on the 30 and 40 m slopes, which was similar to research showing that the runoff rate decreased with an increasing slope length38. One possible explanation is that a slope length of 30 or 40 m is the runoff continuity threshold. The catchment area of the slope was enlarged, the runoff pooling path was increased, the runoff was discontinuous and the infiltration intensity was enhanced, which led to a decrease in runoff. The gully cliff on both sides formed by water flow collapsed; thus, the water flow was blocked, resulting in an increase in the infiltration capacity and a decrease in runoff. The effects of slope length and the upslope inflow rate on the runoff rates were mainly due to the spatial variability of the downslope soil infiltration39 and reinfiltration40. At the same time, the soil loss characteristics varied among sites with different slope lengths; the degree of soil loss reached the minimum values on 30 or 40 m gentle-slope land sites under natural rainfall and simulated overland flow conditions. This phenomenon occurred because the sediment was constantly removed with the water flow with increasing slope length. Thus, the runoff required more energy to transport sediments on the slope35, and the energy used to entrain and disperse soil particles gradually weakened. With further extension of the slope length, the runoff energy was insufficient to transport more sediment when the sediment yield rate reached its maximum value. Because sediment began to deposit, the energy used to denude the soil increased and caused more erosion. In this way, the fluctuation of runoff and soil loss along the slope length indicated that soil erosion was a complex process of entrainment, transportation and deposition, and that these processes alternate and repeat. The entrainment of sediment particles was primarily dependent on the runoff shear stress under the water erosion cnditions33. The ability of water erosion to disperse soil particles increased with the increase in the upslope inflow, leading to an increase in the sediment concentration41. Meanwhile, the increase upslope inflow increased the runoff depth, causing the runoff shear stress and soil detachment rates to increase correspondingly42. The soil detachment rate decreased when the critical sediment discharge was reached43.
To promote large-scale development of agricultural mechanization, the length of the sloping terrace should be as long as possible. However, the cost of land consolidation and the degree of erosion should also be considered. The length should be within an appropriate range to optimize the conditions. The results of this study under erosive precipitation events or runoff scouring showed that the degree of soil erosion was lowest when the slope length was 30 or 40 m. Thus, 30–40 m may be the appropriate slope length range to control the loss of newly reconstructed soil from gentle-slope lands.
Materials and Methods
Study area
The study area was located in the National Purple Soil Monitoring Base of Southwest University, Beibei, Chongqing (106°26′E, 30°26′N) at an altitude of 230 m (Fig. 6). The area has a subtropical, humid climate with a mean annual temperature of 18.3 °C The average annual precipitation is 1105 mm, with 70% occurring between May and September. The average annual amount of sunshine is 1277 h, and the mean annual frost-free period is 334 d. The test soils, which are classified as Regosols in FAO Taxonomy or Entisols in USDA Taxonomy44, are formed from purple rocks and weathering products and mainly are distributed in the Sichuan Basin of southwestern China.
Farming plot construction engineering
First, the original 20-cm-thick topsoil was removed and deposited nearby. After engineering, the soil was reclaimed as topsoil for the farming plots. Then, the total soil thickness in the constructed plots was determined to be 50 cm. Finally, the deep excavation, refilling, land-reshaping, and leveling engineering measures were implemented. A schematic diagram of farming plot construction is shown in Fig. 7A.
To meet the requirements of mechanized farming, soil and water conservation, and cost effectiveness of rebuilding farmland, this study used a 10° slope gradient as a benchmark. A field plot with a slope gradient of 20°in the study area was selected and reduced to 10° by engineering. To clarify the effects of the slope lengths of the different sites on soil erosion and reduce the impact of sampling along the path, the experiment established six field plots with different slope lengths of 5, 10, 20, 30, 40 and 50 m, a field width of 2 m and a depth of 0.6 m. The bottom of the plot was the natural soil parent material separated by a cement ridge with a 0.2 m width. The cement ridge was built on the parent material layer, and a PVC sump was arranged at the end of the plot to collect runoff. Before the experiment, the topsoil (approximately 15 cm) was loosened, and the surface was raked to simulate general farming tillage. No fertilizer was applied to the experimental plots, and no crops were planted. The experimental field plots are shown before and after farming plot construction engineering in Fig. 8. The test soil was analyzed after engineering; the results are presented in Table 3.
Experimental design and methods
In addition to rainfall data from the rainy seasons, the simulated overland flow experiment was used to evaluate the soil loss process and the characteristics of the newly reconstructed soil on gentle-slope lands. The specific methods are described below.
Natural rainfall
The rain gauge was set in an experimental plot and recorded precipitation after rainfall. Related data for each rainfall from the weather station of Beibei district were used as a reference. The linear distance of the experimental field from the weather station was 4.8 km. The runoff was quantitated in a runoff pond after rainfall, and the sediment was measured after runoff precipitation.
Simulated overland flow
According to observation data concerning the local runoff and terrain conditions, the maximum runoff values used to determine the upslope inflow rates were 5, 15 and 30 L min−1; the rain intensity per unit area was 0.05–3 mm min−1. An overflow groove was placed at the upper end of the experimental plot, and the bottom of the overflow groove was covered with a few layers of gauze to prevent excessive erosion. The water storage barrel supplied water, and the overflow groove was located on top of the experiment plot horizontally to cause overland flow and maintain well-distributed sheet flow condition. A tap was equipped at the top of the overflow chute to regulate the flow discharge (Fig. 7B). Meanwhile, a voltage regulation pump and a flow meter were used to provide stable flow discharge with the error controlled to within 5%. To avoid the effects of surface roughness and the initial soil moisture content on the test results, the test plots were raked and shelved for approximately one week before initiation of each experiment. Before the experiment, the test soil was placed 12 h after saturation, and the physical properties of each plot, such as the soil bulk density, initial water content and mechanical composition, were measured on the upper, middle and lower sections of the slope surface. To collect surface runoff after runoff generation, approximately 550 mL of runoff and sediment was collected at 1 min in the first 10 min and then collected at 3 min after the first 10 min. The flow velocity of the slope surface was measured according to the potassium permanganate staining method45 when the runoff was stable, and the average value was determined several times. Because the velocity of the runoff measured using the potassium permanganate staining method was the dominant flow velocity of the slope, the measured velocity was multiplied by the correction factor 0.75 as the average velocity of the cross section of the water flow46. The experimental time period was during September-October, 2017.
Equations and data treatment
The soil detachment rate (Dr, g min−1 m2) was calculated with the following equation:
where M is the mass of sediment collected during the observation time T(g), B is the width of the water-crossing section (m) B = 2 m, L is the slope length (m); and T is the observation time (min).
Runoff shear stress (τ, Pa) was calculated by the following equation:
where ρ is the water density (kg m−3), g is the gravitational acceleration (m s−2), J (m/m) is the sine value of the slope gradient sin 10° = 0.174 and R is the hydraulic radius, which was considered equal to the mean flow depth (H) under the overland flow condition (m), H can be estimated by
where R0 is the runoff during the observation time T (m3), and V is the mean calculated flow velocity (m s−1).
Runoff power (P, N m−1 s−1) was calculated by the following equation:
The Darcy-Weisbach drag coefficient (f) was calculated by the following equation:
Conclusions
Based on natural rainfall and simulated overland flow, this study investigated the soil erosion characteristics of newly reconstructed gentle-slope lands with different slope lengths (5, 10, 20, 30, 40 and 50 m). The results indicated that the degree of soil erosion under erosive precipitation events or simulated overland flow was lowest for a slope length of 30 or 40 m. The runoff sediment content was close to the sediment transport capacity of the flow as scouring persisted, causing the runoff shear stress and soil detachment to decrease. The soil detachment rate, runoff shear stress and runoff power exhibited the same trends as the soil and runoff loss. Thus, 30–40 m appears to be the appropriate slope length range to control soil loss from newly reconstructed soil. The results and recommendations reported herein will have value for newly reconstructed soil in farming plot construction engineering in hilly mountainous regions. In the future, the sediment sorting and transport mechanism and the mobilization of nutrients from newly reconstructed soil deserve further in-depth study.
Data Availability
The original data can be obtained from the authors upon reasonable request.
References
Ran, L. S., Lu, X. X., Fang, N. F. & Yang, X. K. Effective soil erosion control represents a significant net carbon sequestration. Scientific Reports 8, 12018–12018, https://doi.org/10.1038/s41598-018-30497-4 (2018).
Gardner, R. A. M. & Gerrard, A. J. Runoff and soil erosion on cultivated rainfed terraces in the Middle Hills of Nepal. Applied Geography 23, 23–45, https://doi.org/10.1016/s0143-6228(02)00069-3 (2003).
Li, X. H., Yang, J., Zhao, C. Y. & Wang, B. Runoff and sediment from orchard terraces in Southeastern China. Land Degradation &. Development 25, 184–192, https://doi.org/10.1002/ldr.1160 (2014).
Yu, G. M. et al. The identification and assessment of ecological risks for land consolidation based on the anticipation of ecosystem stabilization: A case study in Hubei Province, China. Land Use Policy 27, 293–303, https://doi.org/10.1016/j.landusepol.2009.03.004 (2010).
Zhong, S. Q., Liu, J., Liu, W. P. & Wei, C. F. Engineering design parameters of farming plots construction and plot characteristics in hilly area: a case study of Chongiqng. Scientia Agricultura Sinica 50, 4558–4574 (2017).
Zuo, F. L., Zhong, S. Q., Ran, Z. L. & Wei, C. F. Characteristics of sediment and hydrodynamic parameters of new reconstructed slope soil in the hill area with purple soils. Journal of Soil and Water Conservation 32, 59–66 (2018).
Niroula, G. S. & Thapa, G. B. Impacts and causes of land fragmentation, and lessons learned from land consolidation in South Asia. Land Use Policy 22, 358–372, https://doi.org/10.1016/j.landusepol.2004.10.001 (2005).
Liu, S. L. et al. Effects of different terrace protection measures in a sloping land consolidation project targeting soil erosion at the slope scale. Ecological Engineering 53, 46–53, https://doi.org/10.1016/j.ecoleng.2012.12.001 (2013).
Lal, R. Tillage effects on soil degradation, soil resilience, soil quality, and sustainability-introduction. Soil Tillage Res. 27, 1–8, https://doi.org/10.1016/0167-1987(93)90059-x (1993).
Wang, Y. Q. & Shao, M. A. Spatial variability of soil physical properties in a region of the loess plateau of pr china subject to wind and water erosion. Land Degradation & Development 24, 296–304, https://doi.org/10.1002/ldr.1128 (2013).
Leh, M., Bajwa, S. & Chaubey, I. Impact of land use change on erosion risk: an integrated remote sensing, geographic information system and modeling methodology. Land Degradation & Development 24, 409–421, https://doi.org/10.1002/ldr.1137 (2013).
Zhang, X. C. & Wang, Z. L. Interrill soil erosion processes on steep slopes. J. Hydrol. 548, 652–664, https://doi.org/10.1016/j.jhydrol.2017.03.046 (2017).
Fu, X. T., Zhang, L. P. & Wang, X. Y. The Effect of Slope Length on Sediment Yield by Rainfall Impact under Different Land Use Types. Water Resources 43, 478–485, https://doi.org/10.1134/s0097807816030052 (2016).
Kinnell, P. I. A. The impact of slope length on the discharge of sediment by rain impact induced saltation and suspension. Earth Surface Processes and Landforms 34, 1393–1407, https://doi.org/10.1002/esp.1828 (2009).
Liu, B. Y., Nearing, M. A., Shi, P. J. & Jia, Z. W. Slope length effects on soil loss for steep slopes. Soil Science Society of America Journal 64, 1759–1763, https://doi.org/10.2136/sssaj2000.6451759x (2000).
Fox, D. M. & Bryan, R. B. The relationship of soil loss by interrill erosion to slope gradient. Catena 38, 211–222, https://doi.org/10.1016/s0341-8162(99)00072-7 (2000).
Shen, Z. Y., Gong, Y. W., Li, Y. H. & Liu, R. M. Analysis and modeling of soil conservation measures in the Three Gorges Reservoir Area in China. Catena 81, 104–112, https://doi.org/10.1016/j.catena.2010.01.009 (2010).
Bronstert, A., Volimer, S. & Ihringer, J. A review of the impact of land consolidation on runoff production and flooding in Germany. Physics and Chemistry of the Earth 20, 321–329 (1995).
Zhao, G., Jia, W. & Liu, X. Construction of ecological engineering of farmland landscape for land consolidation. Transactions of the CSAE 23, 114–119 (2007).
Wei, C. F. et al. Study on the fertility characteristics of soils in immigration’s reclamation area of ErTan hydropower station. Acta Pedologica Sinica 27, 536–544 (2000).
Bonfanti, P., Fregonese, A. & Sigura, M. Landscape analysis in areas affected by land consolidation. Landscape and Urban Planning 37, 91–98, https://doi.org/10.1016/s0169-2046(96)00373-8 (1997).
Evrard, O. et al. Modelling the impact of land use change and rainfall seasonality on sediment export from an agricultural catchment of the northwestern European loess belt. Agriculture Ecosystems & Environment 138, 83–94, https://doi.org/10.1016/j.agee.2010.04.003 (2010).
Fukamachi, K., Oku, H. & Miyake, A. The relationships between the structure of paddy levees and the plant species diversity in cultural landscapes on the west side of Lake Biwa, Shiga, Japan. Landscape Ecology 1, 191–199, https://doi.org/10.1007/s11355-005-0019-8 (2005).
Crecente, R., Alvarez, C. & Fra, U. Economic, social and environmental impact of land consolidation in Galicia. Land Use Policy 19, 135–147, https://doi.org/10.1016/s0264-8377(02)00006-6 (2002).
Cochrane, T. A. & Flanagan, D. C. Detachment in a simulated rill. Trans. ASAE 40, 111–119 (1997).
Lei, T. W., Nearing, M. A., Haghighi, K. & Bralts, V. F. Rill erosion and morphological evolution: A simulation model. Water Resources Research 34, 3157–3168, https://doi.org/10.1029/98wr02162 (1998).
Zhang, L., Ren, L. Q., Tong, J. & Shi, Y. W. Study of soil-solid adhesion by grey system theory. Progress in natural science-materials international 14, 119–124, https://doi.org/10.1080/10020070412331343241 (2004).
Wei, C. F., Xie, D. T. & Yang, J. H. Evolution of soil fertility of new reconstructed soil in purple hilly slope land. Mountain Developing 5, 61–66 (1994).
Wilkinson, M. T. & Humphreys, G. S. Slope aspect, slope length and slope inclination controls of shallow soils vegetated by sclerophyllous heath - links to long-term landscape evolution. Geomorphology 76, 347–362, https://doi.org/10.1016/j.geomorph.2005.11.011 (2006).
Giesen, N. V. D., Stomph, T. J. & Ridder, N. D. Surface runoff scale effects in West African watersheds: modeling and management options. Agricultural Water Management 72, 109–130, https://doi.org/10.1016/j.agwat.2004.09.007 (2005).
Stomph, T. J., Ridder, N. D., Steenhuis., T. S. & Giesen, N. V. D. Scale effects of Hortonian overland flow and rainfall-runoff dynamics: laboratory validation of a process-based model. Earth Surface Processes & Landforms 27, 847–855, https://doi.org/10.1002/esp.356 (2002).
Kara, O., Sensoy, H. & Bolat, I. Slope length effects on microbial biomass and activity of eroded sediments. Journal of Soils and Sediments 10, 434–439, https://doi.org/10.1007/s11368-010-0192-8 (2010).
Nearing, M. A., Foster, G. R., Lane, L. J. & Finkner, S. C. A Process-Based Soil-Erosion Model for Usda-Water Erosion Prediction Project Technology. Trans. ASAE 32, 1587–1593 (1989).
Huang, Y. et al. Velocity of water flow along saturated loess slopes under erosion effects. J. Hydrol. 561, 304–311, https://doi.org/10.1016/j.jhydrol.2018.03.070 (2018).
Sadeghi, S. H. R., Seghaleh, M. B. & Rangavar, A. S. Plot sizes dependency of runoff and sediment yield estimates from a small watershed. Catena 102, 55–61, https://doi.org/10.1016/j.catena.2011.01.003 (2013).
Chaplot, V. & Le Bissonnais, Y. Field measurements of interrill erosion under different slopes and plot sizes. Earth Surface Processes and Landforms 25, 145–153, 10.1002/(sici)1096-9837(200002)25:2<145::Aid-esp51>3.3.Co;2-v (2000).
Leys, A., Govers, G., Gillijns, K., Berckmoes, E. & Takken, I. Scale effects on runoff and erosion losses from arable land under conservation and conventional tillage: The role of residue cover. J. Hydrol. 390, 143–154, https://doi.org/10.1016/j.jhydrol.2010.06.034 (2010).
Liu, J. Soil engineering effects of farming plots reconstruction in hilly-mountainous region of ChongQing. PhD thesis, Southwest University (2015).
Boix-Fayos, C. et al. Causes and underlying processes of measurement variability in field erosion plots in Mediterranean conditions. Earth Surface Processes and Landforms 32, 85–101, https://doi.org/10.1002/esp.1382 (2007).
Norton, J. B., Sandor, J. A. & White, C. S. Runoff and sediments from hillslope soils within a native American agroecosystem. Soil Science Society of America Journal 71, 476–483, https://doi.org/10.2136/sssaj2006.0019 (2007).
Fu, X. T. Research on slope length effect on runoff and sediment yield and dynamics processes. PhD thesis, Zhejiang University (2012).
Leonard, J. & Richard, G. Estimation of runoff critical shear stress for soil erosion from soil shear strength. Catena 57, 233–249, https://doi.org/10.1016/j.catena.2003.11.007 (2004).
Foster, G. R. & Meyer, L. D. Transport of soil particles by shallow flow. Trans. ASAE 15, 99-& (1972).
He, Y. R. Purple soils in China (2). Science Press (2003).
Han, Z., Wang, X. Y. & Li, X. X. Effects of rock fragment cover on hydrological processes in purple soils. Mountain Research 35, 451–458 (2017).
Abrahams, A. D., Parsons, A. J. & Luk, S. H. Resistance to overland flow on desert hill slopes. J. Hydrol. 88, 343–363 (1986).
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This work was supported by the National Key Research and Development Program of China (2017YFD0800505) and the Foundation of Graduate Research and Innovation in Chongqing under Project CYB18089.
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Zhen Han conceived and designed the experiments, performed the experiments, analyzed the data, contributed reagents/materials/analysis tools, wrote the paper and prepared figures and/or tables. Shouqin Zhong performed the experiments, contributed reagents/materials/analysis tools and prepared Figure 8. Jiupai Ni performed the experiments and reviewed drafts of the paper. Zhonglin Shi contributed reagents/materials/analysis tools. Chaofu Wei conceived and designed the experiments, performed the experiments and reviewed drafts of the paper.
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Han, Z., Zhong, S., Ni, J. et al. Estimation of Soil Erosion to Define the Slope Length of Newly Reconstructed Gentle-Slope Lands in Hilly Mountainous Regions. Sci Rep 9, 4676 (2019). https://doi.org/10.1038/s41598-019-41405-9
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DOI: https://doi.org/10.1038/s41598-019-41405-9
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