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| Quantitative studies on root reinforcement resisting flow-induced erosion in the sandy loess region |
| LI Qiang1,2, LIU Guobin2,3, ZHANG Zheng3, MA Chunyan1,2, BAI Yun1,2, ZHANG Chenchen1,2 |
1. Yulin University, 719000, Yulin, Shaanxi, China;
2. Shaanxi Key Laboratory of Ecological Restoration in Shaanbei Mining Area, 719000, Yulin, Shaanxi, China;
3. State Key Laboratory of Soil Erosion and Dry-land Farming on the Loess Plateau, Institute of Soil and Water Conservation, Northwest A & F University, 712100, Yangling, Shaanxi, China |
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Abstract [Background] In semi-arid areas, soil erosion is a serious threat to land productivity and sustainability for natural and human-managed ecosystems. Traditional vegetation techniques are recognized as effectively in reducing soil erosion, whereas the most evident vegetation source that protects soil against erosion is root wedging, which is an important mechanism where roots can bind soil together and tie weak surface soil layers into strong and stable subsurface layers. Plant roots significantly affect soil erosion process of overland flow by physical consolidation (root link and root-soil adhesive) and biological chemistry functions. The purpose of this study was to evaluate the relative contributions of root link, root-soil adhesive as well as root biological chemistry functions to soil reinforcement. Such study could provide the theoretical explanation for root reinforcement resisting erosion in the flow-induced erosion regions. [Methods] For this purpose, a simulated scouring experiment was conducted on a sandy soil with sand content 36.8%, silt content 51.2% and clay content 12.0%. Three treatments considered were:1) fallow (CK), 2) root-penetrated soil and 3) simulated-root-penetrated soil. Each treatment had four replicates. Rectangular, undisturbed soil samples (20 cm×10 cm×10 cm) were taken in the fallow and root pans and were conducted with a hydrological flume (2 m×0.10 m). The flume contained an opening at its lower base, equaling the size of metal sampling box, so that the soil surface of soil sample was at the same level of the flume surface. Space between the sample box and the flume edges was sealed with painter's mastic to prevent edge effects. The slope of the flume bottom could be varied and clear tap water flow was applied at 4.0 L/min rate discharge on a washing flume slope of 15° for 15 min. During the 15 minutes of each experiment, samples of runoff and detached soil were collected every 1 min in the first 3 min and 2 min in the following time using 10 L buckets for determining sedimentation. Therefore, this paper analyzed the relative role in creating the soil configuration of soil resistance to erosion quantitatively, using no root-penetrated soil, root-penetrated soil erosion simulation test. [Results] The results showed that the physical consolidation effect was the key role in soil erosion resistance, accounting for 70.9% in the total root effect. Compared with alfalfa density of 90 plants/m2, physical consolidation effect in the treatment of 360 plants/m2 increased by 6.8%. In addition, the root string function was the key manner in a proportion of 78.2% in the physical consolidation effect. Exponential function well expressed the relationship between root physical consolidation effect and root surface area density (P<0.01). [Conclusions] Physical consolidation effect is the key role in soil erosion resistance, and root surface area density can reflect the root soil consolidation effect.
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Received: 24 November 2016
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| [1] |
朱显谟. 黄土高原地区植被因素对于水土流失的影响[J]. 土壤学报, 1960, 8(2):110. ZHU Xianmo. Effect of vegetation factor on soil and water loss in the Loess Plateau[J]. Acta Pedologica Sinica, 1960, 8(2):110.
|
| [2] |
GYSSELS G, Poesen J. The importance of plant root characteristics in controlling concentrated flow erosion rates[J]. Earth Surface Processes and Landforms, 2003, 28(4):371.
|
| [3] |
ZHOU Zhengchao, SHANGGUAN Zhouping. Effects of grazing on soil physical properties and soil erodibility in semiarid grassland of the northern Loess Plateau[J]. Catena, 2010, 82(2):87.
|
| [4] |
李勇, 朱显谟, 田积莹. 黄土高原植物根系提高土壤抗冲性的有效性[J]. 科学通报, 1991, 36(12):935. LI Yong, ZHU Xianmo, TIAN Jiying. The effectiveness of root reinforcement to flow-induced soil erosion on the Loess Plateau[J]. Chinese Science Bulletin, 1991, 36(12):935.
|
| [5] |
刘国彬. 黄土高原草地土壤抗冲性及其机理研究[J]. 水土保持学报, 1998, 12(1):93. LIU Guobin. Study on soil anti-scourability and its mechanism[J]. Journal of Soil and Water Conservation, 1998, 12(1):93.
|
| [6] |
De BAETS S, POESEN J, KNAPEN A, et al. Impact of root architecture on the erosion-reducing potential of roots during concentrated flow[J]. Earth Surface Process and Landforms, 2007, 32(9):1323.
|
| [7] |
TUO Dengfeng, XU Mingxiang, GAO Liqian. Changed surface roughness by wind erosion accelerates water erosion[J]. Jouranl of Soils and Sediments, 2016,16:105.
|
| [8] |
YU Bofu, ZHANG Guanghui, FU Xudong. Transport capacity of overland flow with high sediment concentration[J]. Journal of Hydrology Engineer, 2015, 20(6):C4014001.
|
| [9] |
ZHANG Chao, LIU Guobin, XUE Sha. Rhizosphere soil microbial properties on abandoned croplands in the Loess Plateau, China during vegetation succession[J]. European Journal of Soil Biology, 2012, 50:127.
|
| [10] |
ZUAZO V D, PLEGUEZUELO C R R. Soil-erosion and runoff prevention by plant covers:A review[J]. Agronmy for Sustainable Development, 2008, 28(1):65.
|
| [11] |
吴林坤, 林向民, 林文雄. 根系分泌物介导下植物-土壤-微生物互作关系研究进展与展望[J]. 植物生态学报2014, 38(3):298. WU Linkun, LIN Xiangmin, LIN Wenxiong. Advances and perspective in research on plant-soil-microbe interactions mediated by root exudates[J]. Chinese Journal of Plant Ecology, 2014, 38(3):298.
|
| [12] |
刘国彬.黄土高原草地土壤抗冲性及其机理研究[D]. 陕西杨凌:中国科学院水利部水土保持研究所, 1996:15. LIU Guobin. Research on soil resistance to erosion and its mechanism in the meadow on the Loess Plateau[D]. Yangling:Institute of Soil and Water Conservation, Chinese Academy of Sciences and Ministry of Water Resources. 1996:15.
|
| [13] |
ZHOU Zhengchao, SHANGGUAN Zhouping. The effects of ryegrass roots and shoots on loess erosion under simulated rainfall[J]. Catena, 2007, 70(3):350.
|
| [14] |
鄂竟平. 中国水土流失与生态安全综合科学考察总结报告[J]. 中国水土保持, 2008, 12:3. E Jingping. A summary report on soil and water loss, and ecological safety[J]. Soil and Water Conservation, China, 2008, 12:3.
|
| [15] |
李建兴, 何丙辉, 谌芸, 等. 不同护坡草本植物的根系分布特征及其对土壤抗剪强度的影响[J]. 2013, 29(10):144. LI Jianxing, HE Binghui, CHEN Yun, et al. Root distribution features of typical herb plants for slope protection and their effects on soil shear strength[J]. Transactions of the Chinese Society of Agricultural Engineering, 2013, 29(10):144.
|
| [16] |
温维亮, 郭新宇, 赵春江, 等. 作物根系构型三维探测与重建方法研究进展[J]. 中国农业科学, 2015, 48(3):436. WEN Weiliang, GUO Xinyu, ZHAO Chunjiang, et al. Crop roots configuration and visualization:a review[J]. Scientia Agricultura Sinica, 2015, 48(3):436.
|
| [17] |
LOADES K W, BENGOUGH A G, BRANSBY M F, et al. Effect of root age on the biomechanics of seminal and nodal roots of barley (Hordeum vulgare L.) in contrasting soil environments. Plant Soil, 2015, 395:253.
|
| [18] |
LI Qiang, LIU Guobin, ZHANG Zheng, et al. Relative contribution of root physical enlacing and biochemistrical exudates to soil erosion resistance in the Loess soil. Catena, 2017, 153:61.
|
| [19] |
BU Chongfeng, HAN Fengpeng. The combined effects of moss-dominated biocrusts and vegetationon erosion and soil moisture and implications for disturbance on the Loess Plateau, China. Plos One, 2015, 10(5):1.
|
| [20] |
李强, 刘国彬, 许明祥, 等. 黄土丘陵区冻融对土壤抗冲性及相关物理性质的影响[J]. 农业工程学报, 2013, 29(17):105. LI Qiang, LIU Guobin, XU Mingxiang, et al. Effect of seasonal freeze-thaw on soil anti-scouribility and its related physical property in hilly Loess Plateau[J]. Transactions of the Chinese Society of Agricultural Engineering, 2013, 29(17):105.
|
| [21] |
郭明明,王文龙,史倩华,等. 黄土高塬沟壑区退耕地土壤抗冲性及其与影响因素的关系[J].农业工程学报,2016, 32(10):129. GUO Mingming, WANG Wenlong, SHI Qianhua,et al. Soil anti-scourability of abandoned land and its relationship with influencing factors in Loess Plateau Gully region[J]. Transactions of the Chinese Society of Agricultural Engineering, 2016, 32(10):129.
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