高速公路路堑边坡客土喷播的长期防护效果

doi:10.16258/j.cnki.1674-5906.2021.08.019

生态环境学报 ›› 2021, Vol. 30 ›› Issue (8): 1724-1731.DOI: 10.16258/j.cnki.1674-5906.2021.08.019

高速公路路堑边坡客土喷播的长期防护效果

汪益敏(), 陶玥琛, 程致远, 李博文

华南理工大学土木与交通学院,广东广州 510640

收稿日期:2021-05-28 出版日期:2021-08-18 发布日期:2021-11-03
作者简介:汪益敏（1966年生）,女,教授,博士,博士研究生导师,主要研究方向为公路路基边坡加固与防护。E-mail: ctymwang@scut.edu.cn
基金资助:
国家重点研发计划项目(2016YFC0802500);广东省交通科技项目(2014)

Long-term Protective Effect of External-Soil Spray Seeding on Highway Cutting Slope

WANG Yimin(), TAO Yuechen, CHENG Zhiyuan, LI Bowen

School of Civil Engineering and Transportation, South China University of Technology, Guangzhou 510640, China

Received:2021-05-28 Online:2021-08-18 Published:2021-11-03

摘要/Abstract

摘要：

公路路堑边坡不利的地形、土壤条件使得植被恢复和坡面安全受到挑战。客土喷播技术是一种应用于边坡防护的生态护坡技术。为了研究高速公路路堑边坡在进行客土喷播后,对应的长期生态恢复效果和水土保持效益,以广东省惠河高速公路客土喷播路堑边坡为研究对象,基于2003—2020年将近18年的路堑边坡植被调查数据,分析了客土喷播边坡的植被生长特征和物种组成变化,并利用水蚀预报模型对坡面植被的水土保持效果进行定量研究。结果表明：在客土喷播初期,植被能够快速覆盖坡面,3个月实现48%—61%的整体植被覆盖率,第2年后峰值盖度稳定在95%和88%左右,长期植被覆盖率保持在84%—96%左右,植被恢复速度和长期持续效果良好;植被物种组成在调查期间发生显著变化,在建植初期群落主要由初始喷播物种组成,此时优势种为狗牙根（Cynodon dactylon）等先锋植物,随着演替的进行,初始喷播物种逐渐被其他乡土植物取代,形成了以芒萁（Dicranopteris dichotoma）等草本植物为优势种的新群落,灌木植物对整体盖度的贡献逐渐提升,坡面物种丰富度逐渐增加,在第18年的调查中,在样方内共发现20种植物;客土喷播植被对于坡面土壤流失的控制效果显著,第1周年实现了68.6%和91.4%的土壤流失减少率,调查末期的年土壤流失减少率高于96%。因此,引入外来物种实现坡面植被快速恢复的做法是可行的,尽管这些物种存在时间可能较短,但在减少建植早期的坡面侵蚀和改善乡土植物定植条件上是有效的。该研究能为路堑边坡的生态防护设计和长期生态恢复效果预测提供重要的参考与借鉴。

关键词: 客土喷播, 植被恢复, 植物演替, 坡面侵蚀, 生态防护, 路堑边坡, 高速公路

Abstract:

The external-soil spray seeding (ESSS) is an ecological slope protection technology applied to slope protection, the unfavorable topography and soil conditions of the highway cutting slope makes vegetation restoration stability and slope safety challenged. To analysis the long-term vegetation restoration effects and water and soil conservation effects of the cutting slope of the highway restored by ESSS, the cutting slopes on the Huihe Highway in Guangdong Province, which were restored by ESSS, were taken as the research object, based on the long-term vegetation survey data from 2003 to 2020, the vegetation growth characteristics and species composition changes on the research slope were analyzed, and The water erosion prediction model was used to quantitatively analyze the erosion control effect of the slope vegetations. The results showed that in the initial stage after ESSS, vegetations covered the slopes quickly, achieved an overall vegetation coverage of 48% to 61% after 3 months, and the peak coverage stabilized at about 95% and 88% after the second year. The long-term vegetation coverage rate was maintained at about 84%-96%, which means the vegetation restoration speed and long-term continuous effect were good; the vegetation species composition has changed significantly during the investigation period. At the beginning, the vegetations were consist of the initial spraying species, the dominant species was Cynodon dactylon and other pioneer plants. With the succession of the community, the early sprayed species were gradually replaced by other native plants, forming a new community dominated with herbs such as Dicranopteris dichotoma. The coverage of shrubs and trees on the slope gradually increased, so was the species richness. In the 18th year of the survey, a total of 20 plants were found in the plot. the vegetations on the slope has a significant effect on the control of the slope soil loss. The annual soil loss reduction rates were 68.6% and 91.4% in the first anniversary, and the annual soil loss reduction rates were higher than 96% at the end of the survey. Therefore, it is feasible to introduce non-native species to achieve rapid restoration of slope vegetation. Although these species may exist for a short time, they are effective in improving slope erosion in the early stage of planting and native plant colonization conditions. This research can provide an important reference for the ecological protection design and the prediction of long-term ecological restoration effects for the cutting slopes

Key words: external-soil spray seeding, vegetation restoration, vegetation succession, slope erosion, ecological protection, Cutting slope, highway

中图分类号:

X144
X951

汪益敏, 陶玥琛, 程致远, 李博文. 高速公路路堑边坡客土喷播的长期防护效果[J]. 生态环境学报, 2021, 30(8): 1724-1731.

WANG Yimin, TAO Yuechen, CHENG Zhiyuan, LI Bowen. Long-term Protective Effect of External-Soil Spray Seeding on Highway Cutting Slope[J]. Ecology and Environment, 2021, 30(8): 1724-1731.

图/表 10

图1 研究边坡的设计断面和施工完成现场图图中尺寸以米计;岩性：（1）残积土,（2）强风化砂页岩,（3）砂页岩

Fig. 1 Sectional drawing and construction site of the study cutting slope The dimensions in this drawing are in meters; Lithology: (1) Residual soil, (2) Highly-weathered sand shale, (3) Sand shale

表1 WEPP所用的主要土壤参数

Table 1 Major soil inputs for WEPP applications

参数 Parameters	客土 Artificial soil	残积土 Residual soil	强风化砂页岩 Highly-weathered sand shale	砂页岩 Sand shale
土层深度 Soil depth/cm	10	90	90	90
砂粒 Sand/%	52.28	36.78	32.25	38.84
粘粒 Clay/%	29.2	44.5	45.2	15.6
离子交换能力 Cation exchange capacity/(cmol∙kg^-1)	13.1	10.5	10.1	10
有机质含量 Organic matter/(% volume)	1.27	1.1	0.63	0.42

表2 WEPP所用的主要作物管理参数

Table 2 Major management inputs for WEPP applications

参数 Parameters	1号坡 Slope 1		2号坡 Slope 2
参数 Parameters	第1年Year1	第2年起 Year2-Year18	第1年 Year1	第2年起 Year2-Year18
达到衰老的日期 Date to reach senescence/ (Julian day)	280	280	300	280
衰老持续的时间 Period over which senescence occurs/d	100	100	80	100
衰老后剩余的冠层百分比 Fraction of canopy remaining after senescence/%	80	86	80	80
衰老后剩余的生物量百分比 Fraction of biomass remaining after senescence/%	50	46	80	50
生物量能量比 Biomass Energy Ratio	4.5	2.2	19	4.5
最大叶面积指数 Maximum Leaf Area Index			6

图2 植被盖度和地上生物量变化盖度：1号坡（n=15）,2号坡（n=18）;生物量：1号坡（n=9）,2号坡（n=11）

Fig. 2 Variations in vegetation coverage and aboveground biomass Coverage: Slope 1(n=15), Slope 2(n=18); Biomass: Slope 1(n=9), Slope 2(n=11)

图3 不同坡级的植被盖度对比 n=15

Fig. 3 Comparison of vegetation coverage between different slope grades

图4 相对物种盖度变化 1号坡（n=15）;Slope 1（n=15）;2号坡（n=18）;Slope 2（n=18）。下同

Fig. 4 Variations in relative species coverage

图5 第18年11月的相对物种盖度

Fig. 5 Relative species coverage in November of the 18th year

图6 第18年11月的典型植物图像和名称

Fig. 6 Images and names of the typical plants in November of the 18th year

图7 客土喷播坡面与裸坡的土壤流失和径流对比

Fig. 7 Comparison of soil loss and runoff on external-soil spray seeding slope and bare slope

图8 坡面土壤流失量与降雨量的年际变化

Fig. 8 Inter-monthly variations of soil loss on slope and rainfall

参考文献 22

[1]	CAO W, OMRAN B A, LEI Y K, et al., 2018. Studying early stage slope protection effects of vegetation communities for Xinnan Highway in China[J]. Ecological Engineering, 110: 87-98. DOI URL
[2]	CHEN J, XIAO H B, LI Z W, et al., 2019. Threshold effects of vegetation coverage on soil erosion control in small watersheds of the red soil hilly region in China[J]. Ecological Engineering, 132: 109-114. DOI URL
[3]	ELLIOT W J, HALL D E, 1997. Water erosion prediction project (WEPP) forest applications[M]. Ogden: US Department of Agriculture: 1-11.
[4]	FLANAGAN D C, FRANKENBERGER J R, ASCOUGH II J C, et al., 2012. WEPP: Model use, calibration, and validation[J]. Transactions of the American Society of Agricultural and Biological Engineers, 55(4): 1463-1477.
[5]	FU D Q, YANG H, WANG L, et al., 2018. Vegetation and soil nutrient restoration of cut slopes using outside soil spray seeding in the plateau region of southwestern China[J]. Journal of Environmental Management, 228: 47-54. DOI URL
[6]	HUANG Z Y, CHEN J, AI X Y, et al., 2017. The texture, structure and nutrient availability of artificial soil on cut slopes restored with OSSS-Influence of restoration time[J]. Journal of Environmental Management, 200: 502-510. DOI URL
[7]	KUMAR R, LONE M A, SINGH V P, 2021. Temporal Simulation of Sediment Yield Using WEPP Model in Dal Catchment of Temperate Region of Kashmir Valley, India: Case Study[J]. Journal of Hydrologic Engineering, 26(5): 05021006-1-8.
[8]	LIU Y F, DUNKERLEY D, LÓPEZ-VICENTE M, et al., 2020. Trade-off between surface runoff and soil erosion during the implementation of ecological restoration programs in semiarid regions: A meta-analysis[J]. Science of the Total Environment, DOI: 10.1016/j.scitotenv.2019.136477. DOI
[9]	MARTÍNEZ-RUIZ C, FERNANDEZ-SANTOS B, PUTWAIN P D, et al., 2007. Natural and man-induced revegetation on mining wastes: changes in the floristic composition during early succession[J]. Ecological Engineering, 30(3): 286-294. DOI URL
[10]	MUNROE D K, VAN BERKEL D B, VERBURG P H, et al., 2013. Alternative trajectories of land abandonment: causes, consequences and research challenges[J]. Current Opinion in Environmental Sustainability, 5(5): 471-476. DOI URL
[11]	NEARING M A, FOSTER G R, LANE L J, et al., 1989. A process-based soil erosion model for USDA-Water Erosion Prediction Project technology[J]. Transactions of the American Society of Agricultural and Biological Engineers, 32(5): 1587-1593.
[12]	VIDAL-MACUA J J, NICOLAU J M, VICENTE E, et al., 2020. Assessing vegetation recovery in reclaimed opencast mines of the Teruel coalfield (Spain) using Landsat time series and boosted regression trees[J]. Science of The Total Environment, DOI: 10.1016/j.scitotenv.2020. 137250. DOI
[13]	XU X L, ZHANG K L, KONG Y P, et al., 2006. Effectiveness of erosion control measures along the Qinghai-Tibet highway, Tibetan plateau, China[J]. Transportation Research Part D: Transport and Environment, 11(4): 302-309. DOI URL
[14]	蒋鹏飞, 李志勇, 舒安平, 等, 2011. 公路边坡防护技术[M]. 北京: 北京人民交通出版社: 1-248.
	JIANG P F, LI Z Y, SHU A P, et al., 2011. Protection Technology for Highway Slope[M]. Beijing: China Communications Press: 1-248.
[15]	刘涛, 程金花, 李宏钧, 等, 2021. 伊犁地区公路边坡植被恢复措施与土壤因子的耦合关系[J]. 公路交通科技, 38(4): 28-35.
	LIU T, CHENG J H, LI H J, et al., 2021. Coupling Relationship between Vegetation Restoration Measure and Soil Factor of Highway Slope in Ili[J]. Journal of Highway and Transportation Research and Development, 38(4): 28-35.
[16]	潘声旺, 雷志华, 杨丽娟, 等, 2013. 几种典型边坡植被的产流、产沙特征[J]. 生态环境学报, 22(7): 1167-1172.
	PAN S W, LEI Z H, YANG L J, et al., 2013. Characteristic of runoff and sediment yield of typical vegetation for highway side slope in southwest areas[J]. Ecology and Environmental Sciences, 22(7): 1167-1172.
[17]	谭少华, 汪益敏, 2004. 高速公路边坡生态防护技术研究进展与思考[J]. 水土保持研究, 11(3): 83-86.
	TAN S H, WANG Y M, 2004. Research Progress and Thinking of Bioengineering Techniques for Slope Protection in Expressway[J]. Research of Soil and Water Conservation, 11(3): 83-86.
[18]	谭少华, 2005. 高速公路路基边坡生态防护效果的调查研究及评价[D]. 广州: 华南理工大学: 1-100.
	TAN S H, 2005. Investigation and Evaluation of Ecological Protection Effect of Highway Subgrade Slope[D]. Guangzhou: South China University of Technology: 1-100.
[19]	王忠伟, 黄景春, 宁立波, 等, 2018. 灰岩边坡挂网喷播技术适宜坡度条件研究[J]. 环境科学与技术, 41(1): 156-162.
	WANG Z W, HUANG J C, NING L B, et al., 2018. Suitable Slope Conditions for Sowing Grass Seeds in Mixture by Hanging Wire Netting in Limestone Region[J]. Environmental Science & Technology, 41(1): 156-162.
[20]	余长洪, 李就好, 陈凯, 等, 2013. 砖红壤区WEPP模型土壤参数的率定[J]. 广东农业科学, 40(4): 177-178.
	YU C H, LI J H, CHEN K, et al., 2013. Calibrating of WEPP soil parameters on laterite area[J]. Guangdong Agricultural Sciences, 40(4): 177-178.
[21]	喻永祥, 郝社锋, 蒋波, 等, 2021. 基于聚氨酯复合基材的岩质边坡客土生态修复试验研究[J]. 水文地质工程地质, 48(2): 174-181.
	YU Y X, HAO S F, JIANG B, et al., 2021. An experimental study of the ecological restoration of rock slope based on polyurethane composite-based materials[J]. Hydrogeology & Engineering Geology, 48(2): 174-181.
[22]	张霄, 张红玉, 陆兆华, 等, 2017. 高寒地区路堑边坡植被恢复效果[J]. 生态学报, 37(5): 1450-1457.
	ZHANG X, ZHANG H Y, LU Z H, et al., 2017. Vegetation restoration effects of rock cutting slopes in the cold region of China[J]. Acta Ecologica Sinica, 37(5): 1450-1457.

高速公路路堑边坡客土喷播的长期防护效果

Long-term Protective Effect of External-Soil Spray Seeding on Highway Cutting Slope

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 10

参考文献 22

相关文章 3

编辑推荐

Metrics

本文评价

[1]	刘祥宏, 尹勤瑞, 辛建宝, 刘伟, 许秀泉, 黄占斌, 安如意. 生态植被自然修复及其人工促进技术研究进展与展望[J]. 生态环境学报, 2022, 31(7): 1476-1488.
[2]	杨媛媛, 佘志鹏, 宋进喜, 朱大为. 2000年以来浐灞河流域不同地貌区植被变化特征及影响因素研究[J]. 生态环境学报, 2022, 31(2): 224-230.
[3]	史利江, 高杉, 姚晓军, 张晓龙, 李文刚, 高峰. 晋西北黄土丘陵区不同植被恢复下的土壤碳氮累积特征[J]. 生态环境学报, 2021, 30(9): 1787-1796.