Effects of different upper bearing materials of eco-blanket on soil moisture regime and plant growth
ZHAO Zhonghe1,2, TU Panpan1, CHEN Huan1, ZOU Yan3, SONG Huiping1,4, FENG Zhengjun1,5
1. Institute of Resources and Environmental Engineering, Shanxi University, 030006, Taiyuan, China; 2. Shanxi Dadi Eco-Environment Technology Institute Co., Ltd., 030032, Taiyuan, China; 3. Shanxi Qinghuan Nengchuang Environmental Protection Technology Company Limited, 030032, Taiyuan, China; 4. Engineering Research Center of Ministry of Education for Resource Efficiency Enhancing and Carbon Emission Reduction in Yellow River Basin, 030006, Taiyuan, China; 3. Shanxi Laboratory for Yellow River, 030006, Taiyuan, China
Abstract:[Background] Eco-blanket, a convenient material for the restoration of mining area, can control soil erosion and reduce water evaporation. Traditional eco-blanket generally use non-woven fabrics as the upper bearing material. The non-woven fabrics can effectively bear the substrate of eco-blanket and prevent soil erosion, but sometimes it will impede the water infiltration and plant germination. Therefore, it is necessary to find a substitute for the non-woven fabric as the upper bearing material to improve the performance of eco-blanket in mining area restoration. [Methods] A greenhouse experiment was conducted to compare the performances of four different upper bearing materials (fiber paper, thin nonwoven fabric, thick non-woven fabric and knitted fabric) in affecting plant growth, water infiltration rate and soil water content. Bermuda(Cynodon dactylon)grass was planted in a plastic slope with a length of 50 cm, a width of 25 cm and a height of 10 cm for 30 d. The plant growth indexes (vegetation coverage, plant height, plant density and aboveground biomass), the water infiltration rates and changes of soil moisture were detected regularly. [Results] 1) After 30 d of planting, the hierarchy of plant growth indexes was observed as follows: the knitted fabric group showcased superior plant growth and demonstrated the most even distribution of plants on the slope, followed by the thin non-woven fabric group, the fiber paper group, and lastly, the thick non-woven fabric group. 2) At the day 30, the descending order of infiltration levels was the knitted fabric group leading with 0.52 L, then the fiber paper group at 0.47 L, followed by the thin non-woven fabric at 0.44 L, and finally the thick non-woven fabric at 0.41 L. Compared to the day 10, these values increasedby 18.0%, 14.3%, 17.5% and 17.9%, respectively. 3) Within 24 h, soil moisture content for each treatment decreased progressively over time. The fiber paper group, in particular, recorded a significantly lower soil moisture content than the other three groups. The fiber paper group experienced a 28.4% reduction in soil moisture, substantially more pronounced than the reductions in the thick non-woven group at 12.7%, the thin nonwoven group at 16.2%, and the knitted fabric group at 17.2%. [Conclusions] Based on the above results, the knitted fabric seemed to be the best upper bearing material in this study. Its performance in water infiltration and evaporation reduction were ideal and showed no suppression for plant germination, leading to the best vegetation restoration in the four materials. The knitted fabric is therefore an ideal upbearing material, which can replace traditional non-woven fabric and improving the performance of ecoblanket in slope vegetation restoration.
胡振琪,肖武,赵艳玲.再论煤矿区生态环境"边采边复"[J].煤炭学报, 2020, 45(1):351. HU Zhenqi,XIAO Wu,ZHAO Yanling. Re-discussion on coal mine eco-environment concurrent mining and reclamation[J]. Journal of China Coal Society,2020,45(1):351.
[2]
刘兴良,刘世荣,刘杉,等.生态毯植被恢复技术研究及其进展[J].四川林业科技, 2019, 40(6):110. LIU Xingliang,LIU Shirong, LIU Shan,et al. Research and progress of eco-carpet vegetation restoration technology[J]. Journal of Sichuan Forestry Science and Technology,2019, 40(6):110.
[3]
李银,刘凤明,潘元友,等.采矿迹地生态修复综合技术[J].天津农林科技,2009(4):6. LI Yin, LIU Fengming, PAN Yuanyou, et al. Comprehensive technology of ecological restoration of mining sites[J]. Tianjin Agriculture and Forestry Science and Technology, 2009(4):6.
[4]
张利,罗麟,朱欣伟,等.生态毯对川西北流动沙地生态恢复的影响[J].草地学报,2017,25(5):1156. ZHANG Li, LUO Lin, ZHU Xinwei, et al. Effect of ecomat on ecological restoration in shifting sandy land of Northwest Sichuan[J]. Acta Agrestia Sinica, 2017, 25(5):1156.
[5]
ALLEN H H, LEECH J R. Bioengineering for streambank erosion control. Report1-Guidelines[R]. Vicksburg, Mississippi:US Army Corps of Engineers, Waterways Experiment Station, Technical report EL-97-8, 1997.
[6]
HEERTEN G. Geotextiles in coastal engineering:25 years experience[J]. Geotextiles and Geomembranes, 1984, 1(2):119.
[7]
LEFLAIVE E. Geotextiles:Their rationale and future[J]. Geotextiles and Geomembranes, 1985, 2(1):23.
[8]
KANIRAJ S R, RAO G V. Trends in the use of geotextiles in India[J]. Geotextiles and Geomembranes, 1994, 13(6/7):389.
[9]
HONG Y W, SHENG S T. Use of geotextiles in hydraulic works in Heilongjiang, China[J]. Geotextiles and Geomembranes, 1987, 6(4):315.
[10]
马湘波,高小虎.不同覆盖模式对滨莱高速公路路堑边坡客土喷播工程的土壤流失和植被恢复的影响分析[J].公路交通科技(应用技术版), 2019, 15(9):36. MA Xiangbo, GAO Xiaohu. Analysis of the influence of different mulching modes on soil loss and vegetation restoration of the guest soil spraying project on the cutting slope of Binlai Expressway[J]. Highway Traffic Technology (Applied Technology Edition), 2019, 15(9):36.
[11]
李宏钧.植物纤维毯对道路边坡生态防护效益的研究[D].北京:北京林业大学,2016:58. LI Hongjun. The effects of geotextiles on ecological protection technology on the road slope[D]. Beijing:Beijing Forestry University, 2016:58.
[12]
叶建军,王波,李虎,等.曼大公路NK-SG4标段路堤边坡生态防护试验研究[J].公路, 2019, 64(11):246. YE Jianjun, WANG Bo, LI Hu, et al. Experimental study on ecological protection of embankment slope in NK-SG4 section of Manda Highway[J]. Highway, 2019, 64(11):246.
[13]
陈学平,李宏钧,简丽,等.植物纤维毯防护不同施工工艺对公路坡面植被建成影响研究与实践[J].公路, 2016, 61(3):211. CHEN Xueping, LI Hongjun, JIAN Li, et al. Research and practice on the influence of different construction techniques of plant fiber blanket protection on the vegetation formation on highway slope[J]. Highway, 2016, 61(3):211.
[14]
赵廷华,牛晓繁,牛首业,等.河道生态护坡工程中植被毯孔隙率对植物出苗过程的影响[J].南水北调与水利科技,2017,15(A2):114. ZHAO Tinghua, NIU Xiaofan, NIU Shouye, et al. The influence on seedling emergence by pore porosity of vegetation carpet during the projects of ecological slope protection of river channel[J]. South to North Water Transfers and Water Science&Technology, 2017,15(A2):114.
[15]
张强,郇路恒,贾吉敏,等.纯棉针织布印花糊料的研究与应用[J].染整技术, 2022, 44(8):21. ZHANG Qiang, YAN Luheng, JIA Jimin, et al. Research and application of printing paste for pure cotton knitted fabrics[J]. Textile Dyeing and Finishing Journal, 2022, 44(8):21.
[16]
余璐璐,孙海龙,李绍才,等.无纺布覆盖高度对土壤水分蒸发的影响[J].中国水土保持, 2011(3):42. YU Lulu, SUN Hailong, LI Shaocai, et al. Effect of nonwoven covering height on soil moisture evaporation[J]. China Soil and Water Conservation, 2011(3):42.
[17]
潘晓海,刘龙,张彦丰,等.植物纤维毯防护对植物种子出苗的影响[J].公路交通科技(应用技术版), 2015, 11(1):44. PAN Xiaohai, LIU Long, ZHANG Yanfeng, et al. Effect of plant fiber blanket protection on plant seed emergence[J]. Highway Traffic Technology (Applied Technology Edition), 2015, 11(1):44.
[18]
张爱宾,李义强,胡兴波,等.公路绿地废弃物制作边坡绿化覆盖物的性能研究[J].水土保持应用技术, 2020(1):14. ZHANG Aibin, LI Yiqiang, HU Xingbo, et al. Study on the performance of slope greening cover made of highway green space waste[J]. Applied Technology of Soil and Water Conservation, 2020(1):14.
[19]
陈学平,简丽,贾献卓,等.植物纤维毯覆盖对公路边坡植被重建的影响[J].公路交通科技, 2017, 34(2):143. CHEN Xueping, JIAN Li, JIA Xianzhuo, et al. Effect of plant fiber blanket coverage on revegetation of highway side slope[J]. Journal of Highway and Transportation Research and Development, 2017, 34(2):143.
[20]
陈学平,江玉林,宋志强.液压喷播在黄土地区边坡植被建植中的应用研究[J].水土保持研究, 2007,14(1):266. CHEN Xueping,JIANG Yulin,SONG Zhiqiang. The use of hydro-seeding technology for side slope revegetation on Loess Plateau[J]. Research of Soil and Water Conservation,2007,14(1):266.
2024, Vol. 22 
