پیوندهای مفید
آمار
| تعداد نشریات | 32 |
| تعداد شمارهها | 848 |
| تعداد مقالات | 8,218 |
| تعداد مشاهده مقاله | 52,501,370 |
| تعداد دریافت فایل اصل مقاله | 8,947,215 |
Efficacy of nano-hydromulch in mitigating runoff and sediment from forest road trenches.. | ||
| Caspian Journal of Environmental Sciences | ||
| دوره 24، شماره 1، فروردین 2026، صفحه 171-185 اصل مقاله (1.13 M) | ||
| نوع مقاله: Research Paper | ||
| شناسه دیجیتال (DOI): 10.22124/cjes.2026.9507 | ||
| نویسندگان | ||
| Mohammadreza Peron1؛ Ramin Naghdi* 1؛ Mohammadreza Khaledian2 | ||
| 1Department of Forestry, Faculty of Natural Resources, University of Guilan, Sowmehsara, Guilan, Iran | ||
| 2Department of Water Engineering, Faculty of Agricultural Sciences, University of Guilan, Rasht, Iran & Department of Water Engineering and Environment, Caspian Sea Basin Research Center | ||
| چکیده | ||
| Water erosion causes significant damage to forest roads. Protecting cut-and-fill slopes can mitigate these damages. This study aimed to evaluate the effectiveness of several protective coverings based on nano-materials in reducing runoff and sediment yield from forest road trenches. Nano-hydromulch (NH) with rice straw, sawdust and grass, NH with grass, grass, and control were investigated under laboratory conditions on slopes of 10% and 30%, as representatives of the major slopes of forest road trenches, with three replications. Using a rainfall simulator, a rainfall event with a volume of 1800 cm3 was simulated, and runoff, sediment, sediment concentration, runoff coefficient, and soil loss were measured in the treatments. Results indicated that increasing slope steepness from 10 to 30% significantly increased runoff by 76%, sediment yield by 979%, and soil loss percentage by 480% (p < 0.01). Therefore, cut-and-fill slopes should be adequately protected. NH treatments effectively reduced runoff, and by creating proper soil aggregate adhesion, reduced substantially sediment yield and soil loss (p < 0.01). It is recommended to use NH, especially combined with grass, to protect cut-and-fill slopes of forest roads, thereby reducing maintenance costs. | ||
| کلیدواژهها | ||
| Grass؛ Rainfall simulator؛ Sediment concentration؛ Soil loss | ||
| مراجع | ||
|
Abbas, H, Singh, A & Zhang, Z 2021, Soil erosion and sediment transport under different land management practices. Journal of Soil and Water Conservation, 76(4): 245-257.
Alvarez, S & Carpintero, C 2023, The influence of environmental conditions on the fire behavior of natural fibers. Fire Safety Journal,
Angulo-Martinez, M, Begueria, S, Navas, A, Machin, J 2012 Splash erosion under natural rainfall on three soil types in NE Spain. Geomorphology, 175-176: 38-44.
Blanco-Canqui, H & Ruis, S J 2020, No-till and soil physical environment. Geoderma, 365: 114224.
Brown, K, & Burnham, J 2022, Time dynamics of hydromulched vegetation establishment. Soil Science Society of America Journal.
Chen, Y, Liu, H & Zhao, S 2023a, Current status and future directions of nanomulch technology for erosion control: A review. Journal of Hydrology and Environmental Engineering, 45(1): 56-71.
Chen, W, Zhang, H & Liu, J 2023b, Nano-biochar effects on soil erosion and soil organic carbon dynamics: A review. Environmental Science & Technology, 57(3): 1245-1260.
Farhoudi, M, Beheshti Aal-Agha, A, Aghabigi Amin, S, Bazrafshan, E, Halisaz, E, Eshmaeilpour, Y 2018, The impact of vermicompost and straw and hay additives on runoff and soil erosion. Geography and Sustainability, 29: 1-12.
Fine-nano 2025, https://fine-nano.ir/product/silicium-oxide-nano-particle/.
Gagg, C & Cooper, L 2020, Economic assessment of hydromulch in vegetation establishment: A review. International Journal of Innovative Research in Engineering and Management.
Ghahramani, A, Amiri, F & Moghaddam, R 2011, Effectiveness of bioengineering techniques for erosion control in forested areas. Forest Ecology and Management, 261(3): 391-399.
Greenway, M 2019, Vegetation and environmental management of constructed wetlands for stormwater and wastewater treatment in subtropical and tropical regions. Hydrobiologia, 634: 139-152.
Gupta, S, Chandra, P & Singh, V P 2022, Nanotechnology for sustainable soil management: Challenges and opportunities. Journal of Cleaner Production, 339: 130658.
Gupta, R & Sharma, P 2023, Application of nanomaterials in soil erosion prevention: A comprehensive review. Agricultural Sciences, 14(2): 123-134.
Jiang, H, Chen, Z & Zhang, X 2023, Evaluation of nano-hydromulch for soil erosion control under simulated rainfall. Journal of Environmental Management, 315, 115206.
Jabbari, Z, Mohammadi Qalanei, M, Maqdesi, M, Dehban, H 2022, The effects of slope and rainfall intensity on runoff and soil loss using a rainfall simulator. Environmental Erosion Research, 12(1): 128-113.
Kumar, S, Singh, A & Gupta, R K 2021, The role of bioengineering techniques in soil erosion control: A comprehensive review. Environmental Science and Pollution Research, 28(4): 4524-4541.
Lal, R 2020, Soil erosion and carbon dynamics. Global Change Biology, 26(1): 9-25.
Lal, R & Stewart, B A 2018, Soil erosion research methods. CRC Press.
Li, X, Chen, W & Zhang, J 2022, Impacts of nano-hydromulch on soil erosion and runoff control in forest slopes. Geoderma, 412: 115623.
Li, Y, Liu, J & Zhang, S 2021, Performance of nano-hydromulch in reducing soil erosion and runoff. Environmental Science & Technology, 55(22): 15478-15486.
Liu, Y, Zhang, J & Hu, G 2021, Impact of rainfall runoff on soil erosion and sediment yield in hilly terrains: A case study. Journal of Hydrology, 596: 126059.
Lyu, Y, Wang, W & Zhang, X 2021, Hydroseeding with nano-hydromulch for erosion control: A review of recent advances. Journal of Hydrology, 604: 127245.
Markou, G, Santini, C & Papadakis, E 2007, Rainfall simulation experiments for evaluating soil erosion control measures. Soil & Tillage Research, 94(1): 30-39.
Mahaske, SN, Pathak, K & Basak, A 2019, A comprehensive design of rainfall simulator for the assessment of soil erosion in the laboratory. Catena, 172: 408 -420.
Miyata, S, Masuzawa, T & Kuraoka, S 2009, "Quantifying soil erosion and sediment yield using simulated rainfall." Catena, 79(2), 116-122.
Milly, PCD, Dunne, KA & Vecchia, AV 2020, Climate change and the frequency of extreme flood events. Nature Climate Change, 10(10): 816-820.
Morgan, RPC 2020, Soil erosion and conservation. John Wiley & Sons.
Morgan, RPC & Nearing, MA 2022, Soil erosion and conservation: The role of mulches in modern soil conservation strategies. Journal of Soil and Water Conservation, 77(2): 155-167.
Nguyen, TT, Le, HT & Nguyen, A V 2023a, Recent advancements in soil erosion control techniques: A comprehensive review. Journal of Environmental Management, 327: 116793.
Nguyen, H, Tran, H & Nguyen, M 2023b, Advances in soil erosion control and runoff reduction: A comprehensive review. Journal of Soil and Water Conservation, 78(2): 142-158.
O'Gorman, PA 2019, Climate change and precipitation. Annual Review of Earth and Planetary Sciences, 47: 75-100.
Pimentel, D, Harvey, C & Resosudarmo, P 2019, Environmental and economic costs of soil erosion and conservation benefits. Science, 267(5201): 1117-1123.
Prats, SA, Malvar, MC, Vieira, DCS, MacDonald, L, Keizer, JJ 2016, Effectiveness of hydromulching to reduce runoff and erosion in a recently burnt pine plantation in central Portugal. Land Degradation and Development, 27: 1319-1333.
Raza, A, Khan, M & Ali, S 2023, The role of nanomaterials in enhancing soil properties and erosion control: A review. Environmental Science and Pollution Research, 30(2): 1500-1512.
Ricks, MD, Wilson, WT, Zech, WC, Fang, X, Donald, WN 2020 Evaluation of hydromulches as an erosion control measure using laboratory-scale experiment. Water, 12: 515.
Sadeghi, S, Fattahi, B & Keshavarz, M 2019, Impact of hydromulch on soil erosion and runoff: A case study. Environmental Management, 63(5): 621-631.
Saeidi, M & Sadeghi, S 2010, Evaluation of soil loss and sediment yield using rainfall simulation tests. Soil Science Society of America Journal, 74(1): 20-27.
Shao, M, Wang, J & Qin, F 2020, Nanotechnology applications in soil moisture management: A review. Journal of Nanoparticle Research, 22(1): 1-15.
Silva, J, Duarte, A & Oliveira, A 2023, Assessment of sediment transport and soil erosion in response to different hydromulch treatments. Land Degradation & Development, 34(2): 358-370.
Singh, N, Sharma, A & Singh, V 2022, Nanotechnology for soil and water management: Implications for environmental sustainability. Environmental Pollution, 301: 118929.
Smith, AJ & Johnson, R 2022, Evaluating the economic and environmental benefits of nano-mulch for soil conservation. Journal of Soil and Water Conservation, 77(4): 381-390.
Stokes, A & Morgan, RPC 2019, The contribution of soil erosion research to the development of sustainable land management. Environmental Science & Policy, 101: 100-110.
Tajada, G & Gonzalez, M 2007, "Methods for determining soil bulk density and their implications." Soil Science Society of America Journal, 71(5): 1551-1559.
Thompson, L, Baker, M & Zhang, H 2021, Nano-enhanced mulch for improved soil stability and water conservation in arid environments. Agricultural Water Management, 251: 106897.
Trenberth, K E 2022, The changing character of precipitation. Climate Change, 170(1-2): 1-10.
Wang, Y, Liu, Z & Zhou, Q 2022a, Impact of straw mulch on soil erosion and water infiltration in cultivated lands: A review. Catena, 209: 105819.
Wang, T, Sun, D & Yu, Q 2022b, Evaluation of hydrological and sedimentological impacts of different bioengineering techniques in mountainous regions. Water Resources Research, 58(8): e2022WR031213.
Wang, H, Yang, X & Zhao, X 2022c, Effectiveness of different erosion control treatments on sediment and runoff. Journal of Environmental Management, 306: 114446.
Wischmeier, WH & Smith, D 1978, Predicting Rainfall Erosion Losses: A Guide to Conservation Planning. USDA Agricultural Handbook, No. 537.
Yakupoglu, S, Çolak, A & Yalçın, A 2019, The potential benefits of polymers in soil erosion control for agricultural designs. Journal of Soil and Water Conservation, 74(5): 37-45.
Zhang, H, Li, Y & Chen, W 2020a, Biochar and nano-biochar: Promising soil amendment for improved soil moisture retention and erosion control. Geoderma, 378: 114613.
Zhang, J, Lin, Y & Wu, X 2020b, Improving soil stability with nano-materials: A review. Journal of Environmental Quality, 49(3): 606-617.
Zhang, Y, Liu, W & Wu, Y 2021a, Nano-hydromulch as an innovative soil stabilizer in slope protection: A review. Journal of Soil Science and Plant Nutrition, 21(2): 1256-1268.
Zhang, L, Wang, J & Li, X 2023, Recent advancements in hydromulch technology for soil erosion control: A review. Environmental Science and Pollution Research, 30: 45789-45802.
Zhang, Y, Wang, X & Liu, L 2022a, Integration of mechanical and biological methods for effective soil erosion control: A review. Land Degradation & Development, 33(5): 819-832.
Zhang, H, Wu, P & Zhou, Q 2021b, Role of nanomaterials in improving soil properties and preventing soil erosion: A review. Environmental Science: Nano, 8(7): 1854-1869.
Zhang, Y, Xue, Y & Zhao, R 2022b, Advanced nanomaterials for erosion control and soil stabilization: A review. Advanced Materials, 34(10): 2108253.
Zhang, L, Yang, H & Sun, X 2024, Efficacy of nanomulch in managing soil erosion under extreme rainfall conditions: Insights and future research needs. Environmental Science & Technology Letters, 11(3): 234-243.
Zhao, J, Yang, Z & Govers, G 2019, Soil and water conservation measures reduce soil and water losses in China but not down to background levels: Evidence from erosion plot data. Geoderma, 337: 729-741. | ||
|
آمار تعداد مشاهده مقاله: 10 تعداد دریافت فایل اصل مقاله: 5 |
||