Iranian Journal of Forest

Iranian Journal of Forest

Effect of slope and different intensities of rainfall using rain simulator on runoff and soil loss one year after forest fire (Shenroud Forest, Guilan)

Document Type : Research Paper

Authors
M Alidoust 1
R Naghdi 2
M Nikooy 2
H.R Peyrowan 3
1 Ph.D. Forest Science and Engineering, Faculty of Natural Resources, University of Guilan, Sowmeh sara, I. R. Iran
2 Prof., Dept. of Forestry, Faculty of Natural Resources, University of Guilan, Sowmeh sara, I. R. Iran
3 Associate Prof., Soil Conservation and Watershed Management Research Institute, Agricultural Research, Education and Extension Organization (AREEO), Tehran, I. R. Iran
10.22034/ijf.2024.414296.1943
Abstract
Introduction: Forest fires is one of the most important environmental problems and often as an important driver in runoff generation and soil erosion in the forest. This study was conducted with the aim of investigating the mutual effect of slope and rainfall intensity on the runoff generation and soil loss in a burned forest using a rainfall simulator.
Material and Methods: This study was conducted in series 4 of Babakoh of the 25 Forestry Zone of Shenroud, Siahkal County, Guilan Province, where about 8(ha) of the forest area of this zone suffered from a relatively severe fire in 2019. The climate of the region is semi-humid and moderate, the minimum and maximum relative humidity varies between 70 and 90 percent, respectively. The height above the sea level is 350 meters, the slope direction is southwest, the annual rainfall is 1465 mm, the initial soil moisture is 16.46%, the texture of the soil is loamy sand. Changes in parameters of runoff volume, runoff coefficient, soil loss and sediment concentration due to changes with two treatments, slopes at two levels of 15 and 30% and rainfall intensity at three levels of 8.16, 7.16, and 4.13 mm min-1 in the time of 6.26 min was investigated using a rainfall simulator. Analysis of variance of the parameters measured in the experiments was performed with three replications within 18 plots (25×25 cm) by using Komforest type rain simulator. Factorial analysis of variance was performed in the form of complete randomized design and comparison of the average interaction effects of treatments was performed with Duncan's method at the 95% confidence level.
Results: The results of analysis of variance showed that the interaction effect of slope treatments and rainfall intensity on the studied components is significant (p≤0.05). The highest amount of runoff volume was recorded in the treatment of rainfall intensity of 16.8 mm/min and slope of 30% with a value of 2418.33 ml and a runoff coefficient of 81.53%  and the lowest one related to the treatment of rainfall intensity of 13.4 mm/min and slope of 15% was recorded with a value of 846 ml. The results of soil loss showed that the highest value was related to the rainfall intensity of 16.8 mm/min with a slope of 15% to the value of 11.06 gr and the lowest soil loss was 13.4 mm/min related to the intensity of rainfall and a slope of 30% to the value of 1.79 gr. The highest concentration of sediment was recorded at a slope of 15% and intensity of 13.4 mm/min.
Conclusion: This research showed that the total average volume of runoff increased by 17.61% in the period of one year after the fire in this area with the increase of slope from 15% to 30%. Also, in the rainfall intensity of 8.16 mm/min, as the maximum intensity in this research, the volume of runoff increased by 33.6% from the slope of 15 to 30%. The results of the study of soil loss showed that it had an average increase of 61.9% in the slope of 15% compared to 30%. Also, there was a 76% increase in the rainfall intensity treatment of 8.16 mm/min. These results indicate that the slope and intensity of rainfall are effective factors in the hydrological cycle and erosion in the forest area of this study after the fire. 
Keywords
Forest fire
Runoff
Rain simulator
Soil erosion

Subjects

Ahmadi Eilkhchy, A., Hajabbasi, M.A., & Jalalyan, A. (2002). The effect of changing the use of pasture land to dry farming on runoff production, waste and soil quality in Dorahan region. Agricultural sciences and techniques and natural resources, 6(4),103-114. (In Persian)
Akbarzadeh, A., Ghorbani Dashtaki, S., Naderi Khorasgani, M., Mohammadi, J., & Taghizadeh Mehrjardi, R. (2017). Effect of fire on water repellency, amount and factors of soil erosion in forests of southwest coast of the Caspian Sea. Iranian Journal of Forest, 9(1),145-157. (In Persian)
Azmoodeh, A., Kavian, A., soleimani, K., & Vahabzadeh, Gh. (2010). Comparing Runoff and Soil Erosion in Forest, Dry Farming and Garden Land Uses Soils Using Rainfall Simulator. Journal of Water and Soil, 24(3), 490-500. (In Persian)
Badia, D., & Marti, C. (2008). Fire and Rainfall Energy Effects on Soil Erosion and Runoff Generation in Semi-Arid Forested Lands. Arid Land Research and Management, 22(2), 93-108.
Bayat, R., Arabkhedri, M., Gerami, Z., Eisaei, H., & Alivamaei, R. (2016). Survey on quality of dry lands runoff using rainfall simulator (Kalaleh, Golstan Province, case study). 5th conference on rainwater catchment systems. Guilan- IRAN. (In Persian)
Brath, A., Montanari, A., & Moretti, G. (2006). Assessing the effect on flood frequency of land use change via hydrological simulation (with uncertainty). Journal of Hydrology, 324(4), 141-153.
Debano, L.F., Neary, D.G., & Folliott, P.F. (1998). Fire effects on ecosystems. Wiley, New York. 333p.
Doerr, S.H., Shakesby, R.A., Blake, W.H., Chafer, C.J., Humphreys, G.S., & Wallbrink, P.J. (2006). Effects of different wildfire severities on soil wettability and implications for hydrological response. Journal of Hydrology, 319, 295–311.
Ebrahimi Mohammadi, Sh., Azari, M., & Manoochehri, E. (2016). Effects of Fire on Soil Properties, Erosion and Hydrologic Regime of Zrebar Lake Watershed. Journal of Water and Soil, 30(2), 618-631. (In Persian)
Foster, A.C., Armstrong, A.H., Shuman, J.K., Shugart, H.H., Rogers, B.M., Mack, M.C., Goetz, S.J., & Ranson, K.J., (2019). Importance of tree- and species-level interactions with wildfire, climate, and soils in interior Alaska: implications for forest change under a warming climate. Ecological Modelling, 409, 108765. https://doi.org/10.1016/j.ecolmodel.2019.108765
Havel, A., Tasdighi, A., & Arabi, M. (2018). Assessing the hydrologic response to wildfires in mountainous regions. Hydrology and Earth System Sciences, 22(4), 2527-2550.
Hubbert, K.R., Preisler, H.K., Wohlgemuth, P.M., Graham, R.G., & Narog, M.G. (2006). Prescribed burning effects on soil physical properties and water repellency in a steep chaparral watershed, Southern California, USA. Geoderma, 130, 284–298.
Gholami Gohareh, R., Sadeghi, S.H.R., Mirnia, S.Kh., & Soleimankhani, Z. (2012). Effects of Light Firing on Infiltration, Runoff and Sediment in Rangeland in Kodir Area, Iran. Iran-Watershed Management Science & Engineering, 5(17), 23-32. (In Persian)
Goode, J.R., Luce, C.H., & Buffington, J.M. (2012). Enhanced sediment delivery in a changing climate in semi-arid mountain basins: implications for water resource management and aquatic habitat in the northern Rocky Mountains. Geomorphology, 139(140), 1–15. https://doi.org/10.1016/j.geomorph.2011.06.021.
Jabbary Zahra, A., Mohammadi GHaleni, M., Moghaddasi, M., & Dehban, H. (2021). The effect of slope and rainfall intensity on runoff and soil erosion using a rainfall simulator. Quarterly journal of Environmental Erosion Research, 45(1), 113-128. (In Persian)
Jafari Haghighi, M., (2003). Methods of soil decomposition Sampling and important physical and chemical analyzes with emphasis on theoretical and practical principles. neday zaha press. (In Persian)
Landi, A., Barzegar, AR., Sayadi, J., & Khademalrasoul, A. (2011). Assessment of Soil Loss Using WEPP Model and eographical Information System. Journal of Spatial Hydrology, 11(1), 40-51.
Larsen, I.J., MacDonald, L.H., Brown, E., Rough, D., Welsh, M.J., Pietraszek, J.H., Libohova, Z., Benavides-Solorio, J.D., & Schaffrath, K. (2009). Causes of post-fire runoff and erosion: water repellency, cover, or soil sealing?. Soil Science Society of America Journal, 73(4), 1393-1407. https://doi.org/10.2136/sssaj2007.0432.
Marques, M.J., Bienes, R., Jimenez, L., & Perez- Rodriguez, R. (2007). Effect of vegetal cover on runoff and soil erosion under light intensity events. Rainfall simulation over USLE plots. Science of the Total Environment, 378, 161-165. https://doi: 10.1016/j.scitotenv.2007.01.043.
Matinizadeh, M., & Gudarzi, M. (2013). Effects of fire on activity of some rangeland soil enzymes.
Iranian Journal of Range and Desert Research, 20(1), 213-225. (In Persian)
McNabb, D., Swanson, H., & Frederick, J. (1990). Effects of fire on soil erosion. In: Walstad, John D.; Radosevich, Steven R.; Sandberg, David V., eds. Natural and prescribed fire in the Pacific Northwest forests. Corvallis, OR: Oregon State University Press, 159-176p.
Neary, D.G., Gottfried, G.J., & Ffolliott, P.F. (2003). Post-wildfire watershed flood responses. Second International Fire Ecology and Fire Management Congress, Orlando, Florida, Paper 1B7.
Neris,  j., Robichaud, P.R., Wagenbrenner, J.W., Brown, R.E., & Doerr, S.H. (2023). Soil erosion after fire in volcanic terrain: Assessment and implications for post-fire soil losses. Journal of Hydrology, 625(A) 1-17. https://doi.org/10.1016/j.jhydrol.2023.129923
Kiani Harchegani, M., Sadeghi, S., & Asadi, H. (2017). Intra-storm variability of runoff volume change coefficient and soil loss during simulation repetitions of rain and soil erosion. Journal of Ecohydrology, 4(1), 191-199
Parlak, M. (2015). Effects of Wildfire on Runoff and Soil Erosion in the Southeastern Marmara Region, Turkey. Ekoloji, 24, 94, 43-48.
Peyrowan, H.R., & Lotfollahzadeh, D. (2016). Principles and application of desert rain simulator in soil erosion research and runoff and sediment production. The first national conference on soil protection and watershed management. Tehran. Iran. (In Persian)
Rahul, D. (2021). To extinguish or not to extinguish: The role of forest fire in nature and soil resilience. Journal of King Saud University – Science 33, 101539
Refahi, H. (2007). Water erosion and its control, Tehran University Publications, 671p. Iran. (In Persian)
Robichaud, P.R., & Brown, R.E. (1999). What happened after the smoke cleared: onsite erosion rates after a wildfire in eastern Oregon. In: Olsen, D.S., Potyondy, J.P. (Eds.), Proceedings Wildland Hydrology Conference, Bozeman, Mt Hernon, Virginia, June. American Water Resource Association, 10(10) 419–426.
Sadeghi, S.Hr., Gholami Gohareh, R., Mirnia, S.Kh. (2010). Analysis of runoff threshold of two pasture treatments. The 6th National Conference on Watershed Science and Engineering and the 4th National Conference on Erosion and Sedimentation. (In Persian)
Samdaliri, H., Jourgholami, M., Salajegheh, A., Abdi, E., & Kooch, Y. (2021). The effect of forest fires on the dynamics of some soil physical, chemical and biological characteristics over time, Iranian Journal of Forest, 13(2), 129-140, https://doi.10.22034/ijf.2021.136935. (In Persian)
Samdaliri, H., Jourgholami, M., Salajegheh, A., Abdi, E., & Kooch, Y. (2021). Effect of fire on runoff quality in forest watersheds (Case study: Kheyrud educational and research forest). Iranian Journal of Forest and Poplar Research, 29(4), 402-411. https:// doi. 10.22092/ijfpr.2022.356906.2031. (In Persian)
Sarah, R., Schmeer, S.K., Kampf Lee, H., MacDonald, J., & Hewitt, C.W. (2018). Empirical models of annual post-fire erosion on mulched and unmulched hillslopes. Elsevier Catena, 163, 276–287. https://doi.org/10.1016/j.catena.2017.12.029.
Shakesby, R.A. (2011). Post-wildfire soil erosion in the Mediterranean: Review and future research directions. Earth-Science Reviews, 105, 71–100.
Stoof, C.R., Vervoort, R., Iwema, J., Elsen, E., Ferreira, A., & Ritsema, C.J. (2012). Hydrological response of a small catchment burned by experimental fire. Hydrology and Earth System Sciences, 16(2) 267-285.
Iranian Journal of Forest
Volume 16, Issue 2 - Serial Number 2
Summer 2024
Pages 257-271

  • Receive Date 12 September 2023
  • Revise Date 27 December 2023
  • Accept Date 31 January 2024