The Role of Biological Windbreak in the Creation of Microclimate in Arid Areas of Dehloran, Ilam

Document Type : Research Paper

Authors

1 M.Sc. of Combat Desertification, Forest, Range and Watershed Management Organization, Ilam, Iran

2 Department of Range and Watershed Management, Faculty of Agriculture, Ilam University, Ilam, Iran

3 Department of Water and Soil Sciences, Faculty of Agriculture, Ilam University, Ilam, Iran

Abstract

 In this study, the ENVI-met Headquarter model was used to design a biological windbreak to control wind erosion, and wind tunnel was used to determine the wind erosion threshold. In order to determine the wind erosion threshold, soil samples were transferred to laboratory and exposed to dry air and transferred to wind tunnel. Then, the wind erosion threshold velocity was measured by adjusting the wind flow velocity and using an anemometer. The data required for simulation with Envi-met model include geographical location of the region, soil texture, average minimum and maximum temperature, average minimum and maximum relative humidity, average maximum wind speed and wind direction. Based on the simulation results, both designed windbreak for the Prosopis juliflora and Haloxylon aphyllum species can create microclimate in region. The wind speed decreased to the wind erosion threshold in the Haloxylon aphyllum species windbreak and less than that in the Prosopis juliflora species windbreak. In general, in the Prosopis juliflora species windbreak temperature in the first and last row of the windbreak was 36.12 and 34.78˚C, respectively. Besides, the lowest relative humidity in the first row was 28.52% and reached to 33.11% in the distance of 8h to 10h behind the first row. On the contrary, inside the Haloxylon aphyllum species windbreak, the temperature in the first row was 34.67˚C and in the last row was up to about 35.21˚C. Moreover, the highest relative humidity in the first and last row was 33.28% and 31%, respectively. Therefore, the designed windbreak for the Prosopis juliflora species can protect the more distance behind the initial windbreak, reduce the wind speed to a longer extent from the initial windbreak, more effectively affect the microclimate of the area, and modify it. Thus, it is recommended as a suitable windbreak for the study area.
Extended Abstract
1-Introduction
Wind erosion is one of the major problems in arid and semi-arid regions which occurs mainly in the areas with rainfall less than 200 mm. Following the erosion of the wind, the area is deserted and degraded. The problem of erosion in the arid and semiarid regions is very important, since the compensation for the eroded soils is impossible and difficult due to the unfavorable conditions and the fragile ecosystem. Among the methods used to combat wind erosion, the construction of live and inert windbreaks is a good place to be considered as an appropriate option to prevent damage caused by wind erosion to biological and economic resources. The construction of windbreaks has many positive effects on environmental factors, including the advantages of the Windbreak on the temperature of the soil, air humidity and soil, snow accumulation, evaporation rate, carbon dioxide accumulation, etc. Therefore, considering that Dehloran city has a critical center of wind erosion and is also exposed to dust due to its proximity to Iraq, the current study aims to draw a biological windbreak and figure out its role on the microclimate of the study area investigated using the ENVI-met Headquarter model, which is one of the micro-climatic simulation models of urban climate.
2-Materials and Methods
After a detailed visit and the identification of the area, sampling was carried out at the depth of 0-3 cm in three replications. In this study, the threshold wind velocity for erosion was determined using a wind tunnel machine in Ilam University Lab. In order to determine the threshold wind velocity for Erosion, soil samples were exposed to the air in a dry tunnel after being transferred to the laboratory in a wind tunnel. Then, the threshold wind velocity for Erosion was measured with acceptable accuracy by adjusting the wind speed and using the Manometer. The ENVI-met Head quarter was also used to design a biological windbreak. This model calculates the weather conditions (temperature, wind, humidity) at different levels of the domain and the range of effects (buildings, types of vegetation, types of permeable and impenetrable surfaces). Therefore, the most commonly used and used seedlings in sand dunes SStabilization, two Prosopis juliflora and Haloxylon aphyllum species, which are most used in sandy stabilization and flooding projects in the study area, were selected for simulation. The preliminary data required for the implementation of the model is based on the geographical location of the study area, including latitude, longitude, soil texture, air temperature conditions, velocity, wind direction and relative humidity. After implementation of the model, the outputs of the model were prepared and analyzed using Leonardo software.
3-Results and Discussion
Based on the results of Table 3, mean Threshold Velocity for Wind Erosion in the study area is 4.84 m/s. According to the simulation results, both designed Windbreak for the Prosopis juliflora and Haloxylon aphyllum species could lead to the formation of microclimate in region, so that the wind speed has dropped around the wind erosion threshold in the Haloxylon aphyllum species Windbreak and less than that in the Prosopis juliflora species Windbreak. In the Prosopis juliflora Windbreak, the region temperature in the first row of the Windbreak is 36.12 ˚C and in the last row of the Windbreak is reduced to 34.78 ˚C. The relative humidity of the area in the first row of the Windbreak was 28.52%, and of the last row reached 32.55%. On the contrary, in the Haloxylon aphyllum Windbreak, the temperature of the region in the first row of the Windbreak was 34.67 ˚C, but in the last row of the Windbreak increased about 35.21 ˚C, although the relative humidity of the area in the first row of the Windbreak was 33.28% and decreased to 31% in the last row. However, at the end, it can be said that designed windbreak for the Prosopis juliflora species can protect more distance behind the initial windbreak, reduce the wind speed to a longer extent from the initial windbreak, more effectively affect the microclimate of the area, and modify it. Based on the results, it can be said that the changes in temperature and relative humidity in the Prosopis juliflora contrary is a Haloxylon aphyllum species. This difference seems to be due to how the wind velocity changes in the two windbreak, which is the speed change itself to the height of both windbreak, because the higher the wind speed, the lower the wind speed. Therefore, in a Prosopis juliflora windbreak, with a further reduction in wind speed and air turbulence in the vicinity of the surface of the soil and the creation of shadows, there is a region with relatively moderate, relatively low temperatures. As a result, with decreasing air temperature, the amount of evaporation decreases and consequently the amount of moisture increases.
4-Conclusion
Considering that all three factors of wind speed decrease, temperature decrease and humidity increase can reduce evaporation from the water surface. Therefore, in addition to reducing wind erosion in sand dunes and road sides, Prosopis juliflora species can be used as a suitable type for windbreak construction in order to reduce the evaporation from very limited water resources located in the windy region.

Keywords

References

References
Ahmadi, H., Nazari Samani, A. A., Ekhtesasi, M. R., Moghimi-Nejad, F. & Hossein Abadi, M. (2012). The Effects of Urban and Industrial Development (Technogenic Desertification) in the desertification (Case Study: Eastern Region of Esfahan Province). Journal of Environmental Erosion Research, 2 (1), 63-77 (in Persian).
Akbarian, M. & Nohegar, A. (2014). Evaluation of the effect of afforestation on decreasing wind erosion in the Jask Range. Geographic Quarterly, 29 (3), 179-190 (in Persian).
Ameri, F, Khanamani, A. & Karimzadeh, H. R. (2010). The Effect of Local Climate Change Depending on the Ecological Situation of Agriculture and Range Lands (Case Study: Ardestan City, Isfahan Province). Proceedings of the 4th Conference Paper on Climate Change, 515-520 (in Persian).
Arazi, A., Emtahani, M. H., Ekhtesasi, M. R. & Sodaeezadeh, H. (2014). Effect of Tamarix aphylla as tree windbreak on salinity soil agriculture lands in dry region (case study: Ardakan). Watershed Management Research (Pajouhesh & Sazandegi), 26 (2), 53-59 (in Persian).
Arazi, A., Emtahani, M. H., Ekhtesasi, M. R. & Sodaeezadeh, H. (2011). Effect of tree windbreak on agriculture products in dry region. The second national conference of wind erosion and dust storms, Iran, Yazd (in Persian).
Bruse, M. (2009). ENVI-met Website Retrierd from http://www. Envi-met. Com.
California Department of Food & Agricultural (2000). A brief paper for the Government of the India, State governments and concerned ministries, Prosopis juliflora, the tree of the poor. Department for International Development (DFID), 1-2.
Campi, P., Palumbo, A. D. & Mastrorilli, M. (2009). Effects of tree windbreak on microclimate and wheat productivity in a Mediterranean environment. European Journal of Agronomy, 30 (3), 220-227.
Cook, G. D. & Goyens, C. M. (2008). The impact of wind on trees in Australian tropical savannas: lessons from Cyclone Monica. Austral Ecology, 33 (4), 462-470.‏
Foereid, B., Bro, R., Mogensen, V. O. & Porter, J. R. (2002). Effects of windbreak strips of willow coppice—modelling and field experiment on barley in Denmark. Agriculture, ecosystems & environment, 93 (1-3), 25-32.‏
Fryrear, D. W. (1995). Soil losses by wind erosion. Soil Science Society of America Journal, 59 (3), 668-672.‏
He, Z., Li, S. & Harazono, Y. (1997). Wind-sandy environment and the effects of vegetation on wind breaking and dune fixation in Horqin sandy land, China. In Proceedings of Wind Erosion: An International Symposium/Workshop. USDA Agricultural Research Service, Wind Erosion Laboratory, Manhattan, KS.‏
Ilam Meteorological Organization (2020). Weather and climatology reports (in Persian).
Jan mohammadi, R. & Molayynia, M. R. (2017a). The Effect of Eucalyptus Windbreak on changes in Wind Speed, Temperature and humidity. The First International Conference on Modern Advances in Civil Engineering, Amol, North University (in Persian).
Jan Mohammadi, R. & Molayynia, M. R. (2017b). The effect of tamarix Windbreak on changes in wind speed, temperature and humidity, The First International Conference on Modern Advances in Civil Engineering, Amol, North University (in Persian).
Jarrah, M., Mayel, S., Tatarko, J., Funk, R. & Kuka, K. (2020). A review of wind erosion models: data requirements, processes, and validity. Catena, 187, 104388.‏
Kamali Maskoni, E., Amiri & Ekhtesasi, M. R. (2011). A comparative study of the effects of mud wall windbreaks and date palms on wind speed changes case study Jiroft region, The Second National Conference of Wind Erosion and Dust Storms, Iran, Yazd (in Persian).
Kučera, J., Podhrázská, J., Karásek, P. & Papaj, V. (2020). The Effect of Windbreak Parameters on the Wind Erosion Risk Assessment in Agricultural Landscape. Journal of Ecological Engineering, 21 (2), 150-156.
Lampartová, I., Schneider, J., Vyskot, I., Rajnoch, M. & Litschmann, T. (2015). Impact of protective shelterbelt microclimate characteristics. Ekológia (Bratislava), 34 (2), 101-110.‏
Madadi zadeh, N., Amiri, I, Faryabi, N. & Tekluzadeh, A. M. (2014). Comparison of Biological Windbreak Distance in Different Methods of Implementation (Case Study: South of Kerman Province). Conference on Agricultural and Environmental Sciences, Shiraz (in Persian).
Mirhasani, M., Rostami, N., Bazgir, M. & Tavakoli, M. (2019). Living windbreak design for wind erosion control in arid regions: A case study in Dehloran, Iran. Desert, 24 (1), 33-42.‏
Mirhasani. M. (2017). Study of Threshold Velocity for Wind Erosion in Different Land Uses Using Wind Tunnel (Case Study: Eyn- Khowsh, Dehloran, Ilam). Master of Science Thesis, Ilam University (in Persian).
Peri, P. L. & Bloomberg, M. (2002). Windbreaks in southern Patagonia, Argentina: A review of research on growth models, windspeed reduction, and effects oncrops. Agroforestry Systems, 56 (2), 129-144.‏
Refahi, H. Gh. (2012). Wind Erosion and conservation. 6th Edition Tehran: Tehran University (in Persian).
Rezazadeh, R. & Aghajan Biglou, E. (2012). Proposed Model for Massage in Rawty Residential Components, Biannual Journal of the University of Art, 4 (7), (in Persian).
Saffai ghahnouyeh, A. R., Babakhani, S. & Karimzadeh, H. R. (2010). Introduction of Effective Plant Species on Wind Erosion Control, 2nd National Conference on Wind Erosion and Dust Hurricanes, Yazd(in Persian).
Sedaghat, M. (1979). Exterior Processes of Land Formation; Geology Lesson. Volume 2. Tehran: Iran Azad University(in Persian).
Shamsutdinov, Z. S., Ubaydullaev, S. R., Shamsutdinov, N. Z. & Zanzheev, V. V. (2016). Environment-forming role of black saxaul, Haloxylon aphyllum (Minkw.) Iljin in the Karnabchul Desert. Russian journal of ecology, 47 (1), 39-45.‏
Takht Abnoci, Gh. (1994). Forestry in Arid Regions (Translation). Examine the Research Center for Rural Issues Ministry of Jihad.
Uranov, A. A. (1965). Fitogennoe Pole (in Russian) (The phytogenic field). In: Lavrenko EM (Ed.) problem sovremennoj botaniki, vol 1. Naoka, Moscow, 251-254.
Vice President of Strategic Planning and Control (2015). Criteria and Principals for the construction of a biological windbreak. (658) (in Persian).
Yukhnovskyi, V., Polishchuk, O., Lobchenko, G., Khryk, V. & Levandovska, S. (2020). Aerodynamic properties of windbreaks of various designs formed by thinning in central Ukraine. Agroforestry Systems, 1-11.‏

Files

Share

How to cite

Statistics