میزان تخصیص منابع در اندام‏های مختلف گونه‏های درمنه (Artemisia spp.) در دامنۀ جنوب شرقی سبلان

نوع مقاله : مقاله پژوهشی

نویسندگان

1 استاد پژوهش، گروه منابع طبیعی دانشکده کشاورزی و منابع طبیعی دانشگاه محقق اردبیلی، اردبیل، ایران

2 دانش‌آموخته کارشناسی ارشد، گروه منابع طبیعی دانشکده کشاورزی و منابع طبیعی دانشگاه محقق اردبیلی، اردبیل، ایران

3 گروه منابع طبیعی دانشکده کشاورزی و منابع طبیعی دانشگاه محقق اردبیلی، اردبیل، ایران

4 مؤسسه تحقیقات جنگلها و مراتع کشور، سازمان تحقیقات، آموزش و ترویج کشاورزی، تهران، ایران

‎10.22052/deej.2024.255052.1058

چکیده

گونه‌‌های درمنه به‌‌دلیل توانایی منحصربه‌‌فرد خود در تخصیص منابع به اندام‌های دیگر برای حفظ بقا، مقاومت خوبی در برابر چرای دام دارند. ازاین‌رو، با توجه به نقش کلیدی آن‌ها در ترکیب گیاهی رویشگاه‌‌های مرتعی و کاربردهای دارویی و خوراکی آن‌ها، در این پژوهش، توزیع منابع در اندام‌های هوایی و زیرزمینی چهار گونه درمنه شامل Artemisia fragrans، Artemisia Aucheri، Artemisia austriaca و Artemisia melanolepis در دامنۀ جنوب شرقی سبلان، در فصل رویش سال 1393 مورد بررسی قرار گرفت. به‌منظور برآورد تولید کل و سهم گونۀ مورد نظر، در مرحلۀ اول در هر سایت 10 پلات 1 مترمربعی به‌صورت تصادفی در امتداد ترانسکت‌ها مستقر گردید. در مرحلۀ دوم، برای بررسی تخصیص منابع اندام‌های گیاهی، سه ترانسکت به‌صورت تصادفی به ترانسکت‌های مرحلۀ اول در هر سایت اضافه شد و نمونه‌ها به‌صورت تصادفی-سیستماتیک در امتداد ترانسکت‌ها جمع‌آوری شدند. برای تعیین رابطه بین پارامترهای طول ریشه، ارتفاع هوایی، وزن ریشه و بیوماس هوایی از روش‌های تحلیل همبستگی استفاده شد. یافته‌ها نشان‌دهندۀ وجود ارتباط معنی‌داری بین متغیرهای مورد بررسی (P<0.01) بود. برای مقایسۀ میانگین طول و وزن اندام‌های گیاهی در شرایط مختلف مرتعی از آزمون‌های واریانس و دانکن استفاده شد. نتایج حاصل از این بررسی، بیانگر وجود تفاوت معنی‌داری بین شرایط مختلف مرتعی (P<0.01) بود. همچنین نتایج نشان داد که بیشترین طول و وزن ریشه و اندام‌های هوایی در گیاهان مربوط به شرایط مطلوب مرتعی و کمترین آن در شرایط نامطلوب مرتعی مشاهده می‌شود.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Resource Allocation in Different Organs of Artemisia species distributed on Southeastern Facing Slopes of Sabalan

نویسندگان [English]

  • Farshad Keivan-behjou 1
  • Solmaz Firouzpour 2
  • Ardavan Gorbani 3
  • Ehsan Zandi Esfahan 4
  • Maryam Masoum Tamimi 4
1 Department of Forest Sciences and Engineering, Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran
2 M.Sc. Graduated student in Silviculture and Forest ecology, Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran
3 Department of Forest Sciences and Engineering, Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran
4 Rangeland Research Division, Research Institute of Forests and Rangelands, Agricultural Research, Education and Extension Organization (AREEO), Tehran, Iran
چکیده [English]

Introduction:  This research was done with the aim of determination of Resource Allocation in Different Organs of Artemisia species distributed on Southeastern Facing Slopes of Sabalan. Iran's rangelands, with an area of 84.8 million hectares, are considered one of the largest vital areas in the country, more than 70% of which are located in arid and semi-arid areas. These areas with Artemisia and Astragalus vegetation comprise about 46% of the country's area. They are essential in preserving the environment, especially preventing soil erosion and providing fodder for livestock and wildlife. In the face of grazing pressure, Artemisia spp., by allocating resources to other organs, can recover themselves, maintain, and survive in rangelands; for this reason, these species have a particular priority in rangelands. Four species, Artemisia fragransArtemisia Aucheri, Artemisia austriaca, and Ar. Melanolepis were selected for this study because of their importance in rangelands, medicinal and fodder value, and different species on the southeastern slopes of Sablan. Determining the effect of altitude above sea level, range condition, and soil parameters on resource allocation rates in different organs of the study species and comparing resource allocation in these species are the main goals of this research.
 
Materials and methods: This research investigated the resource allocation rates in the shoots and roots of Artemisia fragrans, Ar. Aucheri, Ar. austriaca, and Ar. Melanolepis in Sablan's southeast rangelands. The studied area is located on Sablan's southeast slope, with geographical coordinates of 47'52 to 47'55 east longitude and 38'00 to 12'38 north latitude. It is between 1800 and 3200 meters above sea level. According to DeMarton's classification, the average annual rainfall is 414.5 mm, and the average annual temperature is 7.8 degrees Celsius. This region has 160 freezing days, and its climate is cold semi-arid. Plant samples were collected from three sites under light, medium, and heavy grazing through field visits and the four-factor method.  Vegetation sampling was done in two stages between July and September 2013, systematically and randomly (regarding species presence) according to the access road and rangelands area of the study sites. Soil sampling was also done using a random-systematic method. Three intact soil samples (12 samples) were prepared at 0-30 cm depth along transect in each site.
 
Results: According to the obtained data, Ar. fragrans grows at an altitude of 1800 to 1900 meters, Ar. Aucheri at 2000 to 2300 meters, Ar. austriaca at 2900 to 3000 meters, and Ar. melanolepis grows at an altitude of 3000 to 3200 meters above sea level. No significant difference was observed for the interaction effect of grazing intensity and the studied altitude range on the shoot and root biomass of the species. Soil samples from the habitats of the studied species were compared, and pH, K, OC, silt, and sand showed significant differences. pH, K, silt, and sand were significant at 1% and OC at 5%. The grazing intensity also affected potassium, organic carbon, and soil silt content. The values of pH, EC, P, sand and clay parameters did not show significant differences under different intensities. The type of plant species also influenced EC, potassium, organic carbon, silt, sand and clay. The Pearson correlation test showed a correlation between potassium and shoot biomass. Soil acidity, silt, and sand also affected the amount of root biomass. Artemisia fragrans production was estimated at 952.10, 554.70, and 407.80 kg per hectare under light, medium, and heavy grazing conditions, respectively. Artemisia Aucheri's production was estimated at 874.90, 429.60, and 238.55 kg per hectare under light, medium, and heavy grazing, respectively. In the case of Artemisia melanolepis, 915.30, 421.1, and 275.50 kg per hectare were estimated production values under light, medium, and heavy grazing conditions, respectively. Artemisia austriaca production was estimated at 877.5, 459.3, and 345.3 kg ha-1, respectively. Generally, the highest root weight and length and the highest shoot weight and length were observed under light grazing. For all four studied species, the lowest values were observed under heavy grazing. Also, there was a significant correlation between root weight and root length and between shoot weight and shoot length in all four studied species. Moreover, a significant correlation was found between root length and shoot length and between shoot biomass and root weight in all four studied species.
 
Discussion and Conclusion: Based on the results of this study and considering the altitudinal range defined for each species, altitude does not significantly affect species resource allocation. The highest value for the biomass of different plant organs was in low-intensity grazing, and the lowest was in high-intensity grazing. Therefore, the less degraded the rangeland, the more resources will be allocated by the existing plant species to their organs. Heavy grazing can lead to the loss of key forage species and a decrease in their aboveground plant biomass, while light grazing can improve conditions for their growth. Plant species also play a role in resource allocation patterns. Resource allocation among different organs of a species varies, and ultimately, soil characteristics determine the presence of specific species in a region. Each plant species grows and establishes itself in soils that are compatible with it. Additionally, property K significantly impacted the allocation of aboveground resources, while soil properties pH, silt, and sand significantly impacted the allocation of belowground resources. Environmental variables, pivotal in plant establishment and distribution, can either enhance or deteriorate rangelands. However, by implementing sound rangeland management practices like controlling grazing intensity and duration, we can effectively curb the adverse effects of these factors on plant communities and rangelands in general.

کلیدواژه‌ها [English]

  • Resource Allocation
  • Range Condition
  • Ar. Aucheri
  • Ar. Austriaca
  • Artemisia Fragrans And Ar. Melanolepis

مراجع

  1. Abd El-Ghani, M., & Amer, W.M. (2003). Soil-vegetation relationships in a coastal desert plain of southern Sinai, Egypt. Journal of Arid Environment 55(4), 607-628.
  2. Abrahamson, W.G. & Caswell, H. (1982). On the comparative allocation of biomass, energy and nutrients in plants. Ecology, 63, 982-991.
  3. Akbarlou, M., Sheidaee, A. & Ehsani, S. (2013). Investigating the effect of different grazing intensities on aerial and underground biomass and structural characteristics of 3 species of wheatgrass Bromus tomentellus, Stipa barbata and Festuca ovina in Chaharbagh mountain meadows of Golestan province. Journal Management System, 3, 186-197. (In Persian)
  4. Alidoost, S., Akbarloo, M. & Amirkhani, M. (2013). Reactions of Festuca ovina L underground organs to different grazing intensities (case study: Ghorkhod region of North Khorasan province). Journal of Plant Ecosystem Conservation, 1(2), 81-93. (In Persian)
  5. Angassa, A. & Oba, G. (2010). Effects of grazing pressure, age of enclosures and seasonality on bush cover dynamics and vegetation composition in southern Ethiopia. Journal of Arid Environments, 74, 111–120.
  6. Ansley, R.J. & Castellano, M.J., 2007. Texas winter grass and buffalo grass response to seasonal fires and clipping. Rangeland Ecology and Management, 60, 154-164.
  7. Arzani, H., Mehrabi, A., Nikkhah, A. & Fazel Dehkordi, L., 2007. The minimum rangeland area required for pastoralism in Semnan province. Pajouhesh & Sazandegi, 74, 107-113. (In Persian)
  8. Azarnivand, H., 1992. Investigation of soil and plant cover in relationship within geomorphologic units in Damghan city. Proceeding Seminar of Investigation of Desert and Arid Zones of Iran.
  9. Azarnivand, H., Jafari, M., Moghadam, M., Jalili, A. & Zare Chahouki, M. (2002). Investigating the effect of soil properties and altitude changes on the distribution of two Artemisia species, a case study: the pastures of Wardvard region. Garmsar and Semnan. Iranian Journal of Natural Resources, 56(1-2), 93-100. (In Persian)
  10. Keivan Behjou, F. & Yarmohammadi, K. (2020). Biodiversity and ecosystem with emphasis on sustainability. ACECR publication, Ardebil. (In persian)
  11. Carvalho, I.S., Cavaco, T. & Brodelius, M. (2011). Phenolic composition and antioxidant capacity of six Artemisia species. Industrial Crops and Products, 33(2), 382-388.
  12. Enright, N.J., Miller, B.P. & Akhter, R. (2005). Desert vegetation and vegetation-environment relationships in Kirthar national park, Sindh, Pakistan. Journal of Arid Environment, 61, 397-418.
  13. Fenner, M. (1986). A bioassay to determine the limiting minerals for seeds from nutrient-deprived senecio vulgaris plants. Journal of Ecology, 74, 497-505.
  14. Ghahraman, A. (2008). Cormophytes of Iran (Plant Systematics). IUP Publication, Tehran. (In Persian)
  15. Ghorbani, A. (2013). Textbook of Quantitative Plant Ecology, Pasture Management PhD Course, Department of Pasture and Watershed Management, Mohaghegh Ardabili University. (In Persian)
  16. Griffiths, R.P., Madritch, M.D. & Swansona, A.K. (2009). The effects of topography on forest soil characteristics in the Oregon Cascade Mountains (USA): Implications for the effects of climate change on soil properties. Forest Ecology Management, 257, 1-7.
  17. Guodong, H., Xiying, H., Mengli, Zh. & Mingju, (2008). Effect of grazing intensity on carbon and nitrogen in soil and vegetation in a meadow steppe in Inner Mongolia. Journal of Agriculture, Ecosystems and Environment, 125, 21–32.
  18. Ismaili, M., Kheirfam, H., Deylam, M., Akbarlou, M. & Sabouri, H. (2010). Investigating the effects of cutting on the amount of production of two pasture species Agropyron elongatum and Festuca ovina. Journal of Rangeland, 1, 72-81. (In Persian)
  19. Joneidi Jafari, H., Azarnivand, H.m Zare Chahouki, M. & Jafari, M. (2013). Study of aboveground and below ground biomass of Artemisia sieberi shrublands with different grazing intensities in Semnan /province- Iran. Watershed Management Research (Pajouhesh & Sazandegi), 99, 33-41. (In Persian)
  20. Kazemi, M., Tafreshi, N., & Abdul Hosseini, S. (2009). Investigation of the chemical composition of the essential oil of Artemisia austriaca plant from Iran. National Conference of New Chemistry Findings in Industry and Medicine. Islamic Azad University, Shahr Ray Branch, March 4, 2009, 6p. (In Persian)
  21. Khalasi Ahwazai, L., Zare Chahouki, A. & Hosseini, Z. (2015). Modeling geographic distribution of Artemisia sieberi and Artemisia aucheri using presence-only modelling methods (MAXENT & ENFA). Journal of Renewable Natural Resources Research, 6(1), 57-73. (In Persian)
  22. Kurschner, H. (2004). Phytosociological studies in the Alashan Gobi-A contribution to the flora and vegetation of lnner Mongolia (NW China). Phitocoenologia, 34(2), 169-224.
  23. Lee, W.G., & Fenner, M. (1989). Mineral nutrient allocation in seeds and shoots of 12 chionochloa species in relation to soil fertility. Journal of Ecology, 77, 704-16.
  24. Liu, H., Zang, R. & Chen, H.Y.H. (2016). Effects of grazing on photosynthetic features and soil respiration of rangelands in the Tianshan Mountains of Northwest China. Nature, Scientific reports, 6, 30087.
  25. Mashkuri, L. (2014). Investigating the effect of different intensities of grazing on Festuca ovina and Alopecurus textilis species in the northern pastures of Sablan. MS.c. thesis, Mohaghegh Ardabili University, Ardabil. (In Persian)
  26. Mesadaghi, M. (2007). Pasture in Iran. Astan Quds Razavi Publishing, Mashhad. (In Persian)
  27. Moghaddam, M. (2007). Range and Rangemanagement. Tehran University Press. (In Persian)
  28. Mohammad-Esmaeili, M., Bonis, A., Bouzillé, J.B., Mony, C., & Benot, M.L. (2009). Consequence of ramet defoliation on plant clonal propagation and biomass allocation: example of five rhizomatous grassland species. Flora, 204, 25-33.
  29. Nazari Anbaran, F. (2014). Investigating the composition and diversity of pasture species in the northern slopes of Sablan. MS.c. thesis, Mohaghegh Ardabili University, Ardabil. (In Persian)
  30. Negahban, M., Moharramipour, S. & Sefidkon, F. (2007). Fumigant toxicity of essential oil from Artemisia sieberi Besser against three stored- product insects. Journal of Stored Products Research, 43(2), 123-128.
  31. Rechinger, K.H. (1963-1999). Flora Iranica. Vien: Akademische Druck and Veragsatalt publication.
  32. Saadatfar, A., Barani, H. & Mesadaghi, M. (2007). Review and comparison of 8 distance measurement methods of density in Bardsir-Sirjan grasslands. Journal of Agricultural Sciences and Natural Resources, 4(1), 183-192. (In Persian)
  33. Shokrollahi, Sh., Moradi, H. & Dianati Tilaki, Gh. (2013). Effects of soil properties and physiographic factors on vegetation cover (Case study: Polur Summer Rangelands). Iranian Journal of Range and Desert Research, 19(4), 655-668. (In Persian)
  34. Snyman, H.A. (2005). Rangeland degradation in a semi-arid South Africa: influence on seasonal root distribution, root/shoot ratios and water-use efficiency, 60, 457-481.
  35. Solon, J., Degorski, M. & Roo-Zielinska, E. (2007). Vegetation response to a topographical-soil gradient. Journal of Catena, 71, 309-320.
  36. Vahabi, M.R., Isfahani, M.T., Farhang, H.R. & Salehi, A. (2018). The investigation of the flora, life forms and chorotypes of the plants in the Sheida Protected Area Chaharmahal Bakhtiari Province, Iran. Journal of Plant Research, 31(2) 463-482.
  37. Van Wijnen, H.J., Van der Wal, R. & Bakker, J.P., (1999). The impact of herbivores on nitrogen mineralization rate: Conse-quences for salt-marsh succession. Oecologia 118, 225–231
  38. Watson, L.E., Bates, P.L., Evans, T.M., Unwin, M.M. & Estes, J.R. (2002). Molecular phylogeny of subtribe artemisinae (Asteraceae), including Artemisia and its allied and segregate genera. BMC Evolutionary Biology, 2, 2-17.
  39. Winther, F.P. (2005). Effects of cutting frequency on plant production, N-uptake and N2 fixation in above- and below-ground plant biomass of perennial ryegrass–white clover swards. Grass and Forage Science, 61, 154-163.
  40. Zare Hesari, B., Ghorbani, A., Azimi-Moallem, F., Hashemi Majd, K. & Asghari, A. (2014). Ecological factors affecting the distribution of Artemisia fragrans species in the southeastern slopes of Sablan. Journal of Rangeland 3, 238-250. (In Persian)
مهندسی اکوسیستم بیابان
دوره 12، شماره 41
مهر 1403
صفحه 33-48

فایل ها

هم رسانی

ارجاع به این مقاله

آمار