زی‌توده، اندوختۀ کربن و شاخص سطح برگ درختان کیکم (Acer monspessulanum L.) در جنگل‌های ایلام

مهدوی, علی; یعقوبی, روح‌الله; امیدی, مهدی; ناجی, حمیدرضا

doi:10.22034/ijf.2024.396505.1926

زی‌توده، اندوختۀ کربن و شاخص سطح برگ درختان کیکم (Acer monspessulanum L.) در جنگل‌های ایلام

نوع مقاله : مقاله پژوهشی

نویسندگان

علی مهدوی ¹

روح‌الله یعقوبی ²

مهدی امیدی ³

حمیدرضا ناجی ⁴

¹ استاد گروه علوم جنگل، دانشکدۀ کشاورزی، دانشگاه ایلام، ایلام، ایران.

² کارشناسی ارشد جنگل‌داری، گروه علوم جنگل، دانشکدۀ کشاورزی، دانشگاه ایلام، ایلام، ایران.

³ استادیار گروه آمار و ریاضی، دانشکدۀ علوم پایه، دانشگاه ایلام، ایلام، ایران.

⁴ دانشیار گروه علوم جنگل، دانشکدۀ کشاورزی، دانشگاه ایلام، ایلام، ایران.

10.22034/ijf.2024.396505.1926

چکیده

مقدمه: این پژوهش با هدف اندازه‌گیری و برآورد مقدار زی‌توده، ترسیب کربن و شاخص سطح برگ درختان کیکم (Acer monspessulanum L.) در سه محدوده از منطقۀ حفاظت‌شدۀ مانشت و قلارنگ در جنگل‌های شهرستان سیروان در استان ایلام انجام گرفت.
مواد و روش‌ها: با استفاده از روش نمونه‌برداری تصادفی، 20 درخت از هر محدوده (در مجموع 60 اصله) گزینش شده و فاکتورهای کمّی آنها شامل قطر بزرگ و کوچک تاج، ارتفاع درخت، طول تاج و قطر یقه اندازه‌گیری شد. سپس برگ‌های یک‌چهارم تا یک‌هشتم تاج به نسبت بزرگی و کوچکی تاج درختان نمونه جمع‌آوری شد. پس از خشک کردن در داخل آون، وزن خشک برگ‌ها و پس از سوزاندن مقدار کافی از برگ‌های خشک‌شده در کوره الکتریکی، وزن مواد آلی و ضریب کربن برگ‌ها (47/0) به ‌دست آمد. برای محاسبۀ شاخص سطح برگ از روش وزنی و برای تعمیم نتایج به‌دست‌آمده از درختان نمونه به کل جنگل از روش درخت متوسط استفاده شد.
نتایج: براساس نتایج، متوسط زی‌تودۀ برگ، متوسط ذخیرۀ کربن برگ و متوسط مقدار جذب دی‌اکسید کربن از جو در منطقۀ قلارنگ 28/221، 68،/103، 50/380؛ در منطقۀ مانشت 92/199، 38/100، 34/368 و در منطقۀ میان‌تنگ 32/186، 38/87، 68/320 کیلوگرم در هکتار برآورد شد. متوسط شاخص سطح برگ کیکم برای هر درخت نیز 52/1 و در هکتار 119/0 محاسبه شد. ارزش اقتصادی ترسیب کربن در برگ درختان کیکم 045/21 دلار در هکتار محاسبه شد که معادل 10522500 ریال برآورد می‌شود.
نتیجه‌گیری: تفاوت در متغیرهای بررسی‌شدۀ کیکم در سه منطقۀ مدنظر ممکن است به‌علت تفاوت در تراکم توده، مراحل توالی و اندازۀ درختان و نیز اقدامات مدیریتی اعمال‌شده یا شرایط متفاوت تخریب باشد.

کلیدواژه‌ها

ترسیب کربن

روش درخت متوسط

شاخص سطح برگ

کیکم

مانشت و قلارنگ

موضوعات

زیست سنجی جنگل

عنوان مقاله English

Leaf biomass, Carbon storage and Leaf Area Index of Montpellier maple (Acer monspessulanum L.) in Ilam forests

نویسندگان English

A Mahdavi ¹

R. Yaghobi ²

M Omidi ³

H.R Naji ⁴

¹ Prof., Dept. Forest Sciences, Faculty of Agriculture, Ilam University, Ilam, I.R. Iran.

² MSc. in Forestry, Dept. Forest Sciences, Faculty of Agriculture, Ilam University, Ilam, I.R. Iran.

³ Assistant Prof., Dept. Statistics and Mathematics, Faculty of Basic Sciences, Ilam University, Ilam, I.R. Iran

⁴ Associate Prof., Dept. Forest Sciences, Faculty of Agriculture, Ilam University, Ilam, I.R. Iran.

چکیده English

Introduction: This research was carried out to measure and estimate the amount of leaf biomass, carbon sequestration, and leaf area index of Montpellier maple (Acer monspessulanum L.) trees in three regions of Manesht and Qalarang protected areas of in the forests of Sirvan County located in Ilam province.
Materials and Methods: Using the random sampling method, 20 tree samples were selected from each region (60 trees in total) and their quantitative factors including the large and small diameter of the crown, tree height, crown length and collar diameter of the target trees were measured. Then, the leaves of one-fourth to one-eighth of the crown area of the sample trees were collected. After drying in the oven, the dry weight of the leaves was weighed. The weight of organic matter and carbon content of the leaves (0.47) were obtained, after burning sufficient dried leaves in an electric oven. The weight method was used to calculate the leaf area index. In addition, to generalize the results obtained from the sample trees to the whole forest, the mean tree method was used.
Results: The results showed that the average leaf biomass, average leaf carbon storage, and average amount of carbon dioxide absorption from the atmosphere were 221.28, 103.68, 380.50 (kg/ha) in Qalarang, 199.92, 100.38, 368.34 (kg/ha) in Manesht, and 186.32, 87.38, 320.68 (kg/ha) for MianTang, respectively. The average leaf area index of A. monspessulanum was estimated 1.52 for each tree and 0.119 per hectare in the study areas . Additionally, the economic value of the carbon sequestered in the leaves of A. monspessulanum was 21.045 dollars per hectare, which is estimated to be equivalent to 10522500 rials.
Conclusion: In general, the difference in the investigated variables of A. monspessulanum species in the three study areas can be due to the difference in density per hectare of the species, the difference in the succession stages and the size of the trees in these areas, as well as the applied management strategies or the different degradation conditions in study areas.

کلیدواژه‌ها English

Acer monspessulanum L

Carbon sequestration

Leaf area index

Mean Tree Method

Manesht and Qalarang

Adl, H.R. (2007). Estimation of leaf biomass and leaf area index of two major species in Yasuj forests. Iranian Journal of Forest and Poplar Research, 15(4), 417-426. (In Persian)

Akbari, M. (2021). Estimation of leaf biomass and leaf area index of Crataegus aronia in forests of Ilam. MSc thesis. Dept. Forest Sciences, Ilam University. 88 p. (In Persian)

Alinejadi, S., Basiri, R., TahmasbiKohyani, P., Askari, Y., & Moradi, M. (2016). Estimation of biomass and carbon sequestration in various forms of Quercus brantii Lindl. stands in Balout Boland, Dehdez. Iranian Journal of Forest, 8(2), 129-139. (In Persian)

Askarii, Y., Iranmanesh, Y., & Pourhashemi, M. (2021). The economic value and comparison of carbon storage in different forest areas in Kohgiluyeh and Boyer-Ahmad province. Iranian Journal of Forest, 13(2), 169-182. (In Persian)

Attarod, P., Miri, S., Shirvany, A., & Bayramnejad, V. (2018). Variations in Leaf Area Index of Quercus brantii trees in response to changing climate. Journal of Agriculture Science and Technology, 20(7), 1417-1429. (In Persian)

Brooks, R. (1998). Carbon Sequestration, what's that? UI Extension Forestry Information Series. Forest Management, 32, 2.

Cole, T.G., & Ewel, J.J. (2006). Allometric equations for four valuable tropical tree species. Forest Ecology and Management, 229, 351-360.

Darvishnia, H., Dehghani kazemi, M., Forghani, A.H., &Kavyanifard, A.A. (2012). Study and introduction of the flora of Manshet and Qalarang protected areas in Ilam province. Taxonomy and biosystematics, 11(4), 47-60.

Dufrêne, E., & Bréda, N. (1995). Estimation of deciduous forest leaf area index using direct and indirect methods. Oecologia, 104, 156–162. https://doi.org/10.1007/BF00328580

Environmental science activities for the 21st century (ESA21). (2008). Trees and carbon, 13pp.

Fang, S., Xue J., & Tang, L. (2007). Biomass production and carbon sequestration potential in poplar plantations with different management patterns. Journal of Environmental Management, 85, 672-679.

FAO (2010). Global forest resource assessment. Rome.

Fasth, B.G., Harmon, M.E., Sexton, J., & White, P. (2011). Decomposition of fine woody debris in a deciduous forest in North Carolina. The Journal of the Torrey Botanical Society, 138(2), 192-206

Hakkila, P. (1989). Utilization of residual forest biomass. In Utilization of residual forest biomass. Springer, Berlin, Heidelberg. 352-477p.

Husch, B., Beers T.W., & Kershaw, J.A. (2003). Forest mensuration. Fourth Edition. John Wiley & Sons Inc, 443p.

Intergovernmental Panel on Climate Change (IPCC). (2003). Good practice guidance for land use, land-use change and forestry. Institute for Global Environmental Strategies (IGES), Hayama, Japan, 599p.

Intergovernmental Panel on Climate Change (IPCC). (2006). Guidelines for National Greenhouse Gas Inventories. General guidance and reporting. Institute for Global Environmental Strategies (IGES), Hayama, Japan, 1, 309.

Jonckheere, I., Fleck, S., Nackaerts, K., Muys, B., Coppin, P., Weiss, M., & Baret, F. (2004). Review of methods for in situ leaf area index determination. Part I: Theories, sensors and hemispherical photography. Agricultural and Forest Meteorology, 121(1-2), 19–35.

Kahyani, S., Sohrabi, H., Hosseini, S.M., & Vanclay, J. (2016). LAI and leaf biomass allometric equations for three common tree species in a Hyrcanian temperate forest. Open Journal of Forestry, 6, 1-7.

Karlik, J.F., & McKay, A.H. (2012). Leaf Area Index, Leaf Mass Density, and allometric relationships derived from harvest of blue Oaks in a California Oak savanna. USDA Forest Service Gen. Tech. Rep. PSW-GTR-184.2002. Albany, CA: U.S. Department of Agriculture, Forest Service, Pacific Southwest Research Station, 846 p.

Khalili Ardali, Z., Mirazadi, Z., & Samaei, M. (2019). Estimation of Biomass, carbon sequestration and leaf area of Acer monspessulanum in Middle- Zagros, case study: Chaleh Gol forests in Lorestan province, Journal of Forest Resrach and Development, 5(2), 245-257. (In Persian)

Khosravi, S., Namiranian, M., Ghazanfari, H., & Shirvani, A. (2012). Estimation of leaf area index and assessment of its allometric equations in oak forests: Northern Zagros, Iran. Journal of Forest Science, 58(3), 116-122.

Lehtonen, A. (2005). Estimating foliage biomass in Scots pine (Pinus sylvestris) and Norway spruce (Picea abies) plots. Tree Physiology, 25(7), 803-811.

Litton, C.M., Raich, J.W., & Ryan, M.G. (2007). Carbon allocation in forest ecosystems. Global Change Biology, 13(10), 2089-2109.

Losi, C.J., Siccama, T.G., Juan, R.C., & Morales, E. (2003). Analysis of alternative methods for estimating carbon stock in young tropical plantations. Forest Ecology and Management, 184, 355-366.

Lovynska, V., Lakyda, P., Sytnyk, S., Kharytonov, M. & Piestova, I., 2018. LAI estimation by direct and indirect methods in Scots pine stands in Northern Steppe of Ukraine. Journal of Forest Science, 64(12), 514-522.

Majasalmi, T., Rautiainen, M., Stenberg, P., & Lukes, P. (2013). An assessment of ground reference methods for estimating LAI of boreal forests. Forest Ecology and Management, 292(15), 10-18

Mahdavi, A., & Mirzaei, M. (2020). Estimation of leaf biomass, leaf carbon sequestration and leaf area index of Cercis siliquastrum L. in forests of Ilam. The Journal of Plant Research, 33(1), 205-213. (In Persian)

Naghash Zargaran, M. (2001). Foliage biomass, leaf area index and their relationships to some characteristics of forest stand and soil in a permanent plot located in mid-elevation of Caspian Forests. MSc. thesis in Forest Sciences, Faculty of Forestry, Gorgan University of Agriculture Sciences and Natural Resources, 68 p. (In Persian)

Nowghani, Z., Koohi, L., Panahi, P., Torabian, Y., Pourhashemi, M., & Hashemi, A. (2016). Non-destructive leaf area estimation of indicator tree species of Hyrcanian collection, National Botanical Garden of Iran. Applied Biology, 29(1), 175-190.

Olfati, F., Mosleh Arani, A., & Azimzadeh, H.R. (2013). Estimation of carbon sequestration of four species of Pistacia atlantica, Acer monspessulanum, Amygdalus scoparia, and Ephedra procera in the protected area of Bagh Shadi Herat (Yazd Province). Journal of Plants and ecosystems, 9(36), 65-75. (In Persian)

Otukei, J.R., & Emanuel, M. (2015). Estimation and mapping of above ground biomass and carbon of Bwindi impenetrable National Park using ALOS PALSAR data. South African Journal of Geomatics, 4(1), 1-13.

Panahi, P., Pourhashemi, M., & Hassaninejad, M. (2011). Estimation of leaf biomass and leaf carbon sequestration of Pistacia atlantica in National Botanical Garden of Iran. Iranian Journal of Forest, 3(1), 1-12. (In Persian)

Panahi, P., Pourhashemi, M., & Hassaninejad, M. (2013). Comparison of Specific Leaf Area in Three Native Oaks of Zagros in National Botanical Garden of Iran. Iranian Forest Ecology, 1(2), 12-26. (In Persian)

Peper, P.J., & McPherson, E.G. (1998). Comparison of five methods for Estimating leaf area index of open-grown deciduous trees. Journal of Arboriculture, 24(2), 98-111. https://doi.org/10.48044/jauf.1998.013

Pierce, L.L., Running, S.W., & Walker, J. (1994). Regional‐scale relationships of leaf area index to specific leaf area and leaf nitrogen content. Ecological Applications, 4(2), 313-321.

Pilehvar, B., Mirazadi, Z., Taheri Abkenar, K., & Vayskarami, Z. (2015). Estimation of Leaf biomass, leaf carbon sequestration and leaf area index of oak trees in central of Zagros Forests (Case study: Shahanshah forests of Lorestan Province). Plant and Ecosystem, 10(41), 81-92.

Pourbabaei, H., Babaeian, M., Bonyad, A.E., & Adel, M.N. (2014). Autecology of Montpellier maple (Acer monspessulanum subsp. cinerascens) in forests of Fars Province. Journal of Plant Research, 27(3), 376-385. (In Persian)

Pourhashemi, M., Eskandari, S., Dehghani, M., Najafi, T., Asadi, A., & Panahi, P. (2012). Biomass and leaf area index of Caucasian Hackberry (Celtis caucasica Willd.) in Taileh urban forest, Sanandaj. Iran. Iranian Journal of Forest and Poplar Research, 19(4), 609-620. (In Persian)

Rosta, T. (2011). Estimating the economic value of the carbon sequestration of Pistacia atlantica and Amygdalus scoparia species in the Bene-Badam research forest of Firozabad, Fars. MSc. Thesis in Forestry, Sari University of Agriculture and Natural Resources. 97p. (In Persian)

Sagheb Talebi, Kh., Sajedi, T., & Pourhashemi, M. (2014). Forests of Iran: A Treasure from the Past, A Hope for the Future. Springer, 152p.

Thomas, S.C., & Martin, A.R. (2012). Carbon Content of tree tissues: A Synthesis. Forests, 3, 332-352. doi:10.3390/f3020332.

Vashum, K.T., & Jayakumar, S. (2012). Methods to estimate above-ground biomass and carbon stock in natural forests-a review. Journal of Ecosystem & Ecography, 2(4), 1-7.

Watson, R.T., Noble, I.R., Bolin, B., Ravindranath, N.H., Verardo, D.J., & Dokken, D.J. (2000). Land Use, Land-Use Change and Forestry: A Special Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, 388 pp.

West, P.W. (2009). Tree and Forest Measurement. Springer Publisher, 190 p.

Williams, T.M., & Gresham, C.A. (2006). Biomass accumulation in rapidly growing loblolly pine and sweetgum. Biomass and Bioenergy, 30(4), 370-377.

Zianis, D., & Mencuccini, M. (2003). Aboveground biomass relationships for beech (Fagus moesiaca Cz.) trees in Vermio Mountain, Northern Greece, and generalized equations for Fagus sp. Annals of Forest Science, 60(5), 439-448.

Zianis, D., Muukkonen, P., Mäkipää, R. & Mencuccini, M., 2005. Biomass and stem volume equations for tree species in Europe. Silva Fennica Monographs, 4(2), 5-63.