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Šumarski list, Vol. 141 No. 3-4, 2017.

Izvorni znanstveni članak
https://doi.org/10.31298/sl.141.3-4.2

Evaluation of the effects of various factors on aboveground and belowground biomass storage capacity of eastern mediterranean maquis vegetation

Ali Durkaya ; Bartın University, Faculty of Forestry
Birsen Durkaya ; Bartın University, Faculty of Forestry
Ali Sabanci ; Bartın University, Faculty of Forestry
Sinan Kaptan ; Bartın University, Faculty of Forestry

Puni tekst: engleski, pdf (623 KB) str. 123-130 preuzimanja: 85* citiraj
APA 6th Edition
Durkaya, A., Durkaya, B., Sabanci, A. i Kaptan, S. (2017). Evaluation of the effects of various factors on aboveground and belowground biomass storage capacity of eastern mediterranean maquis vegetation. Šumarski list, 141 (3-4), 123-130. https://doi.org/10.31298/sl.141.3-4.2
MLA 8th Edition
Durkaya, Ali, et al. "Evaluation of the effects of various factors on aboveground and belowground biomass storage capacity of eastern mediterranean maquis vegetation." Šumarski list, vol. 141, br. 3-4, 2017, str. 123-130. https://doi.org/10.31298/sl.141.3-4.2. Citirano 15.02.2019.
Chicago 17th Edition
Durkaya, Ali, Birsen Durkaya, Ali Sabanci i Sinan Kaptan. "Evaluation of the effects of various factors on aboveground and belowground biomass storage capacity of eastern mediterranean maquis vegetation." Šumarski list 141, br. 3-4 (2017): 123-130. https://doi.org/10.31298/sl.141.3-4.2
Harvard
Durkaya, A., et al. (2017). 'Evaluation of the effects of various factors on aboveground and belowground biomass storage capacity of eastern mediterranean maquis vegetation', Šumarski list, 141(3-4), str. 123-130. doi: https://doi.org/10.31298/sl.141.3-4.2
Vancouver
Durkaya A, Durkaya B, Sabanci A, Kaptan S. Evaluation of the effects of various factors on aboveground and belowground biomass storage capacity of eastern mediterranean maquis vegetation. Šumarski list [Internet]. 2017 [pristupljeno 15.02.2019.];141(3-4):123-130. doi: https://doi.org/10.31298/sl.141.3-4.2
IEEE
A. Durkaya, B. Durkaya, A. Sabanci i S. Kaptan, "Evaluation of the effects of various factors on aboveground and belowground biomass storage capacity of eastern mediterranean maquis vegetation", Šumarski list, vol.141, br. 3-4, str. 123-130, 2017. [Online]. doi: https://doi.org/10.31298/sl.141.3-4.2

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Sažetak
This study was carried out on the data obtained from 35 plot areas selected among the vertical distribution regions of maquis in study area located in Eastern Mediterranean region. The data were grouped in terms of altitude, dominant exposure, vegetation height, and mean age factors, and it is tried to reveal the change of maquis biomass depending on these factors. The data obtained shown significant variation and, for this reason, the mass values are expressed as mean values. The potential relationship between the mentioned factors and the amounts of stored biomass was examined by using t-test and variation analysis. The mean aboveground biomass amount was found to be 24,183 ton/ha, while mean belowground biomass that doesn’t contain fine root was found to be 41,062 ton/ha. According to these results obtained from mean values, the root/shoot ratio was calculated to be 1.7.

Ključne riječi
Biomass; maquis; root/shoot ratio; altitude; exposure

Hrčak ID: 181409

URI
https://hrcak.srce.hr/181409

Reference

1 

Alkan H., Korkmaz M., Eker M. 2014: Stakeholders’ Perspectives on Utilization of Logging Residues for Bioenergy in Turkey. Croat.J.For.Eng., 35/2: 153-165.

2 

Arıcak B., Bulut A., Altunel A. O., Sakıcı O. E. 2015: Estimating Above Ground Carbon Biomass Using Satellite Image Reflection Values: A Case Study in Camyazi Forest Directorate, Turkey. Sumarski List, 7-8: 369-376.

3 

Armand D., Etienne M., Legrand C., Marechal J., Valette J. C. 1993: Phytovolume, phytomasse et relations structurales chez quelques arbustes méditerranéens [Phytovolume, phytomass and structural relationships of certain Mediterranean shrubs]. Annals For Science, 50: 79-89.

4 

Birdsey R. A. 1992: Carbon Storage and Accumulation in United States Forest Ecosystems,. USDA For Serv. Gen Tech. Rep/ WO-59 51.

5 

Brown S. 2002: Measuring carbon in forests: current status and future challenges. Environmental Pollution, 116, 363-372.

6 

Brown S. L., Schroeder P. E. 2002: 'Spatial patterns of aboveground production and mortality of wood biomass for eastern U.S. Forests'. Ecol. Appl., 9(3), 968-980.

7 

Canadell J., Roda F. 1991: Root biomass of Quercus ilex in a montane Mediterranean forest. Canadian Journal Of Forest Research, 21(12): 1771-1778.

8 

Canteiro C., Pinto-Cruz C., Simões M., Gazarini L. 2011: Conservation of Mediterranean oak woodlands: understory dynamics under different shrub management. Agroforestry Systems , 82, 161-171.

9 

Cornelissen C., Lavorel C., Garnier M., Diaz L., Buchmann L., Gurvich L., Reich L. 2003: A handbook of protocols standardisation and easy measurement of plant functional traits worldwide. Australian Journal of Botany , 51: 335-380.

10 

De Miguel S., Mehtatalo L., Durkaya A. 2014: Developing generalized, calibratable, mixed-effects meta-models for large-scale biomass predictions. Can.J.For.Res. , 44: 648-656.

11 

Durkaya A., Durkaya B., Makineci E., Orhan İ. 2015: Aboveground biomass and carbon storage relationship of Turkish pines. Fresenius Environmental Bulletin, 24(11): 3573-3583.

12 

Durkaya A., Durkaya B., Makineci E., Ülküdür M. 2013: Estimation of above-ground biomass and sequestered carbon of Taurus cedar (Cedrus libani L.) in Antalya, Turkey. iForest-Biogeosciences and Forestry, 6: 278-284.

13 

Eker M. 2014: Trends in Woody Biomass Utilization in Turkish Forestry. Croat.J.For.Eng., 35/2: 255-270.

14 

Granstrom K. 2003: Emissions of monoterpenes and VOCs during dryingof sawdust in a spouted bed. Forest Products Journal , 53(10): 48-55.

15 

Houghton J. T., Meira Filho L. G., Lim B., Treanton K., Mamaty I., Bonduki Y., Griggs D. J., Callander B. A. 1997: Revised 1996 Guidelines for National Greenhouse Gas Inventories. IPCC/OECD/IEA.

16 

Joosten R., Schumacher J., Christian W., Schulte A. 2004: Evaluating tree carbon predictions for beech (Fagus sylvatica L.) in western Germany. Forest ecology and management, 189, 87-96.

17 

Marziliano P. A., Lafortezza R., Medicamento U., Lorusso L., Giannico V., Colangelo G., Sanesi G. 2015: Estimating belowground biomass and root/shoot ratio of Phillyrea latifolia L. in the Mediterranean forest landscapes. Annals of Forest Science, 72: 585-593.

18 

McKinley D. C., Ryan M. G., Birdsey R. A., Giardina C. P., Health L. S., Houghton R. A., Jackson R. B., Morrison J. F., Murray B. C., Pataki D. E., Skog K. E. 2011: A synthesis of curresnt knowledge on forests and carbon storage in the United States. Ecological Applications, 21(6): 1902-1924.

19 

McPherson E. G., Nowak D. J., Rowntree R. A. 1994: Chicago’s Urban Forest Ecosystem: Results of the Chicago Urban Forest Climate Project. USDA Forest Service General Technical Report NE-186. Radnor, PA pp. 83-94.

20 

Nair P. K. R., Kumar B. M., Nair V. D. 2009: Agroforestry as a strategy for carbon sequestration. Journal of Plant Nutrition and Soil Science , 172, 10-23.

21 

Özalp G. 2000: Sert yapraklı ormanlar ve maki. İÜ Orman Fak. Dergisi, Seri A, 50(2): 131-155.

22 

Rodriguez PG, Annamalai K., Sweeten J. 1998: The effect of drying on the heating value of biomass fuels. Transactions of the ASAE, 41(4): 1083-7.

23 

Ruiz-Peinado R., Moreno G., Juarez E., Montero G., Roig S. 2013: The contribution of two common shrub species to aboveground and belowground carbon stock in Iberian dehesas. Journal of Arid Environments, 91: 22-30.

24 

Sağlam B., Küçük Ö., Bilgili E., Dinç Durmaz B., Baysal İ. 2008: Estimating fuel biomass of some shrub species (maquis) in Turkey. Turkish Journal of Agriculture and Forestry, 32: 349-356.

25 

Silva JS, Rego F. C. 2004: Root to shoot relationships in Mediterranean woody plants from Central Portugal. Biologia, 59(13): 1-7.

26 

Tamai S., Kato K., Kishibe Y., Ando M., Sano J. 2007: Effect of climate changes on the species composition and productivity of plant communities in the eastern Mediterranean region of Turkey. In: The Final Report of the Research Project on the Impact of Climate Changes on Agricultural Production System in Arid Areas (ICCAP). Research Institute for Humanity and Nature (RIHN) of Japan, and The Scientific and Technological Research Council of Turkey (TUBITAK), ICCAP Pub. No 10 (ISBN 4-902325-09-8), Kyoto, Japan pp. 103-110.

27 

Topić V., Butorac L., Jelić G. 2009: Biomass in strawberry tree coppice forests (Arbutus unedo L.) on Island Brač. Izvorni Znanstveni Članci, 133: 5-14.

28 

UNFCCC 2012: The Cancun Agreements. New York, NY:UN. pp. 103-110.

29 

Uslu T. 1985: A Plant Ecological and Sociological Research on the Vegetation of the Area Between Küçük and Büyük Menderes Rivers at the West of Aydın. Üniversitesi. Fen-Edebiyat Fakültesi Yayın No:8, Ankara. 174 pp.

30 

Varol T., Ertugrul m. 2015: Climate change and Forest Fire Trend in the Aegean and Mediterranean Regions of Turkey. Fresenius Environmental Bulletin, 24(10b): 3436-3444.

31 

Westerman T. 1985: Soil testing and plant analysis. 3rd ed. Soil Science Society of America, Madison, Wisconsin, USA.

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