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:: Volume 6, Issue 13 (3-2019) ::
PEC 2019, 6(13): 215-232 Back to browse issues page
Investigating the carbon storage in different climatic regions and the affecting factors in Kordestan Province
Reza Omidipour Mr.
Abstract:   (643 Views)
In recent decades, climate change and global warming have become to one of the critical global challenges that have attracted the attention of researchers. Knowing the effects of climate change on soil carbon can be used as the best tools regarding to understand the soil carbon cycle, therefore, this study was carried out to investigate and compare the amount of carbon storage in different climatic region, as well as to determine the most important environmental factors (soil factors, precipitation and elevation), affecting the amount of carbon storage in all three Dezly regions (wet), Naran (arid) and Gardaneh Morvarid (semi-arid) in Kurdistan province. To do so, six, three, and four sites were selected in the Dazli, Neran and Gardaneh Morvarid, respectively. To study the physical and chemical properties of soil in each site, three profiles were drilled from 0 to 50 cm depth (total of 39 soil samples). In order to statistical analysis, analysis of variance (one-way ANOVA) and regression were used. The results showed that there was a significant difference between the amount of carbon storage in our studied areas, so that the highest and lowest amount of carbon storage were in Dezly (9.56 ± 1.16, ton/ha) and Gardaneh Morvarid (5.45 ± 1.08, ton/ha), respectively. The results also showed that there were a linear and positive relationship between the amount of carbon storage and soil P content and elevation in all regions. In addition, the results of stepwise regression showed that soil limestone (R = 0.52), nitrogen fertilizer (R = 0.71), and altitude (R = 0.83) were the most important factors affecting carbon storage in Dezly, Naran and Gardaneh Morvarid, respectively. The results of this study highlighted that climate change (get dry) could reduce soil carbon storage. Given the variability of environmental factors in different climates, it is suggesting that different methods could be used to manage carbon storage in each climate.
Keywords: Climate Change, Global Warming, Carbon Sequestration, Soil, Kurdistan.
Full-Text [PDF 387 kb]   (213 Downloads)    
Type of Study: Applicable | Subject: Special
Received: 2017/09/10 | Accepted: 2018/03/16 | Published: 2019/05/3
1. Abdi N., Arefi M., Zahedi-Amiri G.H. 2008. Estimation of carbon sequestration in Astragalus rangelands of Markazi province (Case study: Malmir rangeland in Shazand region). researches on forest and rangelands, 15: 269-282.
2. Allen-Dias B. 1996. Rangelands in a changing climate: impacts, adaptations and mitigation. In: Watson, R.T., et al. (Eds.), Climate Change 1995. Impacts, Adaptations and Mitigation of Climate Change: Scientific- Technical Analyses. Cambridge University Press, Cambridge, Published for the Intergovernmental Panel on Climate Change, pp. 131–158.
3. Augusto L.R, Jacques D., Roth A. 2002. Impacts of several common tree species of European temperate forests on soil fertility, Annals of Forest Science, 59: 233-253.
4. Burke I.C., Yonker C. M.,Parton W. J., Cole C.V., Flach K., Schimel D.S. 1989. Texture, climate, and cultivation effects on soil organic matter content in U.S. Grassland Soil. Soil Science Society Am. J. 53:800-805.
5. Buschiazzo D.E., Quiroga A.R., Stahr K. 1991. Patterns of organic matter accumulation in soil of the semi-arid Argentinean Pampas. Zeitschrift für Pflanzenernährung und Bodenkunde, 154: 437-441.
6. Crow S.E., Swantson C., Lajtha K. 2007. Density fraction of forest soils: methodological question and interpretation of incubation result and turnover time in an ecosystem context. Biogeochemistry 85: 69-90.
7. Cui X., Wang Y., Niu H., Wu J., Wang S., Schnug E., Rogasik J., Fleckenstein J., Tang Y. 2005. Effect of long-term grazing on soil organic carbon content in semi-arid steppes in inner Mongolia, Ecological Research, 20: 519-527.
8. Delgado-Baquerizo M., Eldridge D.J., Maestre F.T., Karunaratne S.B., Trivedi P., Reich P.B., Singh B.K. 2017. Climate legacies drive global soil carbon stocks in terrestrial ecosystems. SCIENCE ADVANCES, 3: e1602008.
9. Eskandari N., Alizadeh A., Mahdavi F. 2007. Iran range management policy. Forest and rangeland organization. 190 p.
10. Hoyos N., Comerford N. B. 2005. Land use and landscape effects on aggregate stability and total carbon of Andi-sols from the Colombian Andes. Geoderma 129: 268-278.
11. Izaurralde R., Williams J.R., McGill W.B., Rosenberg N.J., Jakas M. 2006. Simulating soil C dynamics with EPIC: Model description and testing against long-term data. Ecological Modelling, 192: 362-384.
12. Jafari M. 2005. The effect of climate changes on forest ecosystems. Publications of Research Institute of Forest, Rangeland and Watershed Management. 90 p.
13. Jinxum L. 2005. Nitrogen controls on ecosystem carbon sequestration: a model implementation and application to Saskatchewan, Canada. Journal of Ecological modeling. 186: 178-195.
14. Kessler A., Landsberg H.E. 1985. General climatology. Amsterdam: Elsevier Press. p. 224.
15. Lal R. 2001. The potential of soil carbon sequestration in forest ecosystems to mitigate the greenhouse effect. Soil Science Society of America, Madison, WI.
16. Liu Z., Shao M., Wang Y. 2011. Effect of environmental factors on regional soil organic carbon stocks across the Loess Plateau region, China”, Agriculture, Ecosystems and Environment, 142:184-194.
17. Ma Z., Coppock D.L. 2012. Perceptions of Utah ranchers toward carbon sequestration: Policy implications for US rangelands. Journal of Environmental Management, 111: 78-86.
18. Monger C., Sala O.E., Duniway M.C., Goldfus H., Meir I.A., Poch R.M., Throop H.L., Vivoni E.R. 2015.Legacy effects in linked ecological-soil-geomorphic systems of drylands. Front. Ecol. Environ. 13:13–19.
19. Morgan J., Follet R., Allen L. 2010. Carbon sequestration in agricultural lands of the United States. Journal of Soil and Water Conservation, 65: 1-17.
20. Munoz-Rojas M., Doro L., Ledda L., Francaviglia A. 2015. Application of Carbo-SOIL model to predict the effects of climate change on soil organic carbon stocks in agro-silvo-pastoral Mediterranean management systems. Agriculture, Ecosystems & Environment 202:8-16.
21. Neill C., Melillo J. Steudler P. A., Cerri C.C., MoraesJ. F.L., Piccolo M.C., Brito M. 1997. Soil carbon and nitrogen stocks following forest clearing for pasture in the southwestern Brazilian Amazon. Ecological Application, 7: 1216-1225.
22. Oades J.M. 1993. The role of biology on the formation, stabilization and degradation of soil structure. Geoderma, 59: 377-400.
23. Ogle S.M., Breidt F.J., Easter M., Williams S., Paustian K. 2007. An empirically based approach for estimating uncertainty associated with modelling carbon sequestration in soils. Ecological Modelling 205: 453-463.
24. Ogle K., Barber J.J., Barron-Gafford G.A., Bentley L.P., Young J.M., Huxman T.E., Loik M.E., Tissue D. T. 2015. Quantifying ecological memory in plant and ecosystem processes. Ecol. Lett. 18:221–235.
25. Polglace J., Almeida A. 2013. Potential for forest carbon plantings to offset greenhouse emissions in Australia: economics and constraints to implementation. Climate Change 121: 161–175.
26. Page A.L., Miller R.H., Keeney D.R. 1982. Methods of Soil Analysis. 2th ed. Part 2: Chemical and biological properties. Soil Science Society of America. Inc. publisher.
27. Pandey C.B., Chaudhari S.K. Dagar J.C. Singh G.B., Singh R.K. 2010. Soil N mineralization and microbial biomass carbon affected by different tillage levels in a hot humid tropic. Soil and Tillage Res. 110: 33-41.
28. Paul K.I., Polglase P.J. 2002. Changes in soil carbon following Afforestation. Forest Ecology and Management, 168:241-257
29. Pussinen A. 2002. Forest carbon sequestration and harvest, in scots pine stand under different climate and nitrogen deposition scenarios. Forest Ecology and management, 158(1-3): 103- 115.
30. Ruiz-Sinoga J. D., Pariente S., Diaz A.R., Martinez-Murillo J.F. 2012. Variability of relationships between soil organic carbon and some soil properties in Mediterranean rangelands under different climatic conditions (South of Spain). Catena, 94:17-25.
31. Sariyildiz T., Anderson J.M., Kucuk M. 2005. Effect of tree species and topography on soil chemistry, litterquality, and decomposition in Northeast Turkey. Soil Biol. and Biochem, 37: 1695-1706.
32. Schmidt M.W.I., Torn M.S., Abiven S., Dittmar T., Guggenberger G., Janssens I.A., Kleber M., Kögel-Knabner I., Lehmann J., Manning D.A.C., Nannipieri P., Rasse D.P., Weiner S., Trumbore S. E. 2001. Persistence of soil organic matter as an ecosystem property. Nature, 5: 49–56.
33. Singh S. K., Pande C. B.,Sidhu G.S., Dipak-Sarkar R. S. 2011. Concentration and stock of carbon in the soils affected by land uses and climates in the western Himalaya, India. Catena, 87: 78-89.
34. Skyllberg U. 1991. Seasonal variation of pH H2O and pH CaCl2 in centimeter layers of more humus in a Picea abies (L.) Karst. stand. Scandinavian Journal of Forest Research, 6: 3-18.
35. Strickland M.S., Keiser A.D., Bradford M.A., 2015. Climate history shapes contemporary leaf litter decomposition. Biogeochemistry 122, 165–174.
36. Tiessen H., Cuevas E., Chacon P. 1994. The role of soil organic matter in sustaining soil fertility. Nature, 371: 783–785.
37. Tan Z., Lal R. 2005. Carbon sequestration potential estimates with changes in land use and tillage practice in Ohio, USA. Agriculture, ecosystems & environment, 111: 140-152.
38. Tan B., Fan J., He Y., Luo S., Peng X. 2014. Possible effect of soil organic carbon on its own turnover: A negative feedback. Soil Biology and Biochemistry, 69: 313-319.
39. United Nations Environment Program (UNEP). 2012. Year Book: Emerging Issues in our Global Environment (United Nations Environment Program.
40. Walkley A., Black I.A., 1934. An examination of the Degtjareff method for determining soil organic matter and a proposed modification of the chromic acid titration method. Journal of Soil Science, 37: 29–38.
41. Wang Z., Zhang B., Song K., Liu D., Li F., Guo Z., Zhang S. 2008. Soil organic carbon under different landscape attributes in croplands of Northeast China. Plant Soil Environ, 54: 420-427
42. Xiong X., Grunwald S., Brenton Meyres D., Wade Ross C., Harris W.G., Comerford N. B., 2014. Interaction effects of climate and land use/land cover change on soil organic carbon sequestration. Science of the Total Environ, 493: 974-982.
43. Zahedi G.h., 2002. Spatial dependence between soil carbon and nitrogen storage in two forest types. Proceeding of the XII World Forestry Congress in Canada/Quebec: 357-358.
44. Zandi L., Erfanzadeh R., Joneidi-Jafari H. 2017. Rangeland Use Change to agriculture has different effects on soil organic matter fractions depending on the type of cultivation. Land Degradation and Development, 28: 157-180.
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Omidipour R. Investigating the carbon storage in different climatic regions and the affecting factors in Kordestan Province. PEC. 2019; 6 (13) :215-232
URL: http://pec.gonbad.ac.ir/article-1-377-en.html

Volume 6, Issue 13 (3-2019) Back to browse issues page
مجله حفاظت زیست بوم گیاهان Journal of Plant Ecosystem Conservation
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