Research papers

Effects of Four Afforestation Stands on Some Physical, Chemical and Biological Properties of Soil in Northern Iran


Abstract


Selected species for afforestation have different effects on soil quality in addition to differences in their growth. The aim of current study was to investigate the effects of afforestation with four tree species, including chestnut-leaved oak, loblolly pine, black alder and Persian maple on the soil properties in the northwest of Iran. For this purpose, eight sample plots of 400 m2 were conducted in the study area and diameter and total height of the trees were measured. Then, eight soil samples were taken from a depth of 0 to 30 cm of each stand and transferred to the soil laboratory to be investigated some physical, chemical and biological properties of the soil. Hence, a total number of 16 different soil parameters of the four stands were measured and compared using ANOVA. Besides, the correlation between different soil properties and their relationship with tree species was analyzed, using principal components analysis (PCA). The results showed that among the studied stands, the loblolly pine had a higher mean diameter, mean height, basal area and volume. Regarding soil properties, alder stand possessed the highest porosity and the lowest bulk density. The pine stand, however, was estimated to possess the highest value of basal respiration, substrate induced respirations, microbial carbon biomass, organic carbon, total nitrogen, C/N ration, absorbable potassium and the lowest pH value. Finally, the maple stand possessed the highest amount of absorbable phosphorus. Based on the results of this study, pine species due to its high diameter growth and positive effects on most soil properties is recommended for afforestation in Hyrcanian region and similar habitats in west Asia.


Keywords

Bulk density; loblolly pine; organic carbon; substrate induced respirations

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DOI: http://dx.doi.org/10.12899/asr-2263

References


Alef K., Nannipieri P. 1995 - Methods in applied soil microbiology and biochemistry. Academic Press. London. 608p.

Allison L.E. 1975 - Organic carbon In: Black, C. A. (Ed.), “Methods of soil analysis”. American Society of Agronomy, Part 2, Madison, Vol.1: 1367-1378.

Arias-Navarro C., Díaz-Pinés E., Klatt S., Brandt P., Rufino M.C., Butterbach-Bahl K., Verchot L.V. 2017 - Spatial variability of soil N2O and CO2 fluxes in different topographic positions in a tropical montane forest in Kenya. Journal of Geophysical Research: Biogeosciences 122: 514-527.

Anderson J.P.E. 1982 - Soil respiration. In: Miller R.H and Keeney D.R (eds). "Methods of soil analysis part 2. Chemical and microbiological properties”. The American Society of Agronomy, Madison, Wisconsin: 831-871.

Badehian Z. 2007 - Evaluate the relationship between pH and carbon storage in organic and inorganic layers in Mixed Beech forest. MSc thesis. University of Tehran press. Tehatan. 69 p.

Blake G.R., Hartge K.H. 1986 - Bulkdensity. In: Klute A. (ed.): “Methods of Soil Analysis. Physical and Mineralogical Methods”. Agronomy Monographs, 9. Madison, ASA-SSA: 363–375.

Bouyoucos G.J. 1962 - Hydrometer method improved for making particle size analysis of soils. Agronomy Journal 56: 464-465.

Bower C.A., Reitemeier R.F., Fireman M. 1952 - Exchangeable cation analysis of saline and alkali soils. Soil Sciences 73: 251-261.

Chandran P., Dutta D.R., Gupta S.K., Banerjee S.K. 1987 - Soil characteristics under different forest cover in the eastern Himalayas. Indian Agriculturist 31: 93-99.

Cloy J.M., Smith K.A. 2018 - Greenhouse Gas Sources and Sinks. Reference Module in Earth Systems and Environmental Sciences 2: 391-400.

Deluca T.H., Boisvenue C. 2012 - Boreal Forest soil carbon: Distribution, function and modelling. Forestry 85 (2): 161-184.

De Wit H.A., Austnes K., Hylen G., Dalsgaard L. 2015 - A carbon balance of Norway: Terrestrial and aquatic carbon fluxes. Biogeochemistry 123 (2): 147-173.

Fadaei F., Fallah A., Latifi H., Mohammadi K. 2008 - Determining the best form factor formula for Loblolly Pine (Pinus taeda L.) plantations at the age of 18, in Guilan- northern Iran. Caspian Journal of Environmental Sciences 6(1): 19-24.

Farley K.A., Kelly E.F. 2004 - Effects of Eucalyptus saligna and Albizia falcataria on soil processes and nitrogensupply in Hawaii. Oecologia 113: 547-556.

Ghazanshahi J. 2006 - Soil and plant analysis. Ayizh Press, Tehran. 311 p.

Hashemi S.¬A., Hojati S.¬M., Hoseiny Nasr S.¬M., Asadyan M., Tafazoli M. 2017 - Studying soil physical, chemical and net Nitrogen mineralization in plantation and natural stands in Darabkola Forest (Sari). Journal of Forest Research and Development 3 (2): 119-132.

Hagen-Thorn A., Callesen I., Armolaitis K., Nihlgård B. 2004 - The impact of six European tree species on the chemistry of mineral topsoil in forest plantations on former agricultural land. Forest Ecology and Management 195 (3): 373-384.

Hou G., Delang C.O., Lu X. 2020 - Afforestation changes soil organic carbon stocks on sloping land: The role of previous land cover and tree type. Ecological Engineering 152: 105860.

Jafari Haghighi M. 2003 - Soil analysis methods. Nedaye Zohi Publication. 236 p.

Jenkinson D.¬S. Ladd J.¬N. 1981 - Microbial biomass in soil measurement and turnover. P415- 471, In: Paul E.A., Ladd, J.N. (Eds). Soil Biochemistry, Marcel Dekker, Inc., NY.

Kooch Y., Bayranvand M. 2017. Variability analysis of litter quality, mineral nitrogen, soil respiration and microbial biomass under afforested tree stands. Forest and Wood Products 70 (3): 451-460.

Mijangos I., Epelde L., Garbisu C., González-Oreja J.A. 2014 - Modification of soil enzyme activities as a consequence of replacing meadows by pine plantations under temperate climate. Pedobiologia (Jena) 57: 61-66.

Mijangos R., Kambozia J., Sabahi H., and Damghany A. 2009 - Effect of organic fertilizer on physical and chemical properties of soil, the yield and dry matter of tomato. Journal of Farm Research 7 (1): 257-267.

Morris L.A., Ludovici K.H., Torreano S.J., Carter E.A., Lincoln M.C., Will R.E. 2006 - An approach for using general soil physical condition – root growth relationships to predict seedling growth response to site preparation tillage in loblolly pine plantations. Forest Ecology and Management 227: 169-177.

Montagnini F. 2000 - Accumulation in above ground biomass and soil storage of mineral nutrients in pure and mixed plantations in a humid tropical lowland. Forest Ecology and Management 134: 257-270.

Motaghikhah K., Salehi A., Kahneh E., Heidari Safari Kouchi A. 2021 - Comparing the effect of Frankia nodules and urea fertilizer on biomass and amount of nutrients of alder saplings. Forest and Wood Products 73(4): 417-425.

Moslemi Seyed Mahalle SM., Jalali SM., Hojjati SM., Kooch Y. 2019 - The Effect of Different Forest Types on Soil Properties and Biodiversity of Grassland Cover and Regeneration in Central Hyrcanian Forests (Case Study: Seri-Alandan-Sari). Ecology of Iranian Forest 7 (14):10-21.

Niu D., Wang S., Ouyang Z. 2009 - Comparisons of carbon storages in Cunninghamia lanceolata and Michelia macculurei plantations during a 22¬ year period in southern China. Journal of Environmental Sciences 21: 801¬-805.

Nobakht A., Pourmajidian M., Hojjati S.¬M. 2011 - A comparison of soil carbon sequestration in hardwood and softwood monocultures (Case study: Dehmian forest management plan, Mazindaran). Iranian Journal of Forest 3 (1): 13-23.

Olsen S.R., Cole C.V., Watanabe F.S., Dean L.A. 1954 - Estimation of Available Phosphorous in Soils by Extraction with Sodium Bicarbonate. U.S. Department of Agriculture: Washington, D.C., USDA Circ. 939 p.

Poeplau C., Don A. 2013 - Sensitivity of soil organic carbon stocks and fractions to different land-use changes across Europe. Geoderma 192: 189-201.

Pourshakouri Allahdeh F., Hasanzad Navroudi I. 2008 – Member Investigation of the best method of volume estimation for Guilan forests (Case study: District one of NAV Asalem). Iranian Journal of Research and construction 77: 24-31.

Rahman M.¬M., Barcena T.¬G., Vesterdal L. 2017 - Tree species and time since afforestation drive soil C and N mineralization on former cropland. Geoderma 305: 153-161.

Rahmati H., Rostami Shahraji T., Salehi A., Heidari Safari Kouchi A. 2020. Comparison of Quantitative, Qualitative and Soil of Chestnut-leaved Oak and Loblolly Pine plantations of Shen-Rood Watershed No: 25 of Guilan Province. Iranian Journal of Forest Ecology 8 (15): 104-114.

Ridvan K. 2004 - Cu and Zn accumulation in earth worm Lumbricus terrestrist in sewag sludge amended soil and fraction of Cu and Zn casts and surrounding soil. Science 22: 141-145.

Simard R.S., Dekimpe C.¬R., Zizka J. 1993 - Release of potassium and magnesium from soil fractions and its kinetics. Soil Science Society of America Journal 56: 1421-1428.

Strand L., Callesen T., Dalsgaard I., De Wit H.¬A. 2016 - Carbon and nitrogen stocks in Norwegian forest soils the importance of soil formation, climate, and vegetation type for organic matter accumulation. Canadian Journal of Forest Research 46 (12): 1-15.

Teoman Güner S., Erkan N., Karataş R. 2021 - Effects of afforestation with different species on carbon pools and soil and forest floor properties. CATENA 196: 1048710.

Torreano S.J., Morris L.A. 1998 - Loblolly pine root growth and distribution under water stress. Soil Science Society of America Journal 62: 818-827.

Zare H., Amini T. 2012 - A review of the genus Alnus Mill. In Iran, New records S




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