Investigating the rate of litterfall and decomposition in Phulai dominated forest of Pakistan: A nutrient cycling perspective

Paper Details

Research Paper 01/01/2017
Views (439) Download (295)
current_issue_feature_image
publication_file

Investigating the rate of litterfall and decomposition in Phulai dominated forest of Pakistan: A nutrient cycling perspective

Iqra Naeem, Lubna Ansari, Syed M. Nizami, Talal Asif, Hina Tariq, Tariq Mahmood
Int. J. Biosci.10( 1), 42-51, January 2017.
Certificate: IJB 2017 [Generate Certificate]

Abstract

Phulai (Acacia modesta) is widely distributed and dominates in subtropical forests of Pakistan. Every year a huge amount of litter falls on the ground and decomposed to become part of nutrient cycling in this forest ecosystem. Although past research highlighted that llitterfall and roots decomposition is an important process in terrestrial C and N cycling. Unfortunately no attempt has been made in the past to explore the rate of decomposition of litter fall as well as the roots and subsequent entry into the soil as nutrients of this forest ecosystem. Therefore to cope with this knowledge gap one year data collection for total litterfall and decomposition bag experiment for leaf litter and roots of various classes (Fine having diameter <2mm, Medium = 2mm and coarse >2mm) was carried out. The study revealed that on average basis 31.95 t ha-1 yr-1 litterfall in this ecosystem with 32 % mass loss from decomposition. Moreover fine, medium and coarse roots deteriorate at rate of 33%, 34% and 29% of initial mass respectively. The examination of the supplements from litter fall as Nitrogen (N), Potassium (K), Phosphorus (P) and Carbon (C) entering into the soil at rate of 0.209, 1.31, 0.139 and 4.45 t ha-1 yr-1 respectively. Our results suggest that the decomposition rate and nutrient release in this forest ecosystem are closely linked to initial nutrients and C contents of litters. Thus, further investigations are required to explore specific content of the easily decomposable component in order to assess the effect these components on decomposition.

VIEWS 10

Alexander BA. 2013. Assessment of decomposition rate of Acacia mangium litter for rehabilitating degraded mined sites. Agriculture and Biology Journal of North America 4(3), 280-283.

Atkinson D. 1973. Some general effects of phosphorus deficiency on growth and development. New Phytologist 72(1), 101-111.

Baquar SR. 2010. Medicinal Plants and Poisonous Plants of Pakistan. Graphic Printers, Karachi, Pakistan. 455 p.

Beets PN, Hood IA, Kimberley MO, Oliver GR, Pearce SH, Gardner JF. 2008. Coarse woody debris decay rates for seven indigenous tree species in the central North Island of New Zealand. Forest Ecology and Management 256, 548-557. www.dx.doi.org/10.1016/j.foreco.2008.05.036

Berg B, McClaugherty C. 2010. Plant Litter: Decomposition, Humus Formation, Carbon Sequestration, second ed. Springer-Verlag Heidelberg Berlin 3, 338-352.

Berg B, McClaugherty C. 2014. Plant Litter: Decomposition, Humus Formation, Carbon Sequestration, 3rd ed. Springer, Verlag, Berlin, Heidelberg, Germany.

Blouin CM, Lay SL, Lasnier F, Dugail , Hajduch E. 2008. Regulated association of caveolins to lipid droplets during differentiation of 3T3-L1 adipocytes. Biochemical and Biophysical Research Communications 376(2), 331-335. www.dx.doi.org/10.1016/j.bbrc.2008.08.154.

Camiré C, Côté B, Brulotte S. 1991. Decomposition of roots of black alder and hybrid poplar in short-rotation plantings: nitrogen and lignin control. Plant Soil, 138, 123–132.

Champion HG, Seth SK, Khattak GM. 1965. Manual of General Silviculture of Pakistan. Pakistan Forest Institute. Peshawar. Pakistan.

Emily FS, Ingo S, Steffen B, Ellen K, Sven M, Beate M, Jorg M, Jakob Z, Susan ST, Marion S. 2013. Factors controlling decomposition rates of fine root litter in temperate forests and grasslands. Plant Soil 382(1-2), 203-218. www.dx.doi.org/10.1007/s11104-014-2151-4

Fahey TJ, Hughes JW, Pu M, Arthur MA. 1988. Root decomposition and nutrient flux following whole-tree harvest of northern hardwood forest. Forest Science 34, 744–768.

Fanin N, Haettenschwiler S, Barantal S, Schimann H, Fromin N. 2011. Does variability in litter quality determine soil microbial respiration in an Amazonian rainforest? Soil Biology & Biochemistry 43, 1014-1022.

Flanagan PW, Cleve KV. 1983. Nutrient cycling in relation to decomposition and organic matter quality in taiga ecosystems. Canadian Journal of Forest Research 13, 795-817.

Fujii S, Takeda H. 2012. Succession of collembolan communities during decomposition of leaf and root litter: Effects of litter type and position. Soil Biology & Biochemistry 54, 77-85. www.dx.doi.org/10.1016/j.soilbio.2012.04.021.

Gajri PR, Arora VK, Kumar K. 1994. A procedure for determining average root length density in row crops by single-site augering. Plant Soil 160(1), 41-47.

Jawla SK, Kumar S, Malik HK. 2005. Evaluation of Mode Fields in a Magnetized Plasma Waveguide and Electron Acceleration. Optics Communication 4-6, 346-60.

Joergensen RG, Kubler H, Meyer B, Wolters V. 1995. Microbial biomass in soils of beech (Fagus sylvatica L.) forests. Biol. Fertil. Soil 19, 215–219.

Lee M, Nakane K, Nakatsubo T, Koizumi H. 2003. Seasonal changes in the contribution of root respiration to total soil respiration in a cool-temperate deciduous forest. Plant Soil 255(1), 311-318. www.dx.doi.org/10.1023/A:1026192607512

Makita N, Fuji S. 2015. Tree species effects on microbial respiration from decomposing leaf and fine root litter. Soil Biology & Biochemistry 88, 39-47. www.dx.doi.org/10.1016/j.soilbio.2015.05.005

Mellilo JM, Aber JD, Muratore JF. 1982. Nitrogen and lignin control of hardwood leaf litter decomposition dynamics. Ecology 63, 621-626.

Olajuyigbe S, Tobin B, Hawkins M, Nieuwenhuis M. 2012. The measurement of woody root decomposition using two methodologies in a Sitka spruce forest ecosystem. Plant Soil 360(1-2), 77-91. www.wos:000310207300006

Olsen JS. 1963. Energy storage and the balance of producers and decomposers in ecological systems. Ecology 44, 322-331.

Palm CA. 1995. Contribution of agroforestry trees to nutrient requirement of inter-cropped plants. Agroforestry Systems 30, 105-124.

Paruelo J, Jobbagy E, Sala O, Lauenroth W, Burke I. 1998. Functional and structural convergence of temperate grassland and shrubland ecosystems. Ecology Applied 8, 194-206.

Paul EA, Clark FE. 1989. Soil microbiology and biochemistry. Academic Press Inc. London, England, 276 p.

Powers JS, Montgonery RA, Adair EC, Brearley FQ, DeWalt SJ, Castanho CT, Chave J, Deinert J, Ganzhorn JU, Gilbert ME, Gonzales-Iturbe JA, Bunyavejchewin S, Grau HR, Harms GE, Hiremath A, Iriarte-Vivar S, Manzane E, de Oliveria AA, Pooter A, Ramanamanjato J, Salk C, Varela A, Wieblen GD, Lerdau MT. 2009. Decomposition in tropical forests: a pan-tropical study of the effects of litter type, litter placement and mesofaunal exclusion across a precipitation gradient. Journal of Ecology 97, 801-811. www.wos:000267071500021

Prescott CE, Grayston SJ. 2013. Tree species influence on microbial communities in litter and soil: current knowledge and research needs. Forest Ecology and Management 309, 19-27.

Silver WL, Miya RK. 2001. Global patterns in root decomposition: Comparisons of climate and litter quality effects. Oecologia 129(3), 407-419.

Singh K, Singh P, Tripathi S. 1999. Litterfall, litter decomposition and nutrient release patterns in four native tree species raised on coal mine spoil at Singrauli, India. Biology and Fertility of Soils 29, 371-378.

Vogt KA, Vogt DJ, Palmiotto PA, Boon P, O’Hara J, Asbjornsen H. 1995. Review of root dynamics in forest ecosystems grouped by climate, climatic forest type and species. Plan and Soil 187(2), 159–219. www.dx.doi.org/10.1007/BF00017088

Waring RH, Schlesinger WH. 1985. Forest ecosystems concepts and management Ch.8. In: Decomposition and Forest Soil Development. Academic Press, Inc. New York. 181-210 p.

Wedin DA. 1995. Species, nitrogen and grassland dynamics: the constraints of stuff. In: Jone, C. G., Lawton, L. H. (Eds.), Linking Species and Ecosystems. Chapman & Hall, New York, 253-262 p.

Wedin DA. 1999. Nitrogen availability, plant soil feedbacks and grassland stability. In: Eldridge, D., Freudenberger, D. (Eds.), Proceedings of the VI International Rangeland Congress on People and Rangelands Building the Future. Townsville, Australia, 193-197 p.

White LD, Haines BL, Boring LR. 1988. Litter decomposition in southern Appalachian black locust and pine-hardwood stands: litter quality and nitrogen dynamics. Canadian Journal of Forestry Research 18, 54-63.

Xin W, Yin X, Song B. 2012. Contribution of soil fauna to litter decomposition in Songnen sandy lands in northeastern China. Journal of Arid Environment 77, 90-95. www.dx.doi.org/10.1016/j.jaridenv.2011.10.001

Xiong Y, Hanping X, Zhian L, Xian C, Shenglei F. 2008. Impacts of litter and understory elimination on soil belongings in a subtropical Acacia mangium plantation in China. Plant Soil 304(1-2), 179-188.