The leaf litter decomposition of Nypa fruticans, Rhizophora racemosa and Avicennia africana were studied across a tidal gradient in a mixed mangrove forest of the Cross River estuary Nigeria. Leaf litter decomposition was measured along the tidal gradients (low, mid, high) using litter bags. A single exponential model was used to study the decomposition rates of the leaves. Leaf decomposition varied significantly (P < 0.001) among species and spatially across tidal gradients over the study period. Decomposition was fastest in A. africana and slowest in N. fruticans and spatially, it was fastest at the low tide level and slowest at the high tide level. Tidal effects were much larger than species differences in the decomposition rates. The time (days) required for the loss of half the initial dry mass (T50) of the decomposing leaves at the low, mid and high tide levels were A. africana, 46, 57 and 77, R. racemosa 69, 86 and 115, and N. fruticans 86, 99 and 115 respectively. Estimates of leaf litter turnover rates showed that the actual litter turnover based on the relative measure of leaf litterfall and biomass on the forest floor (Kt) were much shorter than the projected litter turnover based on the leaf decomposition rates (Kd). The estimated actual residence times were less than one day while the projected residence times ranged from 83 to 142 days across tidal gradients, suggesting involvement of other ecological processes in litter loss and their possible transport into the Cross River estuary. The nitrogen contents and nutritional value of the decomposing leaves increased with time during the study. The increase varied significantly (P <0.001) among species, as well as temporally (P < 0.001) and spatially (P ≤ 0.05). The average C:N ratio decreased from 27.7 to 22.1 in A. africana, 26.4 to 23.9 in R. racemosa and 32.8 to 23.6 in N. fruticans. The overall changes in nutrients during decomposition indicated net mineralization. Mangrove leaf litter dynamics, trophic value and organic matter exchange of the system have implications on the productivity of the Cross River estuary and ultimately the Gulf of Guinea. Knowledge of these processes is critical for the maintenance and long term sustainability of the mangrove and surrounding ecosystems.
Published in | International Journal of Environmental Monitoring and Analysis (Volume 2, Issue 3) |
DOI | 10.11648/j.ijema.20140203.16 |
Page(s) | 163-174 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2014. Published by Science Publishing Group |
Leaf Decomposition, Spatial Variation, Temporal Variation, Total Carbon, Total Nitrogen
[1] | Alongi, D. M. Present state and future of the world’s mangrove forests. Environmental Conservation, Vol. 29, pp.231-349. 2002. |
[2] | World Bank, International Society for Mangrove Ecosystems, Center Aarhus, Principles for a code of conduct for the management and sustainable use of mangrove ecosystems. The World Bank, Washington, D.C. 211pp. 2004. |
[3] | Hogarth, P. J. The Biology of Mangroves. Oxford University Press. 272pp. 1999. |
[4] | Middleton, B. A. and McKee, K. L. Degradation of mangrove tissues and implications for peat formation in Belizean Island forest. Journal of Ecology, Vol. 89, pp.818-828. 2001. |
[5] | Ellison, A. M. and Farnsworth, E. J. Mangrove communities. In: Bertness, M. D., Gaines, S. D. and Hay, M. E. (eds). Mangrove Community Ecology, (432 – 442). Sinauer Associates, Sunderland, Massachetts, U. S. A. 2001. |
[6] | Rey, J. R. and Rutledge, C. R. Mangroves. http://edis.ifas.ufi.edu/in195. 2005. Retrieved 16/02/06. |
[7] | Ong, J. E. The ecology of mangrove conservation and management. Hydrobiologia, Vol. 295, pp.343-351. 1995. |
[8] | McKee, K. L. and Faulkner, P. L. Restoration of biogeochemical function in mangrove forests. Restoration Ecology, Vol. 8, pp. 247-259. 2000. |
[9] | Lee, S. Y. Mangrove outwelling: A review. Hydrobiologia, Vol. 295, pp.203-212. 1995. |
[10] | Sunil-Kumar, R. A review of biodiversity studies of soil dwelling organisms in Indian mangroves Zoos Print Journal, Vol.15 No.3, pp. 221-227. 2000. |
[11] | Sunil-Kumar, R. Mangrove debritus loading, tidal export and its large scale effect on promoting biodiversity resources. http://chennai.sancharnet.in/d/envasscas/9(13).htm. Retrieved 02/06/05. 2005. |
[12] | Wardle, D. A. Bonner, K. I. and Nicholson, K. S. Biodiversity and plant litter: experimental evidence which does not support the view that enhanced species richness improves ecosystem function. Oikos, Vol. 79, pp. 247-258. 1997. |
[13] | Feller, I. C., Whigham, D. F., O’Neill, J. P. and McKee, K. L. Effects of nutrient enrichment on within stand cycling in a mangrove forest. Ecology, Vol. 8,pp. 2193-2205. 1999. |
[14] | Alongi, D. M. Mangrove – microbe – soil relations. In: Kristensen, E., Haesse, R. R., Kostka, J. E. (Eds), Interactions between macro and micro-organisms in marine sediments, (85-103). Coastal and estuarine studies, volume 60 American Geophysical Union, Washington DC. 2005. |
[15] | Alongi, D. M., Clough, B. F. and Robertson, A. J. Nutrient-use efficiency in arid-zone forests of the mangrove Rhizophora stylosa and Avicennia marina. Aquatic Botany, Vol, 82, pp.121-131. 2005. |
[16] | Dittmar, T., Hertkorm, N., Kattner, G. and Lara, R. J. Mangroves, a major source of dissolved organic carbon to the oceans. Global Biogeochemical Cycles, 20, GB 1012. doi:1029/2005GB0025. 2006. |
[17] | Akpan, E. R. Influence of meteorological and hydrographic factors on the water quality of the Calabar river, Nigeria. Tropical Journal of Environmental Research, Vol.2, No.182, pp.107-111. 2000. |
[18] | Holzloehner, S., Nwosu, F. M. and Akpan, E. R. Mangrove mapping in the Cross River estuary, Nigeria. African Journal of Environmental Pollution and Health, Vol. 1, No.2, pp. 76-87. 2002. |
[19] | NMOC. Meteeorological data for 2008/2009. Nigeria meteorological office, Margaret Ekpo International Airport, Calabar. 2010. |
[20] | Fell, I. W. and Master, I. M. Litter decomposition and nutrient enrichments. In: Snedaker, S. C. and Snedaker, J. G. (Eds.). The Mangrove Ecosystem Research Method, (239-263). UNESCO, United Kingdom. 1984. |
[21] | APHA, Standard methods for the examination of water and waste water, Washington DC. PHHA-AWWA-WPCF, 1134pp. 1980. |
[22] | Minderman, G. Addition, decomposition and accumulation of organic matter in forest. Journal of Ecology, Vol.56, pp.335-362. 1968. |
[23] | Obi, J. U. Statistical methods of determining differences between treatment means and research methodology issues in laboratory and field experiments. Enugu: SNAAP Press. 717pp. 2002. |
[24] | Harmon, M. E., Franklin, J. F., Swanson, F. J., Sollins, P., Gregory, S. V., Lattin, J. P., Anderson, N. H., Cline, S. A., Aumen, N. G., Sedell, J. R., Lienkaemper, G. W., Gromack, K. J. and Cummins, K. W. Ecology of coarse woody debris in temperate ecosystems. Advances in Ecological Research, Vol.15, pp.133 – 302. 1986. |
[25] | Nye, P. H. Organic matter and nutrient cycles under moist tropical forests. Plant Soil, Vol.13, pp.333 – 346. 1961. |
[26] | Edu, E. A. B. Litter dynamics (Production, Composition and Decomposition) of mangroves in a mixed riverine mangrove forest of the Cross River estuary, Nigeria. Ph.D Thesis, University of Calabar, Calabar, Nigeria. 2012. |
[27] | Goulter, P. F. E. and Allaway, W. G. Litter fall and decomposition in a mangrove stand Avecennia marina (Forsk) Vieth. Australian Journal of Marine and Freshwater Resources, Middle Harbour, Sydney, Vol.30, pp.541 – 546. 1979. |
[28] | Imgraben, S. and Dittmann, S. Leaf litter dynamics and litter consumption in two temperate South Australian mangrove forests. Journal of Sea Research, Vol.59, pp.83-93. 2008. |
[29] | Ashton, E. C., Hogarth, P. J. and Ormond, R. Breakdown of mangrove leaf litter in a managed mangrove forest in Peninsular Malaysia. Hydrobiologia, Vol.413, pp.77-88. 1999. |
[30] | Wafar, S., Untawale, A. G. and Wafar, M. Litterfall and energy flux in a mangrove ecosystem. Estuarine, Coastal and Shelf Science, Vol.44, pp.111-124. 1997. |
[31] | Twilley, R. R., Pozo, M., Garcia, V. H., Rivera-Monroy, V. H., Zambrano, R. and Bodero, A. Litter dynamics in riverine mangrove forests in the Guayas River Estuary, Ecuador.Oecologia, Vol.111, pp.109-122. 1997. |
[32] | Tam, M. F. Y., Li, S. H., Lan, C. Y., Chen, G. Z., Li, M. S. and Wong, Y. S. 1998. Nutrients and heavy metal contamination of plants and sediments in Futian mangrove forest. Hydrobiologia, Vol.295, No.1 – 3, pp.149 – 158. |
[33] | Boulton, A. J. and Boon, P. I. A review of methodology used to measure leaf litter decomposition in lotic environments: time to turn over an old leaf? Australian Journal of Marine Freshwater Resources, Vol.42, pp.1 – 43. 1991. |
[34] | Steinke, T. D., Holland, A. J. and Singh, Y. Leachira losses during decomposition of mangrove leaf litter. South African Journal of Botany, Vol.59, pp.21-25. 1992. |
[35] | Bosire, J. D., Dahdouh-Guebas, F., Kairo, S. G., Kazungu, J., Dehairs, F. and Koedam, N. Litter degradation and CN dynamics in reforested mangrove plantations at Gazi Bay, Kenya. Biological Conservation, Vol.126, pp.287-295. 2005. |
[36] | Cattiano, J. H., Anderson, A. B., Rombold, J. S.and Nlepstad, D. C. Phenology, litterfall, growth and root biomass in a tidal flood plain forest in the Amazon estuary. Revista Brasileira de Botanica, Vol.25, pp.419 - 430. 2004. |
[37] | Lee, S. Y. Ecological role of graspid crabs in mangrove ecosystems: a review. Marine and Freshwater Resources, Vol.49, pp.335 – 343. 1998. |
[38] | Alongi, D. M. Coastal Ecosystem Processes. Boca Raton. CRC Press, 419pp. 1998. |
[39] | Smithwick, E. A. H., Turnei, M. G., Mack, M. C. G., Chapin III, F. S., Shu, Jun and Balser, T. C. Spatial heterogeneity in ecosystem processes after severe fire in a black spruce (P. mariana) forest: Alaska (USA). Ecological Society of America 89th Annual Meeting, (August 1-6) Portland Oregon. 314pp. 2004. |
[40] | Dick, T. M. and Osunkoya, O. O. Influence of tidal restriction floodgates on decomposition of mangrove litter. Aquatic Botany, Vol.68, pp. 273-280. 2000. |
[41] | Mfilinge, P. L., Atta, N. and Tsuchiya, M. Nutrient dynamics and leaf litter decomposition in a subtropical mangrove forest at Oura Bay, Okinawa, Japan. Trees, Vol.6, pp.172-180. 2002. |
[42] | Edu, E. A. B. Microflora populations in riverine mangrove sediments, Cross River estuary, Nigeria Masters Thesis. University of Calabar, Calabar, Nigeria 92pp. 2005. |
[43] | Edu, E. A. B., Omokaro, D. N., Holzloehner, S. and Udensi U. Microflora populations in mangrove sediments of Cross River estuary. Global Journal of Pure and Applied Sciences, Vol.13, No.3, pp.347-352. 2007. |
[44] | Holmer, M. and Olsen, A. B. Role of decomposition of mangrove and seagrass detritus in sediment carbon and nitrogen cycling in a tropical mangrove forest. Marine Ecological Progress Series, Vol.230, pp.87-101. 2002. |
[45] | Jennerjahn, T. C. and Ittekkot, V. Relevance of mangroves for the production and deposition of organic matter along tropical coastlines. Naturwissenschaften, Vol.89, 23-30. 2002. |
[46] | Fujimoto, K., Imaya, A., Tabuchi, R., Kuramoto, S., Utsugi, H. and Murofushi, T. Blowground carbon storage of Micronessian mangrove forests. Ecological Research, Vol.14, pp.409 – 413. 1999. |
[47] | Chen, R.R. and Twilley, R. A simulation model of organic matter and nutrient accumulation in mangrove wetland soils. Biogeochemistry, Vol.44, pp.93-118. 1999. |
[48] | Van der Valk, A. G. and Attiwill, P. M. Decomposition of leaf and root litter of Avicennia marina at Westernport Bay, Victoria, Australia. Aquatic Botany, Vol.18, pp.205-221. 1984. |
[49] | Twilley, R. R., Lugo, A. F. and Patterson – Zucca, C. Production, standing crop and decomposition of litter in basin mangrove forests in southwest Florida. Ecology, Vol.67, pp.670 - 683. 1986. |
[50] | Werry, J. and Lee, S. Y. Graspid crabs mediate link between mangrove litter production and planktonic food chains. Marine Ecology Progress Series, Vol.293, pp.165-176. 2005. |
[51] | Woitchik, A. F., Ohowa, B., Kazungu, J. M., Rao, R. G., Goeyens, I. and Dehairs, F. Nitrogen enrichment during decomposition of mangrove litter in an east African coastal lagoon (Kenya): relative importance of biological nitrogen fixation. Biogeochemistry, Vol.39, pp.15-35. 1997. |
[52] | Lee, S. Y. Potential trophic importance of the faecal material of the mangrove crab Sesarma messa. Marine Ecology Progress Series, Vol.158, pp.275 – 284. 1997. |
[53] | Reid, I. D. Biodegradatio of lignin. Canadian Journal of Botany, Vol.73, No.1, pp.51011 – 51018. 1995. |
[54] | Sjoberg, G. Lignin degradation: Long term effects of nitrogen addition on decomposition of forest soil organic matter. Doctoral Thesis. Swedish University of Agricultural Sciences, Uppsala, Sweden 46pp. 2003. |
[55] | Romero, L. M., Smith III, I. J. and Fourqurean, J. W. Changes in mass and nutrient content of wood during decomposition in a South Florida mangrove forest Journal of Ecology, Vol.93, pp.618-631. 2005. |
[56] | Edu, E. A., Omokaro, D. N. and Nya, P. J. Influence of forest types on the physicochemical parameters in mangrove sediments of Cross River estuary, Nigeria. Nigerian Journal of Botany, Vol.21, No.1,pp. 179-186. 2008a. |
[57] | Edu, E. A., Omokaro, D. N. and Nya, P. J. Microflora and nutrient status in the mangrove sediments of Cross River estuary, Nigeria. Nigerian Journal of Experimental and Applied Biology, Vol.9, No.2, pp.109-118. 2008b. |
[58] | Bouillon, S., Connolly, R. M. and Lee, S. Y. Organic matter exchange and cycling in mangrove ecosystems: recent insights from stable isotope studies. Journal of Sea Research, Vol.59, pp.44-58. 2008. |
[59] | Dittmar, T., Lara, R. J. and Kattner, G. River or mangrove? Tracing major organic matter sources in tropical Brazilian coastal waters. Marine Chemistry, Vol.73, pp.253-271. 2001. |
[60] | Lee, S. Y. Carbon dynamics of Deep Bay eastern Pearl River estuary, Chinall: Trophic relationship based on carbon and nitrogen stable isotopes. Marine Ecology Progress Series, Vol.205, pp.51-70. 2000. |
[61] | Lee, S. Y. Mangrove macrobenthos. Assemblages, services and linkages. Journal of Sea Research, Vol.59, pp.16-29. 2008. |
[62] | Macia, A. Primary carbon sources for juvenile penaeid shrimps in a mangrove-fringed Bay of Inhaca island, Mozambique: A dual carbon and nitrogen isotope analysis. West Indian Ocean Journal of Marine Science, Vol.3, pp.151-161. 2004. |
[63] | Panikov, N. S. Understanding and prediction of soil microbial community dynamics under global change. International Journal of Applied Soil Ecology, Vol.5, No.1,pp. 1 – 17. 1999. |
APA Style
Edu. Esther. Aja. B, Nsirim. L. Edwin. Wosu, Martins, O. Ononyume. (2014). Monitoring and Assessment of Leaf Litter Dynamics in a Mixed Mangal Forest of the Cross River Estuary, Nigeria. International Journal of Environmental Monitoring and Analysis, 2(3), 163-174. https://doi.org/10.11648/j.ijema.20140203.16
ACS Style
Edu. Esther. Aja. B; Nsirim. L. Edwin. Wosu; Martins; O. Ononyume. Monitoring and Assessment of Leaf Litter Dynamics in a Mixed Mangal Forest of the Cross River Estuary, Nigeria. Int. J. Environ. Monit. Anal. 2014, 2(3), 163-174. doi: 10.11648/j.ijema.20140203.16
AMA Style
Edu. Esther. Aja. B, Nsirim. L. Edwin. Wosu, Martins, O. Ononyume. Monitoring and Assessment of Leaf Litter Dynamics in a Mixed Mangal Forest of the Cross River Estuary, Nigeria. Int J Environ Monit Anal. 2014;2(3):163-174. doi: 10.11648/j.ijema.20140203.16
@article{10.11648/j.ijema.20140203.16, author = {Edu. Esther. Aja. B and Nsirim. L. Edwin. Wosu and Martins and O. Ononyume}, title = {Monitoring and Assessment of Leaf Litter Dynamics in a Mixed Mangal Forest of the Cross River Estuary, Nigeria}, journal = {International Journal of Environmental Monitoring and Analysis}, volume = {2}, number = {3}, pages = {163-174}, doi = {10.11648/j.ijema.20140203.16}, url = {https://doi.org/10.11648/j.ijema.20140203.16}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijema.20140203.16}, abstract = {The leaf litter decomposition of Nypa fruticans, Rhizophora racemosa and Avicennia africana were studied across a tidal gradient in a mixed mangrove forest of the Cross River estuary Nigeria. Leaf litter decomposition was measured along the tidal gradients (low, mid, high) using litter bags. A single exponential model was used to study the decomposition rates of the leaves. Leaf decomposition varied significantly (P < 0.001) among species and spatially across tidal gradients over the study period. Decomposition was fastest in A. africana and slowest in N. fruticans and spatially, it was fastest at the low tide level and slowest at the high tide level. Tidal effects were much larger than species differences in the decomposition rates. The time (days) required for the loss of half the initial dry mass (T50) of the decomposing leaves at the low, mid and high tide levels were A. africana, 46, 57 and 77, R. racemosa 69, 86 and 115, and N. fruticans 86, 99 and 115 respectively. Estimates of leaf litter turnover rates showed that the actual litter turnover based on the relative measure of leaf litterfall and biomass on the forest floor (Kt) were much shorter than the projected litter turnover based on the leaf decomposition rates (Kd). The estimated actual residence times were less than one day while the projected residence times ranged from 83 to 142 days across tidal gradients, suggesting involvement of other ecological processes in litter loss and their possible transport into the Cross River estuary. The nitrogen contents and nutritional value of the decomposing leaves increased with time during the study. The increase varied significantly (P <0.001) among species, as well as temporally (P < 0.001) and spatially (P ≤ 0.05). The average C:N ratio decreased from 27.7 to 22.1 in A. africana, 26.4 to 23.9 in R. racemosa and 32.8 to 23.6 in N. fruticans. The overall changes in nutrients during decomposition indicated net mineralization. Mangrove leaf litter dynamics, trophic value and organic matter exchange of the system have implications on the productivity of the Cross River estuary and ultimately the Gulf of Guinea. Knowledge of these processes is critical for the maintenance and long term sustainability of the mangrove and surrounding ecosystems.}, year = {2014} }
TY - JOUR T1 - Monitoring and Assessment of Leaf Litter Dynamics in a Mixed Mangal Forest of the Cross River Estuary, Nigeria AU - Edu. Esther. Aja. B AU - Nsirim. L. Edwin. Wosu AU - Martins AU - O. Ononyume Y1 - 2014/07/10 PY - 2014 N1 - https://doi.org/10.11648/j.ijema.20140203.16 DO - 10.11648/j.ijema.20140203.16 T2 - International Journal of Environmental Monitoring and Analysis JF - International Journal of Environmental Monitoring and Analysis JO - International Journal of Environmental Monitoring and Analysis SP - 163 EP - 174 PB - Science Publishing Group SN - 2328-7667 UR - https://doi.org/10.11648/j.ijema.20140203.16 AB - The leaf litter decomposition of Nypa fruticans, Rhizophora racemosa and Avicennia africana were studied across a tidal gradient in a mixed mangrove forest of the Cross River estuary Nigeria. Leaf litter decomposition was measured along the tidal gradients (low, mid, high) using litter bags. A single exponential model was used to study the decomposition rates of the leaves. Leaf decomposition varied significantly (P < 0.001) among species and spatially across tidal gradients over the study period. Decomposition was fastest in A. africana and slowest in N. fruticans and spatially, it was fastest at the low tide level and slowest at the high tide level. Tidal effects were much larger than species differences in the decomposition rates. The time (days) required for the loss of half the initial dry mass (T50) of the decomposing leaves at the low, mid and high tide levels were A. africana, 46, 57 and 77, R. racemosa 69, 86 and 115, and N. fruticans 86, 99 and 115 respectively. Estimates of leaf litter turnover rates showed that the actual litter turnover based on the relative measure of leaf litterfall and biomass on the forest floor (Kt) were much shorter than the projected litter turnover based on the leaf decomposition rates (Kd). The estimated actual residence times were less than one day while the projected residence times ranged from 83 to 142 days across tidal gradients, suggesting involvement of other ecological processes in litter loss and their possible transport into the Cross River estuary. The nitrogen contents and nutritional value of the decomposing leaves increased with time during the study. The increase varied significantly (P <0.001) among species, as well as temporally (P < 0.001) and spatially (P ≤ 0.05). The average C:N ratio decreased from 27.7 to 22.1 in A. africana, 26.4 to 23.9 in R. racemosa and 32.8 to 23.6 in N. fruticans. The overall changes in nutrients during decomposition indicated net mineralization. Mangrove leaf litter dynamics, trophic value and organic matter exchange of the system have implications on the productivity of the Cross River estuary and ultimately the Gulf of Guinea. Knowledge of these processes is critical for the maintenance and long term sustainability of the mangrove and surrounding ecosystems. VL - 2 IS - 3 ER -