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1860797493761015808
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INTELEK Repository
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Online Access
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https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072
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2016-05-11 15:21:06
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Restricted Document
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12961
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UniSZA
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1. Toriman, M.E, Gasim, M. B., Yusop, Z., Shahid, I., Mastura, S. A. S., Abdullah, P., Jaafar, M., Abd Aziz, N. A., Kamarudin, M. K. A., Jaafar, O., Karim, O., Juahir, H. and Jamil, N. R. (2012). Use of 137Cs activity to investigate sediment movement and transport modeling in river coastal environment. American Journal of Environmental Sciences, 8 : 417 – 423. 2. Kamarudin, M. K. A., Toriman, M. E., Rosli, M. H., Juahir, H., Azid, A., Mohamed Zainuddin, S. F., Abdul Aziz, N. A. and Sulaiman, W. N. A. (2015). Analysis of meander evolution studies on effect from land use and climate change at upstream reach of Pahang River, Malaysia. Mitigation and Adaptation Strategies for Global Change, 20:1319 – 1334. 3. Velmurugan, A., Gopal K., Dadhwal, V. K. Kumar, S., Swarnam, T. P. and Saha, S.K.(2009). Harmonizing soil organic carbonestimates in historical and current data. Current Science, 97(4): 12 – 22 4. Azid, A., Che Hasnam, C. N., Juahir, H., Amran, M. A., Toriman, M. E., Kamarudin, M. K. A., Mohd Saudia, M. S., Gasim, M. B. and Mustafa, A. D. (2015). Coastal erosion measurement along Tanjung Lumpur to Cherok Paloh, Pahang during the northeast monsoon season. Jurnal Teknologi, 74 (1): 27 – 34. 5. Kamarudin, M. K. A., Toriman, M. E., Sarifah A., S. M, Idris, M., Jamil, N. R. and Gasim, M. B. (2009). temporal variability on lowland river sediment properties and yield. American Journal of Environmental Sciences, 5(5): 657 – 663. 6. Zerva, A. and Maurizio M. (2005). Carbon stock changes in a peaty gluey soil profile after afforestation with Sitka spruce (Picea sitchensis). Annals Forest Science, 62: 873 – 880. 7. Thornley J. H. M. and Cannell, M. G. R. (2001). Soil carbon storage response to temperature: an hypothesis. centre for ecology & hydrology, Bush Estate, Penicuik, Midlothian, UK Annals of Botany, 87: 591 – 598. 8. Sahibin, A. R., Mohd. Nizam, M.S. and Izzat Hidayat, I. (2004/05). Physico-chemical characteristics of soil at Sg. Cheruai in the national park at Merapoh Pahang. Journal Wildlife and Parks, 22: 145 - 152. 9. Steinbeiss, S., Temperton, V. M. and.Gleixner, G. (2007). Mechanisms of soil carbon storage in experimental grasslands. Biogeosciences Discuss., 4, 3829 – 3862. 10. Abdullah, N. M., Toriman, M. E., Md Din, H., Abd Aziz, N. A., Kamarudin, M. K. A., Abdul Rani, N. S., Ata, F. M., Saad, M. H., Abdullah, N. W., Idris, M. and Jamil, N. R. (2013). Influence of spatial and temporal factors in determining rainfall interception at dipterocarp forest canopy, Lake Chini, Pahang. Malaysian Journal of Analytical Sciences, 17 (1): 11 – 23. 11. Yuanhe, Y., Ngyun, F., Yanhong, T., Chengjun, J., Chengyang Z., Jinsheng H. and Biao Z. (2008). Storage, patterns and controls of soil organic carbon in the Tibetan grasslands. Global Change Biology 14: 1592 – 1599 12. Veldkamp, E., Becker, A., Schwendenmann, L., Clark. D. A, and Schult-Bisping. H (2003). Substantial labile carbon stocks and microbial activity in deeply weathered soils below a tropical wet forest. Global Change Biology, 9: 1171 – 1184. 13. Steinbeiss, S., Temperton, V. M. and Gleixner, G. (2007). Mechanisms of soil carbon storage in experimental grasslands. Biogeosciences Discuss, 4: 3829 – 3862. 14. D’bek-Szreniawska, M. and Balashov, E (2007). Seasonal changes in labile organic matter, mineral nitrogen, and N2O emission in a loamy sand Orthic Luvisol cultivated under three management practices. International Agrophysics , 21: 127 – 132. 15. Zulfahmi, A. R., Jasni, Y., Sahibin, A. R. Gasim, M. B. and Ramlan, O. (2002). Preliminary survey of landslide occurrences along main road of gap-Fraser's Hill, Pahang. Proceedings of the Regional Symposium on Environment and Natural Resources, 1: 745 – 751. 16. Noraini M.T. (2002). The use of selected geo-materials for erosion and sediment control at Fraser’s Hill. Proceedings of the Regional Symposium on Environment and Natural Resources, 1: 305 – 312. 17. Metson, A. J. (1956). Methods of chemical analysis for soil survey samples. Bulletin of the New Zealand Department of Industrial Research. No. 12. 18. Rowell, D.L. (1994). Soil science: method and applications. Singapore: Longman Singapore Publishers (Pte) Ltd. 19. Avery, B. W. and Bascomb, C. L. (1982). Soil survey laboratory methods. Soil Survey Technical Monograph No. 6. Harpenden. 20. Bationo A. and Buerkert A. (2001). Soil organic carbon management for sustainable land use in the SudanoSahelian West Africa. Nutrient Cycling in Agroecosystems 61:131 – 142. 21. Richard V. Pouyat, Ian D. Yesilonis Nancy E. Golubiewski. (2009). A comparison of soil organic carbon stocks between residential turf grass and native soil. Urban Ecosyst, 12:45 – 62 22. Reese, R. E. and Moorhead, K. K.. (1996). Spatial characteristics of soil pro:perties along an elevational gradient in a Carolina Bay wetland. Soil Science Society American Journal, 60: 1273 – 1277. 23. Zhuang, Q., Li, Q., Jiang, Y., Liang, W. and Steinberger, Y. (2005). Vertical distribution of soil organic carbon in agrosystems of Songliao Plain along a latitudinal gradient. American-Eurasian Journal of Agriculture and Environment Science, 2(2): 127 – 132. 24. Henry. M., Valentini. R., and Bernoux. M (2009). Soil carbon stocks in ecoregions of Africa. Biogeosciences Discussions, 6: 797 – 823. 25. Officer, S. J., Kravchenko, A., Bollero, G. A., Sudduth, K. A., Kitchen, N. R. and Wiebold. W. J. (2004). Relationships between soil bulk electrical conductivity and the principal component analysis of topography and soil fertility values. Plant and Soil, 258: 269 – 280.
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norman
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oai_dc
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https://intelek.unisza.edu.my/intelek/pages/view.php?ref=12961
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12961 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=12961 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal image/jpeg inches 96 96 norman 49 49 1425 2016-05-11 15:21:06 719 1425x719 7268-01-FH02-ESERI-16-05809.jpg UniSZA Private Access Analysis of seasonal soil organic carbon content at bukit Jeriau forest, Fraser Hill, Pahang Malaysian Journal of Analytical Sciences Soil carbon is the carbon held within the soil, primarily in association with its organic content. The total soil organic carbon study was determined in a plot at Bukit Jeriau forest in Bukit Fraser, Pahang, Malaysia. The aim of this study is to determine the changing of soil organic carbon between wet season and dry season. Soil organic carbon was fined out using titrimetric determination. The soil organic carbon content in wet season is 223.24 t/ha while dry season is 217.90 t/ha. The soil pH range in wet season is between 4.32 to 4.45 and in dry season in 3.95 to 4.08 which is considered acidic. Correlation analysis showed that soil organic carbon value is influenced by pH value and climate. Correlation analysis between clay and soil organic carbon with depth showed positively significant differences and clay are very much influenced soil organic carbon content. Correlation analysis between electrical conductivity and soil organic carbon content showed negative significantly difference on wet season and positively significant different in dry season. 20 2 Malaysian Society of Analytical Sciences Malaysian Society of Analytical Sciences 452-460 1. Toriman, M.E, Gasim, M. B., Yusop, Z., Shahid, I., Mastura, S. A. S., Abdullah, P., Jaafar, M., Abd Aziz, N. A., Kamarudin, M. K. A., Jaafar, O., Karim, O., Juahir, H. and Jamil, N. R. (2012). Use of 137Cs activity to investigate sediment movement and transport modeling in river coastal environment. American Journal of Environmental Sciences, 8 : 417 – 423. 2. Kamarudin, M. K. A., Toriman, M. E., Rosli, M. H., Juahir, H., Azid, A., Mohamed Zainuddin, S. F., Abdul Aziz, N. A. and Sulaiman, W. N. A. (2015). Analysis of meander evolution studies on effect from land use and climate change at upstream reach of Pahang River, Malaysia. Mitigation and Adaptation Strategies for Global Change, 20:1319 – 1334. 3. Velmurugan, A., Gopal K., Dadhwal, V. K. Kumar, S., Swarnam, T. P. and Saha, S.K.(2009). Harmonizing soil organic carbonestimates in historical and current data. Current Science, 97(4): 12 – 22 4. Azid, A., Che Hasnam, C. N., Juahir, H., Amran, M. A., Toriman, M. E., Kamarudin, M. K. A., Mohd Saudia, M. S., Gasim, M. B. and Mustafa, A. D. (2015). Coastal erosion measurement along Tanjung Lumpur to Cherok Paloh, Pahang during the northeast monsoon season. Jurnal Teknologi, 74 (1): 27 – 34. 5. Kamarudin, M. K. A., Toriman, M. E., Sarifah A., S. M, Idris, M., Jamil, N. R. and Gasim, M. B. (2009). temporal variability on lowland river sediment properties and yield. American Journal of Environmental Sciences, 5(5): 657 – 663. 6. Zerva, A. and Maurizio M. (2005). Carbon stock changes in a peaty gluey soil profile after afforestation with Sitka spruce (Picea sitchensis). Annals Forest Science, 62: 873 – 880. 7. Thornley J. H. M. and Cannell, M. G. R. (2001). Soil carbon storage response to temperature: an hypothesis. centre for ecology & hydrology, Bush Estate, Penicuik, Midlothian, UK Annals of Botany, 87: 591 – 598. 8. Sahibin, A. R., Mohd. Nizam, M.S. and Izzat Hidayat, I. (2004/05). Physico-chemical characteristics of soil at Sg. Cheruai in the national park at Merapoh Pahang. Journal Wildlife and Parks, 22: 145 - 152. 9. Steinbeiss, S., Temperton, V. M. and.Gleixner, G. (2007). Mechanisms of soil carbon storage in experimental grasslands. Biogeosciences Discuss., 4, 3829 – 3862. 10. Abdullah, N. M., Toriman, M. E., Md Din, H., Abd Aziz, N. A., Kamarudin, M. K. A., Abdul Rani, N. S., Ata, F. M., Saad, M. H., Abdullah, N. W., Idris, M. and Jamil, N. R. (2013). Influence of spatial and temporal factors in determining rainfall interception at dipterocarp forest canopy, Lake Chini, Pahang. Malaysian Journal of Analytical Sciences, 17 (1): 11 – 23. 11. Yuanhe, Y., Ngyun, F., Yanhong, T., Chengjun, J., Chengyang Z., Jinsheng H. and Biao Z. (2008). Storage, patterns and controls of soil organic carbon in the Tibetan grasslands. Global Change Biology 14: 1592 – 1599 12. Veldkamp, E., Becker, A., Schwendenmann, L., Clark. D. A, and Schult-Bisping. H (2003). Substantial labile carbon stocks and microbial activity in deeply weathered soils below a tropical wet forest. Global Change Biology, 9: 1171 – 1184. 13. Steinbeiss, S., Temperton, V. M. and Gleixner, G. (2007). Mechanisms of soil carbon storage in experimental grasslands. Biogeosciences Discuss, 4: 3829 – 3862. 14. D’bek-Szreniawska, M. and Balashov, E (2007). Seasonal changes in labile organic matter, mineral nitrogen, and N2O emission in a loamy sand Orthic Luvisol cultivated under three management practices. International Agrophysics , 21: 127 – 132. 15. Zulfahmi, A. R., Jasni, Y., Sahibin, A. R. Gasim, M. B. and Ramlan, O. (2002). Preliminary survey of landslide occurrences along main road of gap-Fraser's Hill, Pahang. Proceedings of the Regional Symposium on Environment and Natural Resources, 1: 745 – 751. 16. Noraini M.T. (2002). The use of selected geo-materials for erosion and sediment control at Fraser’s Hill. Proceedings of the Regional Symposium on Environment and Natural Resources, 1: 305 – 312. 17. Metson, A. J. (1956). Methods of chemical analysis for soil survey samples. Bulletin of the New Zealand Department of Industrial Research. No. 12. 18. Rowell, D.L. (1994). Soil science: method and applications. Singapore: Longman Singapore Publishers (Pte) Ltd. 19. Avery, B. W. and Bascomb, C. L. (1982). Soil survey laboratory methods. Soil Survey Technical Monograph No. 6. Harpenden. 20. Bationo A. and Buerkert A. (2001). Soil organic carbon management for sustainable land use in the SudanoSahelian West Africa. Nutrient Cycling in Agroecosystems 61:131 – 142. 21. Richard V. Pouyat, Ian D. Yesilonis Nancy E. Golubiewski. (2009). A comparison of soil organic carbon stocks between residential turf grass and native soil. Urban Ecosyst, 12:45 – 62 22. Reese, R. E. and Moorhead, K. K.. (1996). Spatial characteristics of soil pro:perties along an elevational gradient in a Carolina Bay wetland. Soil Science Society American Journal, 60: 1273 – 1277. 23. Zhuang, Q., Li, Q., Jiang, Y., Liang, W. and Steinberger, Y. (2005). Vertical distribution of soil organic carbon in agrosystems of Songliao Plain along a latitudinal gradient. American-Eurasian Journal of Agriculture and Environment Science, 2(2): 127 – 132. 24. Henry. M., Valentini. R., and Bernoux. M (2009). Soil carbon stocks in ecoregions of Africa. Biogeosciences Discussions, 6: 797 – 823. 25. Officer, S. J., Kravchenko, A., Bollero, G. A., Sudduth, K. A., Kitchen, N. R. and Wiebold. W. J. (2004). Relationships between soil bulk electrical conductivity and the principal component analysis of topography and soil fertility values. Plant and Soil, 258: 269 – 280.
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| spellingShingle |
Analysis of seasonal soil organic carbon content at bukit Jeriau forest, Fraser Hill, Pahang
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| summary |
Soil carbon is the carbon held within the soil, primarily in association with its organic content. The total soil organic carbon study was determined in a plot at Bukit Jeriau forest in Bukit Fraser, Pahang, Malaysia. The aim of this study is to determine the changing of soil organic carbon between wet season and dry season. Soil organic carbon was fined out using titrimetric determination. The soil organic carbon content in wet season is 223.24 t/ha while dry season is 217.90 t/ha. The soil pH range in wet season is between 4.32 to 4.45 and in dry season in 3.95 to 4.08 which is considered acidic. Correlation analysis showed that soil organic carbon value is influenced by pH value and climate. Correlation analysis between clay and soil organic carbon with depth showed positively significant differences and clay are very much influenced soil organic carbon content. Correlation analysis between electrical conductivity and soil organic carbon content showed negative significantly difference on wet season and positively significant different in dry season.
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| title |
Analysis of seasonal soil organic carbon content at bukit Jeriau forest, Fraser Hill, Pahang
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| title_full |
Analysis of seasonal soil organic carbon content at bukit Jeriau forest, Fraser Hill, Pahang
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| title_fullStr |
Analysis of seasonal soil organic carbon content at bukit Jeriau forest, Fraser Hill, Pahang
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| title_full_unstemmed |
Analysis of seasonal soil organic carbon content at bukit Jeriau forest, Fraser Hill, Pahang
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| title_short |
Analysis of seasonal soil organic carbon content at bukit Jeriau forest, Fraser Hill, Pahang
|
| title_sort |
analysis of seasonal soil organic carbon content at bukit jeriau forest, fraser hill, pahang
|