Malaysian
Journal of Analytical Sciences Vol 20 No 6 (2016): 1318 - 1328
DOI:
http://dx.doi.org/10.17576/mjas-2016-2006-10
DETERMINATION
OF TOTAL ORGANIC CARBON CONCENTRATION
IN
SURFICIAL SEDIMENTS OF SUNGAI PINANG, PENANG, MALAYSIA
(Penentuan
Jumlah Karbon Organik dalam Sedimen Permukaan di Sungai Pinang,
Pulau
Pinang, Malaysia)
Ong Meng Chuan*,
Fok Fei Mei, Yong Jaw Chuen
School
of Marine and Environmental Sciences
Universiti
Malaysia Terengganu, 21030 Kuala Terengganu, Terengganu, Malaysia
*Corresponding author: ong@umt.edu.my
Received: 17
August 2015; Accepted: 11 October 2016
Abstract
The concentration of total organic
carbon (TOC) and mean size sediment in a total of 24 samples of surficial
sediment were determined. From the results of study, the concentration of TOC
(5.33%) was found high nearby the housing area at Sungai Pinang. At the
downstream of the river tend to have higher concentration of TOC (1.05% - 5.33 %)
while at the upstream tend to have low degree of TOC in surficial sediments
(0.36% - 0.78%). The major contribution in TOC contamination at the bottom part
of the river maybe due to anthropogenic activities such as waste effluent from
urban runoff, industrial activities and boat activities. Apart from that, the
mean grain size was probably an important factor that influences the TOC
content in surficial sediment at Sungai Pinang. This is because the
distribution of the mean grain size that had similar trend to TOC. In addition,
the high correlation relationship between TOC and mean grain size were observed
and it had accounted for r = 0.67
owing to fine particles of sediment which had provided a large binding capacity
for the sorption of organic carbon. Moreover, fine sediment probably indicates
slow hydrodynamic energy at the downstream. It might affect the chemical
sorption process and allow the particulate organic carbon to accumulate at the
bottom of the water column. Thus, fine sediment maybe playing dominant role in
the content of TOC in surficial sediment at Sungai Pinang.
Keywords: total organic carbon, mean size sediment,
surficial sediments, Sungai Pinang
Abstrak
Kandungan jumlah karbon
organik (TOC) dan purata saiz sedimen di dalam 24 sampel sedimen permukaan
telah ditentukan. Dari hasil kajian ini, kepekatan TOC (5.33%) didapati tinggi
berhampiran dengan kawasan perumahan di Sungai Pinang. Di kawasan hilir sungai
tersebut mempunyai kepekatan TOC yang lebih tinggi (1.05% - 5.33%) manakala di
kawasan hulu sungai mempunyai kepekatan yang rendah dalam permukaan sedimen
(0.36% - 0.78%). Kemungkinan punca utama untuk pencemaran TOC di bahagian hilir
sungai adalah dari aktiviti antropogenik seperti sisa buangan daripada bandar,
aktiviti perindustrian dan aktiviti bot. Selain itu, purata saiz partikel
kemungkinan adalah faktor penting menpergaruhi kandungan TOC dalam sedimen
permukaan di Sungai Pinang. Ini kerana taburan purata saiz partikel mempunyai corak
yang sama dengan TOC. Tambahan pula, hubungan korelasi antara TOC dan purata
saiz partikel didapati tinggi dalam sedimen permukaan, iaitu r = 0.67 disebabkan saiz partikel yang
halus memperolehi kapasiti pengikatan yang luas untuk penyerapan karbon
organik. Selain itu, sedimen yang halus berkemungkinan menunjukkan tenaga
hidrodinamik yang perlahan di bahagian hiliran. Hal ini berkemungkinan mempengaruhi
proses penyerapan dan pengumpulan zarah karbon organik di bahagian bawah turus
air. Oleh itu, sedimen yang halus berkemungkinan besar memainkan peranan yang
paling dominan kepada kandungan TOC yang dalam sedimen permukaan di Sungai
Pinang.
Kata
kunci: jumlah karbon organik,
purata saiz sedimen, sedimen permukaan, Sungai Pinang
References
1. Lazăr, L., Gomoiu, M.T., Boicenco, L.
and Vasili, D. (2012). Total organic carbon (TOC) of the surface layer
sediments covering the seafloor of the Romanian black sea. Geo-Eco-Marina, 18: 121 – 132.
2. Hossain, G. M. and Bhuiyan, M. A. H.
(2016). Spatial and temporal variations of organic matter contents and
potential sediment nutrient index in the sundarbans mangrove forest,
Bangladesh. KSCE Journal of Civil
Engineering, 20 (1): 163 – 174.
3. Anawar, H. M., Yoshioka, T., Konohira,
E., Akai, J., Freitas, M. C. and Tareq, S. M. (2010). Sources of organic carbon
and depositional environment in the Bengal delta plain sediments during the
holocene period. Limnology, 11 (2):
133 – 142.
4. Manju, M. N., Resmi, P., Kumar,
Ratheesh, C. S., Gireeshkumar, T. R., Chandramohanakumar, N. and Joseph, M. M.,
(2016). Biochemical and stable carbon isotope records of mangrove derived
organic matter in the sediment cores. Environmental
Earth Sciences, 75: 565 – 580.
5. Naji, A., Ismail, A. and Ismail, A. R.
(2010). Chemical speciation and contamination assessment of Zn and Cd by sequential
extraction in surface sediment of Klang River, Malaysia. Microchemical
Journal, 95 (2): 285 – 292.
6. Kwaansa-Ansah,
E. E., Voegborlo, R. B., Adimado, A. A., Ephraim, J. H. and Nriagu, J. O.
(2012). Effect of pH, sulphate concentration and total organic carbon on
mercury accumulation in sediments in the volta lake at yeji, ghana, Bulletin of Environmental Contamination and
Toxicology, 88 (3): 418 – 421.
7. Shoham-Frider,
E., Azran, S. and Kress, N. (2012). Mercury speciation and total organic carbon
in marine sediments along the Mediterranean coast of Israel. Bulletin of Environmental Contamination and
Toxicology, 63 (4): 495 – 502.
8. Hall Jr, L. W. and Anderson, R. D.
(2014). Relationship of bifenthrin sediment concentrations to grain size and
total organic carbon in California waterbodies: Implications for ecological risk.
Bulletin of Environmental
Contamination and Toxicology, 93 (6): 764 – 768.
9. Zhao, C., Liu, S., Dong,
S., Isange, S., Liu, Q., An, N. and Li, X. (2015). Spatial and seasonal dynamics of organic carbon in
physically fractioned sediments associated with dam construction in the middle
Lancang-Mekong River. Journal of Soils
and Sediments, 15 (11): 2323 – 2333.
10. Mei, J., Li, Z., Sun,
L., Gui, H. and Wang, X. (2011). Assessment of heavy metals in the urban river
sediments in Suzhou City, Northern Anhui Province, China. Procedia
Environmental Sciences, 10:
2547 – 2553.
11.
Daud, H. (2008). The
water quality monitoring system/ program & pollution control.
Retrieved from Water Environment Partnership in Asia Web Site: http://www.wepa-db.net/pdf/0810malaysia/f.pdf
12. Usali, N. and Ismail,
M. H. (2010). Use of remote sensing and GIS in monitoring water quality. Journal
of Sustainable Development, 3 (3):
228 – 238.
13. Saad, F. N., Rahman,
N. N., Kadir, M. O. and Omar, F. M. (2008). Identification of pollution sources
within the Sungai Pinang River Basin. Proceeding
of the Malaysian Research Group International Conference, Manchester, United
Kingdom: pp. 478 – 485.
14. Dinakaran, J. and
Krishnayya, N. S. R. (2011). Variations in total organic carbon and grain size
distribution in ephemeral river sediments in Western India. International Journal of Sediment Research,
26 (2): 239 – 246.
15. Department of Environment (2012). Malaysia Environment Quality Report.
Department of Environment Malaysia: pp. 112.
16. Meng, J., Yao, P., Yu, Z., Bianchi, T.
S., Zhao, B., Pan, H. and Li, D. (2014). Speciation, bioavailability and
preservation of phosphorus in surface sediments of the Changjiang estuary and
adjacent East China Sea inner shelf. Estuarine,
Coastal and Shelf Science, 144: 27 – 38.
17. Maznah, W. O. and
Mansor, M. (2002). Aquatic pollution assessment based on attached diatom
communities in the Pinang River basin, Malaysia. Hydrobiologia, 481(1):
229 – 241.
18. Misnan, N. and Rindam,
M. (2012). Morfometri lembangan sungai-sungai utama di Pulau Pinang. Malaysia
Journal of Society and Space, 8(3):
71 – 81.
19. Ong, M., Menier, D.,
Shazili, N. and Kamaruzzaman, B. (2013). Geochemical characteristics of heavy
metals concentration in sediments of Quiberon Bay waters, South Brittany,
France. Oriental Journal of Chemistry, 29 (1): 39 – 45.
20. Sany, S. B., Salleh,
A., Rezayi, M., Saadati, N., Narimany, L. and Tehrani, G. M. (2013).
Distribution and contamination of heavy metal in the coastal sediments of Port
Klang, Selangor, Malaysia. Water, Air, and Soil Pollution, 224 (4): 1 – 18.
21. Tung J. W. T. and
Tanner, P. A. (2003). Instrumental determination of organic carbon in marine
sediment. Marine Chemistry, 80 (2-3):
161 – 170.
22. Folk, R. L. (1980). Petrology of sedimentary rocks Austin:
University of Texas Libraries
23. Ong, M. C., Kamaruzzaman,
B. Y., Shazili, N. A. and Rosnan, Y.
(2006). Distribution and normalization of lead, copper and zinc in Terengganu , Malaysia. Journal Sustainability Science
and Management, 1: 74 – 84.
24.
Plumb,
R. H. (1981). Procedures for handling
and chemical analysis of sediment and water samples. Retrieved
from United State Environmental Protection Agency: http://yosemite.epa.gov/r10/CLEANUP.NSF/ph/ T4+Technical+Documents/$F
25. Özkan, E. Y. (2012). A
New assessment of heavy metal contaminations in an eutrophicated bay (Inner
Izmir Bay, Turkey). Turkish Journal of Fisheries and Aquatic Sciences, 12: 135-147.
26. Swarnalatha, K.,
Letha, J. and Ayoob, S. (2013). An investigation into the heavy metal burden of
Akkulam–Veli Lake in South India. Environmental Earth Sciences, 68 (3): 795 – 806.
27. Ali, S. A. M., Payus,
C. and Ali, M. M. (2015). Surface sediment analysis on petroleum hydrocarbon
and total organic carbon from coastal area of Papar to Tuaran, Sabah. Malaysian Journal of Analytical Sciences,
19 (2): 318 – 324.
28. Okoro, H. K., Fatoki, O. S., Adekola, F.
A., Ximba,
B. J. and Snyman, R. G. (2016). Spatio-temporal variation of organotin
compounds in seawater and sediments from Cape Town Harbour, South Africa using gas
chromatography with flame photometric detector (GC-FPD). Arabian Journal of Chemistry, 9 (1): 95 – 104.
29. Mulligan, C., Fukue,
M. and Sato, Y. (2010). Sediment contamination
and sustainable remediation. London: CRC Press.
30. Li, G., Cao, Z., Lan,
D., Xu, J., Wang, S. and Yin, W. (2007). Spatial variations in grain size
distribution and selected metal contents in the Xiamen Bay, China. Environmetal
Geology, 52 (8): 1559 – 1567.
31. Naji, A. and Ismail, A. (2011). Assessment of metals contamination in Klang
River surface sediments by using different indexes. EnvironmentAsia, 4(1): 30 – 38.
32. Adnan, N. H., Zakaria, M. P.,
Juahir, H. and Ali, M. M. (2012). Faecal sterols as sewage markers in the
Langat River, Malaysia: Integration of biomarker and multivariate statistical
approaches. Journal of Environmental
Sciences, 24(9): 1600 – 1608.
33. Zhao, S., Feng, C., Wang, D., Liu, Y. and Shen, Z. (2013). Salinity increases
the mobility of Cd, Cu, Mn, and Pb in the sediments of Yangtze Estuary:
Relative role of sediments’ properties and metal speciation. Chemosphere, 91 (7): 977 – 984.
34. Hu, B., Cui, R., Li,
J., Wei, H., Zhao, J., Bai, F., Song, W. and Ding, X. (2013). Occurrence and distribution
of heavy metals in surface sediments of the Changhua River estuary and adjacent
shelf (Hainan Island). Marine Pollution Bulletin, 76 (1-2): 400 – 405.
35. Wang, F., Wang, W. X. and
Huang, X. P. (2012). Spatial distribution of gut juice extractable Cu, Pb and
Zn in sediments from the Pearl River Estuary, Southern China. Marine
Environmental Research, 77:
112 – 119.
36. Relić, D., Đorđević, D. and Popović, A. (2011). Assessment of the pseudo
total metal content in alluvial sediments from Danube River, Serbia. Environmental Earth Science, 63(6): 1303
– 1317.
37. Chen, L. G., Huang, Y. M., Peng, X. C., Xu, Z., Zhang, S., Ren, M., Ye, Z.
and Wang, X. (2009). PBDEs in sediments of the Beijiang River, China: Levels, distribution,
and influence of total organic carbon. Chemosphere,
76 (2): 226 – 231.
38. Wentworth C. K. (1922). A scale of
grade and class terms for clastic sediments.
Journal of Geology, 30: 377 – 392.
39. Satpathy, K. K.,
Mohanty, A. K., Prasad, M. V., Natesan, U. and Sarkar, S. K. (2012). Studies on
the variations of heavy metals in the marine sediments off Kalpakkam, East
Coast of India. Environmental Earth Science, 65 (1): 89 –101.
40. Kamaruzzaman, Y. and
Ong., M. C., (2009). Geochemical proxy of some chemical elements in sediments
of Kemaman River estuary, Terengganu, Malaysia. Sains Malaysiana, 38 (5): 631
– 636.
41. Idriss, A. A. and
Ahmad, A. K. (2013). Heavy metals nickel and chromiumin sediments in the Juru
River, Penang, Malaysia. Journal of Environmental Protection, 7: 1245 – 1253.
42. Huang, K. M. and Lin,
S. (2003). Consequences and implication of heavy metal spatial variations in
sediments of the Keelung River Drainage basin, Taiwan. Chemosphere, 53 (9): 1113 – 1121.