Distributions and Fluxes of Nitrogen and Phosphorus Nutrients in Porewater Sediments in the Estuary of Jepara Indonesia

Maslukah, Lilik; Wulandari, Sri Yulina; Prasetyawan, Indra Budi; Zainuri, Muhammad

doi:10.12911/22998993/95093

Artykuł - szczegóły

Tytuł artykułu

Distributions and Fluxes of Nitrogen and Phosphorus Nutrients in Porewater Sediments in the Estuary of Jepara Indonesia

Autorzy

Maslukah Lilik , Wulandari Sri Yulina , Prasetyawan Indra Budi , Zainuri Muhammad

Treść / Zawartość

Pełne teksty:

8_Maslukah_Distributions and Fluxes_58-64.pdf

Pobierz

Identyfikatory

DOI

10.12911/22998993/95093

Warianty tytułu

Języki publikacji

Abstrakty

River is a location that is responsible for the main transport of nutrient flow from land to estuary and oceans. The nutrients that are adsorbed by the solid phase can be deposited and stored in the sediment. Sediments in estuaries and beaches have an important role in storing or removing nutrients from or to the water column. The presence of nutrients in porewater interacts with sediment and water column. In general, the nutrients that have a role as limiting factors for life in the waters are nitrogen (N) and phosphorus (P). The release of N and P elements is very important for the estuary and coastal environment, related to the process of regenerating nutrients into the water column. The release mechanism is determined by a diffusion process, based on the difference of concentration between the water column and the porewater. This study aims to determine the concentration of N and P in the porewater and estimate the value of flux. The sediment samples were taken from the Wiso and Serang estuary, Jepara. The components that were analyzed in the porewater are the concentration of N (nitrate, nitrite) and P (phosphate). Nitrite, nitrate and phosphate were determined by using sulphanilamide method and the molybdenum blue method, respectively. Furthermore, the flux value (F) was calculated based on the Fick’s I Law which was corrected by porosity. The results show that the mean concentrations of nitrate (NO₃^-), nitrite (NO₂^-) and phosphate (PO₄^2-) in the sediment water of Serang Estuary are 1.96, 1.41, 3.46 μM and in the Wiso estuary are 3.4, 1.85, 8.22 μM. In general, based on the calculation of flux, the sediments in the Serang and Wiso estuaries have a positive flux. Moreover, the sediment in Jepara acts as a source and releases N and P nutrient into the water column. The Wiso estuary has a higher flux than the Serang estuary.

Słowa kluczowe

pore water sediment flux nitrogen nutrient phosphorus nutrient Jepara

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2019

Tom

Vol. 20, nr 2

Strony

58--64

Opis fizyczny

Bibliogr. 32 poz., rys., tab.

Twórcy

autor

Maslukah Lilik

lilik_masluka@yahoo.com

Department of Oceanography, Faculty of Fisheries and Marine Sciences, Diponegoro University, Jl. Prof. Soedarto, SH., Semarang 50275, Indonesia

autor

Wulandari Sri Yulina

Department of Oceanography, Faculty of Fisheries and Marine Sciences, Diponegoro University, Jl. Prof. Soedarto, SH., Semarang 50275, Indonesia

autor

Prasetyawan Indra Budi

Department of Oceanography, Faculty of Fisheries and Marine Sciences, Diponegoro University, Jl. Prof. Soedarto, SH., Semarang 50275, Indonesia

autor

Zainuri Muhammad

Department of Oceanography, Faculty of Fisheries and Marine Sciences, Diponegoro University, Jl. Prof. Soedarto, SH., Semarang 50275, Indonesia

Bibliografia

1. APHA. 1992. Standard method for the examination of water and wastewater. 18th edition. Washington, 252p.
2. Bally G., Mesnage V., Deloffre J., Clarisse O., Lafite R., Dupont J.P. 2004. Chemical characterization of porewaters in an intertidal mudflat of the Seine Estuary: relationship to erosion-deposition cycles. Marine Pollution Bulletin, 49(3), 163–173.
3. Brigolin D., Lovato T., Rubino A., and Pastres R. 2011. Coupling early-diagenesis and pelagic biogeochemical models for estimating the seasonal variability of N and P fluxes at the sediment water interface: application to the NorthWestern Adriatic coastal zone. J. Marine Syst., 87, 239–255.
4. Callender E., Hammond D.E. 1982. Nutrient exchange across the sediment-water interface in the Potomac river estuary. Estuar Coast Shelf Sci., 33, 395–413.
5. Carter C.M., Ross A.H., Schiel D.R., Williams C.H., and Hayden B. 2005. In situ microcosm experiment on the influence of nitrate and light on phytoplankton community composition. J. Exp. Mar. Biol. Ecol., 326, 1–13.
6. Corredor J.E, Morell J.1985. Inorganic nitrogen in coral reef sediments. Mar Chem. 16, 379–384.
7. Denis L., Grenz C. 2003. Spatial variability in oxygen and nutrient fluxes at the sediment-water interface on the continental shelf in the Gulf of Lions (NW Mediterranean). Oceanologica Acta, 26(4), 373–389.
8. Gypens N., Borges A.V., and Lancelot, C. 2009. Effect of eutrophication on air–sea CO2 fluxes in the coastal Southern North Sea: a model study of the past 50 years. Global Change Biology, 15, 1040–1056.
9. Halpern B.S., Walbridge S., Selkoe KA., Kappel C.V., Micheli F., D’Agrosa C., Bruno J. F., Casey K.S., Ebert C., Fox H.E., Fujita R., Heinemann D., Lenihan H.S., Madin E.M., Perry M.T., Selig E.R., Spalding, M., Steneck R., and Watson R. 2008. A global map of human impacts on marine ecosystems. Science, 319, 948–952.
10. He T., Xie J., Yu H.S., Fang H., and Gao Q. 2008. The distribution of nutrients in the interstitial water and overlying water in Daya Bay. Acta Scientiae Circumstantiae, 28(11), 2361–2368.
11. Hopkinson Jr.C.S., Giblin A.E. and Tucker J. 2001. Benthic metabolism and nutrient regeneration on the continental shelf of Eastern Massachusetts, USA. Marine Ecology Progress Series, 224, 1–19.
12. Howarth R., Anderson D., Cloern J., Elfring C., Hopkinson C., Lapointe B., Malone T., Marcus N., Mc Glathery K., Sharpley A., and Walker D. 2000. Nutrient pollution of coastal rivers, bays, and seas. Issue in Ecology, 7, 1-15.
13. Hu C.Y., Pan J.M., Liu X.Y., et al., 2006. Study on distribution and benthic fluxes of nutrients in sediment interstitial water of the Southern Ocean. Acta Oceanologica Sinica, 28(4), 102–107. (in Chinese with English Abstract).
14. Jia J.J., Gao J.H., Liu Y.F., Gao S., and Yang Y. 2012. Environmental changes in Shamei Lagoon, Hainan Island, China : Interactions between natural processes and human activities. J. Asian Earth Sci., 52, 158–168.
15. Jin X., He Y., Kirumba G., Hassan Y., and Li J. 2013. Phosphorus fractions and phosphate sorption-release characteristics of the sediment in the Yangtze River estuary reservoir. Ecological Engineering, 55, 62–66.
16. Jones-Lee A., Lee G.F. 2005. Eutrophication (excessive fertilization).water encyclopedia: surface and agricultural water. Wiley, Hoboken, NJ. pp. 107–114.
17. Magni P and Montani S. 2006. Seasonal patterns of pore-water nutrients, benthic chlorophyll a and sedimentary AVS in a macrobenthos-rich tidal flat. Hydrobiologia, 571, 297–311.
18. Maslukah L., Indrayanti E. and Rifai A. 2014. Sebaran material organik dan zat hara oleh arus pasang surut di muara sungai Demaan, Jepara. Ilmu Kelautan, 19 (4), 189–194.
19. Maslukah L., Wulandari S.Y., and Prasetyawan I.B. 2016. Kontribusi nutrien N dan P dari sungai Serang dan Wiso ke perairan Jepara. Prosiding seminar nasional hasil-hasil penelitian perikanan dan kelautan ke-VI. Fakultas Perikanan dan Ilmu Kelautan – Pusat Kajian Mitigasi Bencana dan Rehabilitasi Pesisir, Undip. Pp. 183–191.
20. Maslukah L., Wulandari S.Y., and Setyawan I.B. 2017. Konsentrasi klorofil-a dan keterkaitannya dengan nutrient N, P di Perairan Jepara : Studi Perbandingan Perairan Muara Sungai Wiso dan Serang. Jurnal Kelautan Tropis, 20 (2), 72–77.
21. Mu D., Yuan D., Feng H., Xing F., Teo F.Y., and Li S. 2017. Nutrient fluxes across sediment-water interface in Bohai Bay Coastal Zone, China. Marine Pollution Bulletin, 114, 705–714.
22. Ni J.Y., Maggiulli M., Liu X. Y., et al., 2005. Pore water distribution and quantification of diffusive benthic fluxes of silicate, nitrate and phosphate in surface sediments of the Equatorial Northeastern Pacific. Geochimica, 34(6), 587–594.
23. PREP. 2009. State of the estuaries report. piscataqua region estuaries partnership, University of New Hampshire, Durham, NH. Published online on : www.prep.unh.edu/resources/pdf/2009_state_of_the-prep-09.pdf.
24. Qu T., Song Y. T. and Yamagata T. 2009. An introduction to the South China Sea throughflow: Its dynamics, variability, and application for climate. Dyn. Atmos. Oceans., 47, 3–14.
25. Robledo G., Bohorquez E. Corzo A., Jimenez-Arias J.L., and Papaspyrou, S. 2016. Dynamics of inorganic nutrients in intertidal sediments: porewater, exchangeable, and intracellular pools. Frontier in microbiology (7), 1–14.
26. Thibodeau B., Lehmann M. F., Kowarzyk J., Mucci A., Gelinas Y., Gilbert D., Maranger R., and Alkhatib M. 2010. Benthic nutrient fluxes along the Laurentian Channel: Impacts on the N budget of the St. Lawrence marine system. Estuarine, Coastal and Shelf Science, 90(4), 195−205.
27. Wallman K., Aloisi G., Haeckel M., Tishchenko P., Pavlova G., Greinert J., Kutterolf S., Eisenhaver A. 2008. Silicate weathering in an oxic marine sediments. Geochim.Cosmochim.Acta., 72, 2895–2918.
28. Warnken K., Gill G.A., Santschi P.H. and Griffin L.L. 2000. Benthic exchange of nutrients in Galveston Bay, Texas. Estuaries, 23(5), 647–661.
29. Wetzel R.G. and Likens G.E. 1991. Limnological analysis, 2nd.edn. Springer-Verlag, New York.
30. Ye X.W., Liu S.M., and Zhang J. 2002. Nutrients in sediment pore water in tidal flat area in Yalujiang Estuary. Environmental Science, 23(3), 92–96.
31. Zhang L., Yin K.D., Wang L., Chen F., Zhang D. and Yang Y. 2009. The sources and accumulation rate of sedimentary organic matter in the Pearl River Estuary and Adjacent Coastal Area, Southern China. Estuarine, Coastal and Shelf Science, 85(2), 190−196.
32. Zhang L., Wang K., Yin Y., Lü Y., Yang X., and Huang. 2014. Spatial and seasonal variations of nutrients in sediment profiles and their sedimentwater fluxes in the Pearl River Estuary, Southern China. Journal of Earth Science, 25(1), 197–206.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-7da6208a-44e2-41db-82c0-13b227ef2516