Abstract
Mesocosms in 25-m3 ethylene vinyl acetate or 4-m3 polyethylene bags were performed at two sites in China: Changjiang Estuary in spring–summer 1998, and Jiaozhou Bay in autumn 1999 and spring–summer 2000. The experiments were designed to show the contributions of physical, physicochemical and biological processes to self-purification of water with respect to the water-soluble fraction (WSF) of petroleum hydrocarbon associated with No.0 diesel (PHAD). Over the experimental periods, the WSF-PHAD concentration in water declined significantly. A kinetic model for WAS-PHAD distribution in multiphase environments – in this case water (W), suspended sediment (SS), phytoplankton (PPT), zooplankton (ZPT) and atmosphere (ATM) – was developed to estimate the contributions of the various processes. In the model, the key processes responsible for self-purification include (1) physical transport by volatilization from W to ATM; (2) biological transformation through biodegradation; (3) biological transfer involving bioconcentration by PPT and ZPT; and (4) physicochemical transfer through sorption by SS. Model parameters were determined from the mesocosm experiments and parallel laboratory experiments, or taken from the literature. It indicated that volatilization plays an important role in short-term self-purification especially regarding alkanes with relatively low molecular weight, accounting for 82.9±2.5%. After the volatilization stops, bioconcentration by PPT contributes greatly to long-term self-purification especially regarding alkanes of higher molecular weight and polycyclic aromatic hydrocarbons (PHAs), accounting for 0.7 – 17.8% with an average of 7.8±7.3%. The bioconcentration is dominated by biomass of PPT as well as the WSF-PHAD concentration. However, the biodegradation process makes the greatest contribution to both the short- and long-term self-purification, affecting alkanes of both lower and higher molecular weight as well as PHAs. The results suggest that it is necessary to take into account the biological processes of biodegradation and bioconcentration in estimating the self-purification of water with respect to oil pollutants.
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Ansari, Z. A. M., C. Saldanha & R. Rajkumar, 1997. Effects of petroleum hydrocarbons on the growth of a microalga, Isochrysis sp. (Chrysophyta). Ind. J mar. Sci. 26: 372–376.
Balzano, A., R. Pastres & C. Rossi, 1996. Coupling hydrodynamic and biochemical mathematical models for lagoon ecosystems. In Aldama, A. A., J. Aparicio, C. A. Brebbia, W. G. Gray, I. Herrera & G. F. Pinder (eds), 11th International Conference on Computational Methods in Water Resources. Cancun (Mexico): 375–382.
Berger, D. & D. Mackay, 1994. The evaporation of viscous or waxy oils — When is a liquid-phase resistance significant? 17th Arctic and Marine Oil Spill Program Technical Seminar, Vancouver (BC, Canada): 77–92.
Bhadauria, S., R. M. S. Sengar, S. Mittal & S. Bhattacharjee, 1992. Effect of petroleum hydrocarbons on algae. J. Phycol. 28 (3 suppl.): 16–21.
Chan, K. Y. & S. Y. Chiu, 1985. The effects of diesel oil and oil dispersants on growth, photosynthesis, and respiration of Chlorella salina. Arch. Environ. Contain. Toxicol. 14: 325–331.
Charbeneau, R. J. & J. W. Weaver, 1992. Modeling contaminant transport through subsurface systems. J. Hazard. Mater 32: 293–311.
Chen, C. M., J. L. Huang & F. Wu, 1992. Effects of low concentration of fuel oil Nos 0 and 20 accommodated in intertidal water on growth of marine phytoplankton. Hai Yang Tong Bao 11: 32–38.
Farrington, J. W., 1991. Biogeochemical processes governing exposure and uptake of organic pollutant compounds in aquatic organisms. Environ. Health Perspect 90: 75–84.
Fucik, K. W. & I. T Show, 1980. Environmental assessment of buccaneer gas and oil field in the northwestern Gulf of Mexico-Sources, fate and effects modeling. NOAATMNMFSSEFC43, National Marine Fisheries Service, Galveston (TX, USA): 149 pp.
Haitzer, M. & S. Höss, 1998. Effects of dissolved organic matter on the bioconcentration of organic chemicals in aquatic organisms: a review. Chemosphere 37: 1335–1362.
Han, X. R., 2000. Kinetics for uptake and release of nutrients by marine phytoplankton. Master thesis, Ocean University of Qingdao, Qingdao, China.
Hirose, K. & E Tanoue, 1997. The vertical distribution of the strong ligand in particulate organic matter in the North Pacific. Mar. Chem. 59: 235–252.
Hsieh, Y. P., M. B. Tomson & C. H. Ward, 1980. Toxicity of water-soluble extracts of No. 2 fuel oil to the freshwater alga Selenastrum capricornutum. Dev. Ind. Microbiol. 21: 401–409.
Krapivin, V. F. & Ba Lan, Huynh, 1994. Mathematical model for radionuclides, heavy metals, and petroleum hydrocarbons dynamics in the Arctic Basin. Morsk. Gidrofiz. Zh. 6: 41–60.
Krapivin, V. F., 1995. A simulation model for studying pollutant dynamics in the Arctic Ocean. Okeanologiya 35: 366–375.
Latimer, J. S. & J. G. Quinn, 1992. Role of resuspended sediments in the transport and bioaccumulation of toxic organic contaminants in nearshore marine environment. Rhode Island University, Kingston (U.S.A.) AFOSRTR929748: 18 pp.
Li, W. S., Q. X. Yang & J. Y. Xu, 1991. Study on the factors affecting the absorption processes of the petroleum hydrocarbons by mineral particles in seawater. Hai Yang Huan Jing Ke Xue 10: 42–45.
Mackay, D. & F. Wania, 1993. Transport of contaminants to the Arctic: Partitioning, processes and models. In Landers, D. H. & S. J. Christie (eds), International Symposium on the Ecological Effects of Arctic Airborne Contaminants. Reykjavik (Iceland): 5–38.
Novikov, M. A., V. V Kosheleva, E. A. Gorbacheva & A. M. Lapteva, 1996. Impact of natural factors on seawater selfpurification with removal of gas condensate hydrocarbons. Wat. Resour. 23: 529–532.
Ostroumov, S. A. & V. D. Fedorov, 1999. The most important components of self-purification of ecosystems and its possible impairment as a result of chemical pollution. Vestn. Mosk. Univ. Biol. 1: 24–32.
Panday, S., Y. S. Wu, P. S. Huyakorn, S. C. Wade & Z. A. Saleem, 1997. A composite numerical model for assessing subsurface transport of oily wastes and chemical constituents. J. Contam. Hydrol. 25: 1–2.
Pasichnyi, A. P., I. M. Velichko & A. I. Merezhko, 1995. Analysis and assessment of self-purification processes in the aquatic environment. Hydrobiol. J. 31: 1–9.
Premila, V. E. & M. U. Rao 1998. Effect of petroleum refinery and fertilizer factory effluents on marine algae of Visakhapatnam Coast. Phykos 37: 1–2.
Ricklefs, K. & G. Austen, 1994. Results of suspended matter and current measurements in the back barrier tidal flats of Sylt Island (North Sea/German Bight). Meyniana 46: 91–106.
Sebastiao, P. & C. Guedes-Soares, 1995. Modeling the fate of oil spills at sea. Spill Sci. Technol. Bull. 2: 2–3.
Shi, X. Y., X. L. Wang, Y. Jiang & X. R Han, 1999. Petroleum hydrocarbon associated with oil on and by plankton in a mesocosm experiment of East China Sea. In Watanabe, M. & M. Y. Zhu (eds), Proceedings of the Japan—China Joint Workshop on the Cooperative Study of the Maine Environment-Environmental Capacity and Effects of Pollutants on Marine Ecosystem in the East China Sea. National Institute for Environments, Tsukuba (Japan), JSSN 13413643: 89–96.
Siron, R., G. Giust, B. Berlandet, M. R. Morales-Loo & E. Pelletier, 1991. Water-soluble Petroleum compounds: chemical aspects and effects on the growth of microalgae, Sci. Tot. Environ. 104: 211–227.
SOA, 1991. Specifications of Oceanographic Survey, Ocean Press, Beijing: 766 pp.
SOA, 1996. Annual Report of China Marine Environment. SOA, Beijing, China.
SOA, 2000. Public Report of China Marine Environment in the End of 20th Century. SOA, Beijing, China.
Stewart, P. S., D. J. Dante, A. R. Lewis & E. Goldman, 1993. Biodegradation rates of crude oil in seawater. Wat. Environ. Res. 65: 845–848.
Sun, X. Q. & J. X. Zhang, 1987. Experiment on degradation of aromatic hydrocarbons by microorganisms from the Bohai Sea. Huang Bo Hai Hai Yang 5: 37–47.
Swackhamer, D. L. & R. S. Skoglund, 1993. Bioaccumulation of PCBs by algae: kinetics versus equilibrium. Environ. Toxi. Chem. 12: 831–838.
Swartz, R. C. & H. Lee II, 1980. Accumulation, Trophic Transfer, Biodegradation and Migration. In Baker, R. A. (ed.), Biological Processes Affecting the Distribution of Pollutants in Marine Sediments. U.S. EPA, 15BN0250403072: 533–553.
Watanabe, M. & M. Y. Zhu, 1999. Proceedings of the Japan-China Joint Workshop on the Cooperative Study of the Maine Environment-Environmental Capacity and Effects of Pollutants on Marine Ecosystem in the East China Sea. ISSN 13413643, National Institute for Environmental Studies, Tsukuba, Japan: 185 pp.
Werner, M. D., V. D. Adams V. A. Lamarra & N. L. Winters, 1985. Responses of model freshwater ecosystems to crude oil. Wat. Res. 19: 285–292.
Wiedemeier, T. H., M. A. Swanson, J. T. Wilson, D. H. Kampbell, R. N. Miller & J. E. Hansen, 1996. Approximation of biodegradation rate constants for monoaromatic hydrocarbons (BTEX) in ground water. Ground Water Monit. Remediat. 16: 186–195.
Wolfe, M. F., G. J. B. Schwartz, S. Singaram, E. E. Mielbrecht, R. S. Tjeerdema & M. L. Sowby, 1998a. Effects of salinity and temperature on the bioavailability of dispersed petroleum hydrocarbons to the golden-brown algae. Arch. Environ. Contam. Toxicol. 35: 268–273.
Wolfe, M. F., G. J. B. Schwartz, S. Singaram, E. E. Mielbrecht, R. S Tjeerdema & M. L. Sowby, 1998b. Influence of dispersants on the bioavailability of naphthalene from the water-accommodated fraction crude oil to the golden-brown algae, Isochrysis galbana. Arch. Environ. Contam. Toxicol. 35: 274–280.
Wu, S. C. & D. M. Gachwend, 1986. Sorption kinetics of hydrophobic organic compounds to natural sediments and soils. Environ. Sci. Technol. 20: 717–725.
Xie, Q., D. M. Xue, Y. Z. Zhao, F. L. Yang & C. D. Piao, 1997. Estimation of the volatilization coefficients for the volatile organic chemicals in Dalian Bay. Hai Yang Huan Jing Ke Xue 16: 25–28.
Xu, K. C., 1992. The study of the marine environment and pollution survey in Chinese offshore. Hai Yang Huan Jing Ke Xue 11: 12–17.
Ye, D.Z., C. Z. Ni, Z. C. Zhou R. M. Yao, H. S. Zeng & Y. S. Lin, 1995. Bacterial kinetics and environmental capacity in the Western Xiamen Harbour. Acta Oceanol. Sinica 14: 247–259.
Yentsch, C. S. & D. W. Menzel, 1963. A method for the determination of phytoplankton chlorophyll and phaeophytin by fluorescence. Deep-Sea Res. 10: 221–231.
Yue, G. C., 1990. A simulation study on degradation of petroleum hydrocarbons in bays and river. Hai Yang Ke Xue 1990: 42–44.
Zhang, L. P., L. F. Wang & W. Q. Chen, 1994. Effect of oil-kinds and microbiological degradation on weathering model of petroleum hydrocarbon in seawater. Xia Men Da Xue Xue Bao 33: 226–230.
Zhang, Y. Y., Q. H. Zheng, Y. Q. He W. Y. Wen, M. Z. Zheng & X. Y. Liang, 1995. An experimental study on the self-purification of CODMn, oil and As in the mixing area of saltwater and freshwater in Zhujiang River estuary. Re Dai Hai Yang 14: 67–74.
Zhou, Q. X. & Y. M. Zhu, 1997. Pollution monitoring of marine organisms grown in the Zhoushan Sea of China. J. Environ. Sci. China 9: 288–292.
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Wang, X., An, Y., Zhang, J. et al. Contribution of biological processes to self-purification of water with respect to petroleum hydrocarbon associated with No. 0 diesel in Changjiang Estuary and Jiaozhou Bay, China. Hydrobiologia 469, 179–191 (2002). https://doi.org/10.1023/A:1015550921829
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DOI: https://doi.org/10.1023/A:1015550921829