光谱学与光谱分析 |
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Study on Spectrum of Oil Film in Ice-Infested Waters |
LI Ying, LIU Bing-xin, LAN Guo-xin, MA Long, GAO Chao |
Institute of Environmental Information, Dalian Maritime University, Dalian 116026, China |
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Abstract Oil spills in ice-infested waters are a subject of great concern to corporations, local residents, and government agencies, which participate in oil exploration, production, and transportation in ice-infested regions recently. For developing a credible and effective response to oil spill in ice-infested waters, a field experiment was performed on the spectrum of oil film in ice-infested waters. In this experiment, four groups of spectrum samples were collected, including clean sea water, brash ice and even ice and sea water /brash ice /even ice contaminated by diesel and crude oil. The experiment results indicated that: the same sort of oil with different background had different reflectance at the same wavelength, and so did the same sort of oil with the same background but different distribution state; nevertheless there were some common characteristics within the same oil. For example, diesel had two apparent characteristics, no matter on the surface of sea water or brash ice or even ice, the first of which was that the reflectance curves of diesel film were first lower and then higher than that of clean sea water, brash ice or even ice according to the wavelength; the second was that the reflectance curves of diesel film were almost equaled to that of the background between 400 and 510 nm in sea water, 410 and 510 nm in brash ice and 490 and 510 nm in even ice. The spectrum curves of crude oil had a representative sphenoid reflectance-peak which appeared between 750 and 770 nm. These characteristics of oil film in terms of ice and oil type could be effectively used to distinct the oil with sea water and sea ice, meanwhile this experiment would improve and facilitate the detecting and monitoring proposal of oil which had been spilled in moving, broken pack ice and fast-ice environment in the ocean.
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Received: 2009-05-05
Accepted: 2009-08-06
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Corresponding Authors:
LI Ying
E-mail: yldmu@126.com
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[1] LI Zhi-jun(李志军). China Offshore Platform(中国海洋平台), 2000, 15(5): 20. [2] Nuka Research and Planning Group. Oil Spill Response Challenges in Arctic Waters. Oslo:WWF International Arctic Programme, 2007. [3] YU Jia-ai, WANG Ren-shu, CHEN Wei-bin et al(余加艾,王仁树,陈伟斌,等). Marine Environmental Science(海洋环境科学),1997, 16(1): 72. [4] Dickins D,Buist I. Journal of Pure and Applied Chemistry, 1999,71(1):173. [5] D F Dickins Associates Ltd. Detection and Tracking of Oil Under Ice, 2000. 1. [6] Dickins D F. Advancing Oil Spill Response in Ice Covered Waters, 2004. 1. [7] Jha Maya Nand, Levy Jason, Gao Yang. Sensors, 2008, 8: 236. [8] Praks Jaan, Eskelinen Miia, Pulliainen Jouni, et al. Geoscience and Remote Sensing Symposium,IEEE International, 2004, 1: 273. [9] ZHAO Dong-zhi, CONG Pi-fu(赵冬至,丛丕福). Remote Sensing Technology and Application(遥感技术与应用), 2000, 15(3): 160. [10] ZHANG Yong-ning, DING Qian, GAO Chao,et al(张永宁,丁 倩,高 超,等). Marine Environmental Science(海洋环境科学), 2000, 19(3): 5. [11] LU Ying-cheng, TIAN Qing-jiu, WANG Jing-jing, et al(陆应诚,田庆久,王晶晶,等). Chinese Science Bulletin(科学通报), 2008, 53(9): 1085. [12] MA Yi, ZHANG Jie, ZHANG Han-de, et al(马 毅,张 杰,张汉德,等). Advances in Marine Science(海洋科学进展), 2002, 20(4): 94. [13] PANG Shi-ping, ZHENG Xiao-ling, HE Ying,et al(庞士平,郑晓玲,何 鹰,等). Advances in Marine Science(海洋科学进展), 2007, 25(1): 91. [14] CUI Zhi-cheng, LIU Wen-qing, ZHAO Nan-jing,et al(崔志成,刘文清,赵南京,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2008, 28(6): 1332. [15] Li Ying, Yu Shuiming, Ma Long, et al. Satellite Image Processing and Analyzing for Marine Oil Spill. Guangzhou: SPIE, 2008, 71450c-1. [16] Li Ying, Liu Yu, Ma Long, et al. Oil Spill Monitoring Using MODIS Data. The Second International Conference on Space Information Technology, 24-25, November, Wuhan, 2007. [17] ZHAO Ying-shi, et al(赵英时,等). Theory and Method of Remote Sensing Application and Analysis(遥感应用分析原理与方法). Beijing: Science Press(北京:科学出版社), 2003.
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