使用MODIS和MOPITT卫星数据监测震前异常

doi:10.11867/j.issn.1001-8166.2006.07.0695

地球科学进展 ›› 2006, Vol. 21 ›› Issue (7): 695 -698. doi: 10.11867/j.issn.1001-8166.2006.07.0695

郭广猛 ¹, 曹云刚 ¹, 龚建明 ²

1.中国科学院地理科学与资源研究所，北京 100101; 2.青岛海洋地质研究所，山东青岛 266071

收稿日期:2006-01-09 修回日期:2006-05-22 出版日期:2006-07-15
通讯作者: 郭广猛 E-mail:guogm@igsnrr.ac.cn
基金资助:
国家自然科学基金项目“东北地区特大森林火灾与地质构造的关系研究”（编号：30500393）资助.

Monitoring Anomaly before Earthquake with MODIS and MOPITT Data

Guo Guangmeng ¹, Cao Yungang ¹, Gong Jianming ²

1.Institute of Geographical Science and Natural Resources, Chinese Academy of Science,Beijing 100101,China;2.Institute of Marine Geology, Qingdao 266071,China

Received:2006-01-09 Revised:2006-05-22 Online:2006-07-15 Published:2006-07-15

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地震前温度异常以及CH₄、CO₂等气体的含量增加已经被人们逐渐认识，目前较多的研究集中在使用卫星热红外数据研究震前的温度异常，震前CH₄、CO₂等气体含量的增加却一直未能从卫星观测中实现。使用MODIS数据研究了2002年1月15日台湾5级地震前的海上温度异常，使用MOPITT数据研究了2002年3月31日台湾7.5级强震前的CO异常以及温度异常。研究发现温度异常区和CO高值区吻合，因此认为这种温度异常可能是由于地球排气作用而导致。

关键词: MODIS, MOPITT, CO, 震前异常

Temperature anomaly and gas anomaly such as methane and carbon dioxide before earthquake have been recognized for years. Many researchers have studied temperature anomalies with satellite thermal infrared data, while the gas anomaly has only been derived from limited ground measurements, and it is still not applicable in large areas. Here MODIS (Moderate Resolution Imaging Spectrometer) thermal infrared data is used to study the temperature increase before the Ms 5.0 Taiwan earthquake on January 15, 2002, and MOPITT (Measurements of Pollution in the Troposphere ) data is used to study the CO total column concentration before the Ms 7.5 Taiwan earthquake on March 31, 2002. It is found that there existed both high temperature area and high CO total column area near the Ms 7.5 earthquake epicenter and these two areas located at the same place. It is considered that this CO increase was caused by earth degassing. When these gases emit to atmosphere, they will also lead to temperature increase under the atmosphere electromagnetic field.

Key words: MODIS, MOPITT, CO, Anomaly before earthquake.

中图分类号:

P315.72
TP79

[1] Liu Chuang, Ge Chenghui. The characteristic and application of MODIS remote sensing data in America Earth Observing System (EOS)[J]. Remote Sensing Information, 2000,3:45-48.[刘闯,葛成辉.美国对地观测系统(EOS)中分辨率成像光谱仪(MODIS)遥感数据的特点与应用[J].遥感信息,2000,3:45-48.]

[2] Liu Chuang, Ge Chenghui. The data policy, technical standard and data localization of AQUA data in America Earth Observing System (EOS)[J]. Remote Sensing Information,2002,6:38-42.[刘闯,葛成辉.美国地球观测系统AQUA卫星数据政策、主要技术指标与数据本土化共享问题[J].遥感信息,2002,6:38-42.]

[3] Yuan Benfan, Li Changjun, Ge Zhijiang. Introduction of America new generation Earth observing system-TERRA[J]. Spacecraft Engineering,2001,10(3):60-66.[袁本凡,李长军,葛之江.美国新一代对地观测卫星EOS-TERRA概况[J].航天器工程,2001,10(3):60-66.]

[4] Qiang Zuji, Xu Xiudeng, Lin Changgong. Satellite thermal infrared anormaly—Precursor of impending earthquake[J]. Chinese Science Bulletin,1990,35(17):1 324-1 327.[强祖基,徐秀登,赁常恭.卫星热红外异常——临震前兆[J].科学通报,1990,35(17):1 324-1 327.]

[5] Qiang Zuji, Lin Changgong, Li Lingzhi, et al. Satellite thermal infrared brightness temperature anomal—Short term and impending earthquake precursors[J]. Science in China(D), 1998, 28(6):564-573.[强祖基,赁常恭,李玲芝,等.卫星热红外图像亮温异常——短临震兆[J].中国科学:D辑,1998,28(6):564-573.]

[6] Qiang Zuji, Kong Lingchang, Wang Yiping, et al. Earth degassing, thermal infrared anomaly and earthquake[J]. Chinese Science Bulletin, 1992, 37(24):2 259-2 262.[强祖基,孔令昌,王戈平,等.地球放气、热红外异常与地震活动[J].科学通报,1992,37(24):2 259-2 262.]

[7] Xu Xiudeng, Xu Xiangmin, Ma Shengdeng, et al. A preliminary study of atmosphere temperature increase before earthquake[J]. Acta Seismologica Sinica,1995,17(1):123-127.[徐秀登,徐向民,马升灯,等.临震大气增温异常成因的初步认识[J].地震学报,1995,17(1):123-127.]

[8] Huang Fulin,Zhang Xunhua,Xia Xianghua,et al. Distribution of methane and its homologues in low-layer atmosphere over eastern China and seas[J]. Chinese Science Bulletin,1998,43(16):1 767-1 771.[黄福林,张训华,夏响华,等.中国东部和海域低层大气甲烷及其同系物分布[J].科学通报,1998,43(16):1 767-1 771.]

[9] Lu Zhenquan,Qiang Zuji,Wu Bihao. A tentative interpretation of the formation of high temperature anomaly in satellite-based thermal infrared images of the South China Sea before earthquake[J]. Acta Geoscientia Sinica, 2002,23(1):42-46.[卢振权,强祖基,吴必豪.南海临震前卫星热红外增温异常原因初探[J].地球学报,2002,23(1):42-46.]

[10] Lu Zhenquan, Wu Bihao, Qiang Zuji, et al. Brightness temperature anomalies in satellite-based thermal infrared remote sensing along the offshore China seas[J]. Geoscience,2005,19(1):74-82. [卢振权,吴必豪,强祖基,等.中国近海海域卫星热红外亮温增温[J].现代地质,2005,19(1):74-82.]

[11] Che Yongtai, Yu Jinzi, Liu Wuzhou. Dynamic monitoring of degassing of the crust and prediction of the Zhangbei-Shangyi earthquake of magnitude 6.2[J]. Geological Review,1999,45(1): 59-65. [车用太,于金子,刘五洲.地壳放气动态监测与张北—尚义Ms 6.2级地震预报[J].地质论评,1999,45(1):59-65.]

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