RESEARCH ON DETECTION AND ACTIVITY OF THE HENGGANG BRICKYARD FAULT IN RUICHANG CITY, JIANGXI PROVINCE

QI Xin; SHAO Chang-sheng; CHEN Zhou-feng; CHEN Li-de

2016 Vol. 22, No. 3

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Article navigation > Journal of Geomechanics > 2016 > 22(3): 594-601

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QI Xin, SHAO Chang-sheng, CHEN Zhou-feng, CHEN Li-de. RESEARCH ON DETECTION AND ACTIVITY OF THE HENGGANG BRICKYARD FAULT IN RUICHANG CITY, JIANGXI PROVINCE[J]. Journal of Geomechanics, 2016, 22(3): 594-601.

Citation:

QI Xin, SHAO Chang-sheng, CHEN Zhou-feng, CHEN Li-de. RESEARCH ON DETECTION AND ACTIVITY OF THE HENGGANG BRICKYARD FAULT IN RUICHANG CITY, JIANGXI PROVINCE[J]. Journal of Geomechanics, 2016, 22(3): 594-601.

RESEARCH ON DETECTION AND ACTIVITY OF THE HENGGANG BRICKYARD FAULT IN RUICHANG CITY, JIANGXI PROVINCE

Wuhan Center, China Geological Survey, Wuhan 430223, China

Received Date: 05 May 2016

Publish Date: 25 September 2016

Abstract

Abstract

In the fault activity survey, we found much more fissures in the Henggang Brickyard in Ruichang City, Jiangxi province. The overall trend of the fissures is NE, the fissures distribute densely in a "cluster" shape, with length more than three hundreds. And filled by gray-white and light gray minerals Through the analysis, this paper considers that there is a north-east trend steep normal fault, with south-east strike and dip angle 60°~75°. Local trench excavation exposes that one of the fault planes diastrophism the Quaternary slope alluvial material, the fault occurrence is 155°∠71°, fault strike NE 65°, upside down, stagger distance up to 3 m (not reveal bottom). The fault is straight, we can clearly visible scratches on the fault plane, and five 1~2 m long scraping grooves with 5~20 m deep. These display the fault is left-lateral dip-slip. Through ESR to date the strata sediment from upper breakpoint, the age range is 0.27~0.42 Ma. Research showes that this fault is significantly active in Middle Pleistocene, it is a Middle Pleistocene active fault. It is analysed that the development of ground fissures in this area are controlled by the Henggang Brickyard fracture, the forming of fissures responded to the activity of Henggang Brickyard fracture in Quaternary.
- fissure /
- active fault /
- ESR dating /
- high density resistivity method

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References

[1]	曾文敬, 赵爱平, 汤兰荣.九江-瑞昌5.7级地震余震震源机制解[J].大地测量与地球动力学, 2009, 29(4):42~47. Google Scholar ZENG Wen-jing, ZHAO Ai-ping, TANG Lan-rong. Focal mechanism solutions of aftershocks of Jiujiang-Ruichang earthquake[J]. Journal of Geodesy and Geodynamics, 2009, 29(4):42~47. Google Scholar
[2]	吕坚, 曾文敬, 谢祖军.2011年9月10日瑞昌-阳新4.6级地震的震源破裂特征与区域强震危险性[J].地球物理学报, 2012, 55(11):3625~3633. doi: 10.6038/j.issn.0001-5733.2012.11.011 CrossRef Google Scholar LÜ Jian, ZENG Wen-jing, XIE Zu-jun. Rupture characteristics of the Ms4.6 Ruichang-Yangxin earthquake of Sep.10, 2011 and the strong earthquake risk in the region[J]. Chinese Journal of Geophysics, 2012, 55(11):3625~3633. doi: 10.6038/j.issn.0001-5733.2012.11.011 CrossRef Google Scholar
[3]	邓起东.中国活动构造研究的进展与展望[J].地质评论, 2002, 48(2):168~177. Google Scholar DENG Qi-dong. Advances and overview on researches of active tectonics in China[J]. Geological Review, 2002, 48(2):168~177. Google Scholar
[4]	王秋良, 王恒希, 陈园园, 等.土氡测量在城市断层探测中的应用[J].大地测量与地球动力学, 2010, 30(1):38~42. Google Scholar WANG Qiu-liang, WANG Heng-xi, CHEN Yuan-yuan, et al. Application of soil radon measurement in urban fault surveying[J]. Journal of Geodesy and Geodynamics, 2010, 30(1):38~42. Google Scholar
[5]	程邈, 傅焰林, 李振宇.高密度电法在查明潜伏断裂中的应用[J].工程地球物理学报, 2011, 8(4):417~420. Google Scholar CHENG Miao, FU Yan-lin, LI Zhen-yu. Application of high density resistivity method to hidden fault investigation[J]. Chinese Journal of Engineering Geophysics, 2011, 8(4):417~420. Google Scholar