The application of geophysical methods to the X ore district in southern first region of Chile
WANG Ying-Chao1, 2, WANG Xiao-Hui1, 2, WANG Ming-Ming1, 2, MA Peng-Yuan1, 2
1. Henan Nonferrous Metal Geological Exploration Institute, Zhengzhou 450052, China;
2. Nonferrous Metal Research Key Laboratory for Deep Prospecting Techniques, Zhengzhou 450052, China
The regional geological and geophysical exploration work in Chile remains at relatively low level, the interpretation of mining area geophysical data is insufficient, and the distribution characteristics of ore deposits are not clearly known. The authors made a comprehensive analysis of the geological and geophysical characteristics, and employed the geophysical ground magnetic and electromagnetic measuring method in the X ore district of the first region of Chile. It is held that the relatively high magnetic or weak magnetic low resistivity anomaly zone and its depth and surrounding areas are geophysical anomaly indicators for ore prospecting, and that the structure (shatter zone) should be the focus in further study of the metallogenic regularity. Geophysical exploration methods are of guiding significance in the practical exploration work.
王英超, 王晓辉, 王明明, 马鹏远. 地球物理方法在智利第一大区南部X矿区的应用[J]. 物探与化探, 10.11720/wtyht.2014.5.07.
WANG Ying-Chao, WANG Xiao-Hui, WANG Ming-Ming, MA Peng-Yuan. The application of geophysical methods to the X ore district in southern first region of Chile. Geophysical and Geochemical Exploration, 2014, 38(5): 901-909.
[1] Chouinard A., Williams-Jones A E, Leonardson, et al. Geology and genesis of the multistage high-sulfidation epithermal Pascua Au-Ag-Cu deposit, Chile and Argentina[J].Economic Geology, 2005,100(1):463-490.[2] Ott, Kollersberger, Tassara. GIS analyses and favorability mapping of optimized satellite data in northern Chile to improve exploration for copper mineral deposits[J].Geosphere, 2006(2):236-252.[3] Sillitoe R. A geological appraisal of the Mantovrde copper deposit,Chile[R]. Minera Anglo American Chile Ltda, unpub rep,1989:15.[4] Sillitoe R H. Porphyry Copper Systems[J].Economic Geology, 2010,105(1):3-41.[5] Sillitoe R.H. Iron oxide-copper gold deposits: an Andean view[J].Mineralium Deposita, 2003,30(1):787-812.[6] 王明明,袁稳,王晓辉,等.智利共和国第一大区河南7-8矿区物探工作报告[R].河南省有色金属地质勘查总院.2013.[7] 方维萱,柳玉龙,张守林,等.全球铁氧化物铜金型(IOCG)矿床的3类大陆动力学背景与成矿模式[J].西北大学学报,2009,39(3):404-413.[8] 高乾兰.智利低温热液金矿床的成矿特征及类型[J].黄金科技动态,1991,36(7):20-21.[9] 胡桂明,李兆龙,沈承珩.智利斑岩铜矿产出的地质背景[J].冶金地质动态,1991(9):1-3.[10] 李建旭,方维萱,刘家军.智利阿塔卡玛断裂(AFZ)走滑扩张构造与控矿作用[J].矿物学报,2009(S1):108-181.[11] 李建旭,方维萱,刘家军.智利铁氧化物—铜—金矿床区域定位构造—矿田构造类型与特征[J].地质与勘探,2011,47(3):323-332.[12] 毛景文,余金杰,袁顺达,等.铁氧化物—铜—金(IOCG)型矿床:基本特征、研究现状与找矿勘查[J].矿床地质,2008.27(3):267-278.[13] 吴伟成.智利热液型金矿床地质特征[J].黄金科技动态,1992(4):21-28.[14] 周家云,毛景文,朱志敏.拉拉铁氧化物—铜—金矿床(IOCG)的流体过程[J].矿物学报,2009(S1):272-274.[15] 张杨,高光明,席振,等.秘鲁南部深大断裂与古新世斑岩铜矿带地质特征[J].南方金属,2011,2(179):19-22.[16] 翟裕生,彭润民,向运川,等.区域成矿研究法[M].北京:中国大地出版社,2004.[17] 夏斌,陈根文,王核.全球超大型斑岩铜矿床形成的构造背景分析[J].中国科学 :D辑,2002,32(S1):87-95.[18] 徐巧,杨新雨,付水兴,等.智利科皮亚波月亮山铁铜矿床的地质特征及找矿标志[J].矿产勘查,2011,2(6):618-620.[19] 李忠烈.智利MARCIA铜矿地质特征及成矿机理[J].矿产与地质,2012,26(3):228-230.[20] 李仕明.智利北部斑岩铜矿系统的航磁特征及其地质意义[J].国土资源报,2001,96(8),42-48.[21] 王明国,张晓永,白凤军,等.土壤地球化学测量在智利塔拉帕卡大区地质勘查中的应用[J]. 物探与化探,2013,37(3):394-399.[22] 左仁广.基于多层次模糊综合优选找矿远景区[J].地质与勘探,2009,45(2):85-89.[23] 赵鹏大.矿产勘查理论与方法[M].北京:中国地质大学出版社,2001.[24] 张云, 朱自强, 严文婕.航磁在秘鲁12区找矿靶区中的作用[J]. 物探与化探,2010,34(3):367-371.[25] 李建华, 何继善.秘鲁航磁特征及铁矿类型[J]. 物探与化探,2011,35(5):604-609.