Gold Science and Technology
img

Wechat

Adv. Search
Online Submission Peer Review Office Work

Gold Science and Technology ›› 2014, Vol. 22 ›› Issue (2): 24-30.doi: 10.3969/j.issn.1005-2518.2014.02.024

Previous Articles     Next Articles

Using the Method of Mixing Diluents to Identify the Sr-Nd Isotopic Composition in Rock Samples:Taking Ore-bearing Granite Porphyry in the Songkaersu Copper-Gold Mining Area in Eastern Junggar of Xinjiang as an Example

WANG Bin, ZHANG Dong, FAN Junjie, ZHANG Feng, PAN Aijun,ZHU Peng   

  1. Gold Geological Institute of CAPF,Langfang   065000,Hebei,China
  • Received:2013-12-01 Revised:2014-01-18 Online:2014-04-28 Published:2014-08-26

PDF (PC)

494

Abstract:

Mixing diluents method was an extremely important way in identifying the composition of radioactive isotopes in rock samples,and it had the advantage of less samples,higher test precision and sensitivity.Therefore, mixing diluents method was applied to obtain date about the Sr-Nd isotopic composition of ore-bearing porphyry in the Songkaersu copper(gold) deposit mining area in eastern Junggar.The 87Sr/86Sr(ISr) initial value was relatively low and decentralized with the range of 0.70268 to 0.71004,which was lower than the average ISr value (0.719) in crust.Additionally,the εNd value was high and positive with the range of +3.8~+8.3 as well very young two-stage Nd model ages,and the t2DM value was between 0.4~0.8 Ga.Sr-Nd isotopic composition was similar to the alkali rich intrusive rock in northern Xinjiang.Its source area was likely to be due to the effect of bottom of invasion of the mantle-derived magma adding to the lower crust,and the newborn and young crust with shorter crustal residence time mixed with mantle-derived magma.The delamination of upset the late carboniferous to the lithosphere in east Carboniferous resulted in large bottom of invasion mantle-derived magma.The stretching environment after collision provided the ore-forming materials of upward migration channel,and formed metallogenic belt which was mainly with polymetallic ore.

Key words: copper -gold deposit, mixing diluent method, granite porphyry, Sr-Nd isotopic, Kalamaili , belt

CLC Number: 

  • P618.51

[1] 毛光周,华仁民,高剑峰,等.江西金山金矿含金黄铁矿的Rb-Sr年龄[J].地球学报,2008,29(5):599-606.
[2] 杨进辉,周新华.胶东地区玲珑金矿矿石和载金矿物Rb-Sr等时线年龄与成矿时代[J]. 科学通报,2000,45(14):1547-1553.
[3] 韩以贵,李向辉,张世红,等.豫西祁雨沟金矿单颗粒和碎裂状黄铁矿Rb-Sr等时线定年[J].科学通报,2007,52(11):1307-1311.
[4] 刘远华,杨贵才,张轮,等.西秦岭阳山超大型金矿床花岗岩岩石地球化学特征[J].黄金科学技术,2010,18(6):1-7.
[5] 胡西顺,原莲肖,朱红周,等.陕西龙头沟金矿床的地质地球化学特征及成因探讨[J].黄金科学技术,2010,18(2):1-5.
[6] 应汉龙.云南大坪金矿床围岩蚀变和同位素地球化学特征[J].黄金科学技术,1998,6(4):14-23.
[7] 黄雪飞,张宝林,李晓利,等.电气石研究进展及其找矿意义[J].黄金科学技术,2012,20(3):56-65.
[8] 祁进平,宋要斌,李双庆,等.河南省栾川县西沟铅锌银矿物铷—锶同位素组成特征[J].岩石学报,2009,25(11):2843-2854.
[9] 李科.山东沂南金铜铁矿床同位素地球化学研究[D].北京:中国地质大学,2009.
[10] 王银喜,顾连兴,张遵忠,等.东天山晚石炭世大石头群流纹岩Sr-Nd-Pb同位素地球化学研究[J].岩石学报,2007,23(7):1749-1755.
[11] 李秋立,陈福坤,王秀丽,等.超低本底化学流程和单颗粒云母Rb-Sr等时线定年[J].科学通报,2006,51(3):321-325.
[12] 濮巍,赵葵东,凌洪飞,等.新一代高精度高灵敏度的表面热电离质谱仪( Triton TI) 的Nd 同位素测定[J].地球学报,2004,25(2):271-274.
[13] 应汉龙,刘秉光.云南老王寨金矿床微量元素和同位素组成及对成矿物质来源的限定[J].黄金科学技术,2000,8(2):15-20.
[14] 何国琦,成守德,徐新,等.中国新疆及邻区大地构造图(1∶250万)[M].北京:地质出版社,2004.
[15] 胡霭琴,王中刚,涂光炽.新疆北部地壳演化及成岩成矿规律[M].北京:科学出版社,1997.
[16] 赵振华,沈远超,涂光炽.新疆金属矿产资源的基础研究[M].北京:科学出版社, 2001:75-105.
[17] 赵霞,贾承造,张光亚,等.准噶尔盆地陆东—五彩湾地区石炭系中、基性火山岩地球化学及其形成环境[J].地学前缘,2008,15(2):272-279.
[18] 吴小奇,刘德良,李振生.卡拉麦里缝合带后碰撞期火山活动[J].地学前缘,2009,16(3):220-230.
[19] Liew T C,Hofmann A W.Precambrian crustal components,plutonic associations, plate environment of the Hercynian Fold Belt of central Europe:Indications from a Nd and Sr isotopic study[J].Contributions to Mineralogy and Petrology,1988,98(2):129-138.
[20] 李献华,赵振华,桂训唐.华南前寒武纪地壳形成时代的Sm-Nd和锆石U-Pb同位素制约[J].地球化学,1991,20(3):255-264.
[21] 周新华,蒋荣华,陈焕疆,等.上海金山群斜长角闪岩Sm-Nd和Ar-Ar同位素年龄测定[J].岩石学报,1993,9(4):418-421.
[22] Faure G.Principles of Isotope Geology(2nd Edition) [M].New York:John Wiley and Sons,1986:567.
[23] 廖启林,戴塔根.新疆北部浅成低温热液型金矿床成矿地球化学特征初探[J].地质地球化学,2000,28(2):19-25.
[24] 沈渭洲,凌洪飞,李武显,等.中国东南部花岗岩类的Nd模式年龄与地壳演化[J].中国科学(D辑),2000,30(5):471-478.
[25] 沈渭洲,凌洪飞,孙涛.华南晚中生代花岗岩—火成岩Sr、Nd同位素地球化学[M]//周新民.南岭地区晚中生代花岗岩成因与岩石圈动力学演化.北京:科学出版社,2007:123-160.
[26] 王德滋,沈渭洲.中国东南部花岗岩成因与地壳演化[J].地学前缘,2003,10(3):209-220.
[27] Chen J F,Jahn B M.Crustal evolution of southeastern China:Nd and Sr isotopic evidence[J].Tectonophysics,1998,284(1/2):101-133.
[28] 郭新生,陈江峰,张巽,等.桂东南富钾岩浆杂岩的Nd同位素组成:华南中生代地幔物质上涌事件[J].岩石学报,2001,17(1):19-27.
[29] 李献华,周汉文,刘颖,等.粤西阳春中生代钾玄质侵入岩及其构造意义:Ⅱ.微量元素和Sr-Nd同位素地球化学[J].地球化学,2001,30(1):57-65.
[30] 邱检生,胡建,McInnes B I A,等.广东龙窝花岗闪长质岩体的年代学、地球化学及岩石成因[J].岩石学报,2004,20(6):1363-1374.
[31] 王中刚,赵振华,于学元.新疆北部富碱侵入岩带地质地球化学特征及其成因[G]//涂光炽.新疆北部固体地球科学新进展.北京:科学出版社,1993:169-172.
[32] 赵振华,王中刚,邹天人,等.新疆乌伦古富碱侵入岩成因探讨[J].地球化学,1996,25(3):205-220.
[33] Chen Y,Hu A,Zhang G,et al.Zircon U-Pb age of gramnitic gneiss on Duku highway in westem Tianshan of China and its geological implications[J].Chinese Science Bulletin,2000,45(7):649-653
[34] 谭佳奕,吴润江,张元元,等.东准噶尔卡拉麦里地区巴塔玛依内山组火山岩特征和年代确定[J].岩石学报,2009,25(3):539-546.
[35] Xiao Y,Zhang H F,Shi J A,et al.Late Paleozoic magmatic record of East Junggar,NW China and its significance:Implication from zircon U-Pb dating and Hf istope[J].Gondwana Research,2011,20(2/3):532-542.
[36] Su Y P,Zheng J P,Griffin W L.Geochemistry and geochronology of Carboniferous volcanic rocks in the eastern Junggar terrane, NW China:Implicaiton for a tectonic transition[J].Gondwana Research,2012,22(3/4):1009-1029.
[37] Han B F,Wang S G,Jahn B M,et al. Depleted-mantle source for the Ulungur River A-type granites from North Xinjiang,China:Geochemistry and Nd-Sr isotopic evidence,and implications for Phanerozoic crustal growth[J].Chemical Geology,1997,138(3/4):135-159.
[38] 伍建机,陈斌.西准噶尔庙尔沟后碰撞花岗岩微量元素和Nd-Sr同位素特征及成因[J].新疆地质,2004,22(1):29-36.
[39] 苏玉平,唐红峰,刘丛强,等.新疆东准噶尔苏吉泉铝质A型花岗岩的确立及其初步研究[J].岩石矿物学杂志,2006,25(3):175-184.
[40] Chen B,Jahn B M.Genesis of post-collisional granitoids and basement nature of Junggar Terrane,NW China:Nd-Sr isotope and trace element evidence[J].Journal of Asian EarthSciences,2004,23(5):691-703.
[41] 侯增谦,潘小菲,杨志明,等.初论大陆环境斑岩铜矿[J].现代地质,2007,21(2):332-351.
[1] CHEN Maohong, XIE Xianyang, MA Kezhong. Research on Lithology and Stratigraphy Conditions of Fault-controlled Ore-body in Nibao Carlin-type Gold Deposit,Guizhou Province [J]. Gold Science and Technology, 2018, 26(2): 131-142.
[2] QU Hui, WANG Baiyi, WANG Jianmin, LI Chenglu, XU Guozhan, WANG Zhuo. Application of Soil Geochemical Survey in the Exploration of Yongxin Gold Deposit and Its Prospecting Effect [J]. Gold Science and Technology, 2018, 26(2): 143-152.
[3] ZHANG Jian,YANG Xingke,CHAO Huixia,HE Hujun,HAN Ke,YANG Longwei,LI Bin. Mineralization and Alteration Characteristics of Northern Shiquan-Hanyin Gold Belt in South Qinling [J]. Gold Science and Technology, 2017, 25(6): 21-30.
[4] ZHENG Muting,ZHANG Shugen,HE Zhongchun. Occurrence of Gold and Silver and Their Relation to Metallogenic Evolution in Kangjiawan Au-Ag Polymetallic Deposit,Hunan Province [J]. Gold Science and Technology, 2017, 25(6): 31-42.
[5] LIANG Yongke,WANG Degong,ZHAO Jie. Geological Characteristics and Prospecting Potential of Yuhengtang Gold Deposit in Hunan Province [J]. Gold Science and Technology, 2017, 25(6): 43-51.
[6] GAO Shuai1,2,ZENG Qingdong1,YU Changming,XING Baoshan,JING Linhai,YE Jie,FAN Hongrui,YANG Kuifeng. Application of Remote Sensing and Comprehensive Geophysical Methods in Spatial Localization of Hidden Metallogenic Intrusions in South Zhaoyuan,Shandong Province [J]. Gold Science and Technology, 2017, 25(5): 1-10.
[7] HAN Ke,YANG Xingke,ZHANG Jian,HU Guochao. Characteristics of Brittle-ductile Shear Zone and Its Control Effect on Gold Mineralization in the Huanglong Gold Deposit,Hanyin,South Shaanxi Province [J]. Gold Science and Technology, 2017, 25(5): 18-29.
[8] WANG Xiaoqing,YANG Xingke,RUI Huichao. The Crystal Form Typomorphism of Pyrite and Its Variation Regularity and Prospecting Significance in Daiwangshan Gold Deposit, Inner Mongolia [J]. Gold Science and Technology, 2017, 25(5): 39-46.
[9] CHEN Caihua,SUN Bing,CHEN Ji,CHEN Lizi. Prospecting Effect of Stream Sediment Survey in Zhongzhai-Shilipu Area of West Qinling Mountains [J]. Gold Science and Technology, 2017, 25(4): 1-9.
[10] ZHANG Lei,TONG Yu,YANG Zhendong,BAI Yunlong,LIU Xing,ZHAO Yongtao. Metallogenic Mechanism and Prospecting Direction of Gold-Copper Poly-metallic Deposits in Weizigou Area,Liaoning Province [J]. Gold Science and Technology, 2017, 25(4): 10-17.
[11] SONG Yingxin,SONG Mingchun,DING Zhengjiang,WEI Xufeng,XU Shaohui,LI Jie,TAN Xianfeng,LI Shiyong,ZHANG Zhaolu,JIAO Xiumei,HU Hong,CAO Jia. Major Advances on Deep Prospecting in Jiaodong Gold Ore Cluster and Its Metallogenic Characteristics [J]. Gold Science and Technology, 2017, 25(3): 4-18.
[12] SONG Guozheng,YAN Chunming,CAO Jia,GUO Zhifeng,BAO Zhongyi,LIU Guodong,LI Shan,FAN Jiameng,LIU Caijie. Breakthrough and Significance of Exploration at Depth More than 1 000 m in Jiaojia Metallogenic Belt,Jiaodong:A Case of #br# Shaling Mining Area [J]. Gold Science and Technology, 2017, 25(3): 19-27.
[13] XU Zhonghua,WANG Fujiang,ZHOU Mingling,BAI Yina,ZHAO Chengle,HU Bingqian. Study on the Mineralogical Characteristics of Main Metallic Minerals and Ore Genesis of Moshan Gold Deposit in Eastern Shandong [J]. Gold Science and Technology, 2017, 25(3): 28-37.
[14] LIU Guodong,WEN Guijun,LIU Caijie,BAO Zhongyi,SUN Zhongquan,FAN Jiameng,LI Shan,YAN Chunming,GUO Zhifeng. Discovery,Characteristics and Prospecting Direction of Shuiwangzhuang Deep Super-large Gold Deposit in the Northern Section of Zhaoping Fault [J]. Gold Science and Technology, 2017, 25(3): 38-45.
[15] WAN Peng,DING Zhengjiang,HU Hong,WU Fengping,CHENG Rongrong,ZOU Jian. Deep Metallogenic Characteristics of Denggezhuang Gold Deposit in Jiaodong and Its Prospecting Method Combinations [J]. Gold Science and Technology, 2017, 25(3): 46-53.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!

©2018 Gold Science and Technology 

Telephone:0931-8277791 

E-mail: hjkx@lzb.ac.cn Postcode:730000 

Powered by Beijing Magtech Co. Ltd

陇ICP备17001318号-1