东昆仑茫崖河东地区地球化学钴异常与含矿地质体的响应

doi:10.11720/wtyht.2024.0031

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摘要

近年来,在东昆仑地区以地质找矿为目的开展的大比例尺1:2.5万地球化学测量工作,具有快速、准确定位异常源的特征,在找矿勘查中被广泛应用,并取得了良好的找矿成果。通过开展1:2.5万水系沉积物测量工作,在东昆仑茫崖河东地区圈出了以Cu、Co、Ni等元素组合为主的综合异常12处,其中以Co为主的综合异常有1处,各元素异常套合较好,相对规模大,异常强度高,具有明显的浓度分带。Co异常与奥陶系祁漫塔格群地层关系密切,区位一致性好。经异常查证,在GA16、GA26、GA11、GA39等异常内发现4条钴矿化带,带内圈定出了3条钴矿体及多条矿化体。综合分析认为该区具有优越的成矿地质条件、良好的地球化学特征,取得了较好的找矿效果,具备大中型钴矿的找矿潜力。

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	马文君
	谢海林
	郭伟
	李斐斐
	滕晓燕
	陈苏龙
	李少南
	刘秀峰
	马忠英
	马海云

关键词 ：钴异常, 祁漫塔格群, 找矿前景, 茫崖河东, 东昆仑

Abstract：

Over recent years, large-scale geochemical surveys on a scale of 1:25,000 have been conducted in the eastern Kunlun region for geological prospecting. These surveys, characterized by the rapid and accurate location of anomaly sources, have been widely applied in mineral explorations, yielding encouraging mineral prospecting results. Using 1:25,000-scale stream sediment surveys, this study delineated 12 geochemical integrated anomalies of the element associations of Cu, Co, and Ni in the Hedong area, Mangya City, eastern Kunlun. These anomalies include one integrated anomaly dominated by Co, where various element anomalies exhibit high-degree overlap, relatively large scales, high intensity, and distinct concentration zoning. The Co anomaly is closely associated with the Ordovician Qimantag Group, demonstrating a high degree of spatial consistency. The subsequent anomaly verification reveals four cobalt mineralized zones within anomalies GA16, GA26, GA11, and GA39, with three ore bodies and multiple mineralized bodies of cobalt being identified within the mineralized zones. The comprehensive analysis indicates that the eastern Kunlun region enjoys excellent metallogenic geological conditions and favorable geochemical characteristics, with promising prospecting results having been achieved. Therefore, this region has the prospecting potential of medium to large-scale cobalt deposits.

Key words： cobalt anomaly Qimantag Group prospecting prospects Hedong area of Mangya City eastern Kunlun

收稿日期: 2024-01-22 修回日期: 2024-03-29 出版日期: 2024-10-20

ZTFLH:

P632

基金资助:青海省地矿局项目“青海省格尔木市长山—红卫山地区1:2.5万地球化学测量”(青地矿科[2022]32号);青海省地矿局项目“青海省格尔木市长山—红卫山地区1:2.5万地球化学测量”(青地矿科[2022]6号);“东昆仑奥陶纪钴矿成矿环境及找矿潜力”(青地矿科[2023]50号)

通讯作者: 谢海林(1968-),男,正高级工程师,长期从事地质矿产勘查及管理工作。Email:327383903@qq.com

作者简介: 马文君(1987-),男,高级工程师,从事地质矿产勘查工作。Email:mawenjun926600@163.com

引用本文:

马文君, 谢海林, 郭伟, 李斐斐, 滕晓燕, 陈苏龙, 李少南, 刘秀峰, 马忠英, 马海云. 东昆仑茫崖河东地区地球化学钴异常与含矿地质体的响应[J]. 物探与化探, 2024, 48(5): 1232-1246.
MA Wen-Jun, XIE Hai-Lin, GUO Wei, LI Fei-Fei, TENG Xiao-Yan, CHEN Su-Liong, LI Shao-Nan, LIU Xiu-Feng, MA Zhong-Ying, MA Hai-Yun. Response of the geochemical anomalies of cobalt to ore-bearing geological bodies in the Mangyahedong area, eastern Kunlun. Geophysical and Geochemical Exploration, 2024, 48(5): 1232-1246.

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https://www.wutanyuhuatan.com/CN/10.11720/wtyht.2024.0031 或 https://www.wutanyuhuatan.com/CN/Y2024/V48/I5/1232

Fig.1 茫崖河东地区大地构造位置^[12](a)及地质简图(b)

Fig.2 茫崖河东地区1:20万化探异常分布

Fig.3 茫崖河东地区1:5万水系沉积物化探异常分布

Fig.4 茫崖河东地区1:5万矿产地球化学调查化探异常分布

Table 1 AS^28-3 CuCoNi(AgZnPbSnAu)异常特征统计

Fig.5 AS^28-3CuCoNi(AgZnPbSnAu)综合异常剖析

Table 2 Cu、Co、Cr、Ni元素地球化学变量统计

Fig.6 水系沉积物元素R型聚类分析图谱

Table 3 主要因子特征根及结构式

Fig.7 Cu、Co、Cr、Ni元素因子计量

Fig.8 Cu、Co、Cr、Ni在不同地质体中的含量变化

Table 4 茫崖河东地区Co、Cr、Cu、Ni在不同地质体中的分布特征

Fig.9 Co异常分布

异常编号	异常点数	异常下限	异常面积	排序	平均值	排序	极大值	排序	衬度	排序	AD	排序	AP	排序	NAD	排序	NAP	排序	分带区
Co-1	61	40.00	2.59	6	49.00	12	61.00	10	1.23	12	507.41	7	93.20	5	12.69	7	2.33	5	1
Co-2	24	40.00	0.78	12	50.15	10	58.30	13	1.25	10	157.36	12	31.86	9	3.93	12	0.80	9	1
Co-3	7	40.00	0.24	17	45.10	30	53.30	20	1.13	30	43.76	19	4.95	22	1.09	19	0.12	22	1
Co-4	3	40.00	0.10	24	45.73	27	49.00	28	1.14	27	19.07	24	2.39	28	0.48	24	0.06	28	1
Co-5	3	40.00	0.19	20	61.07	4	81.90	6	1.53	4	46.17	17	15.93	15	1.15	17	0.40	15	2
Co-6	58	40.00	3.04	5	47.03	21	55.10	17	1.18	21	571.31	5	85.43	6	14.28	5	2.14	6	1
Co-7	3	40.00	0.104	25	45.40	29	49.80	26	1.14	29	17.49	26	2.08	30	0.44	26	0.05	30	1
Co-8	113	40.00	4.60	2	53.69	7	81.90	5	1.34	7	987.16	2	251.65	2	24.68	2	6.29	2	2
Co-9	3	40.00	0.16	21	46.13	26	48.90	30	1.15	26	29.97	22	3.99	24	0.75	22	0.10	24	1
Co-10	26	40.00	1.11	10	45.71	28	60.20	11	1.14	28	202.60	10	25.30	12	5.07	10	0.63	12	1
Co-11	68	40.00	3.54	3	48.11	16	59.90	12	1.20	16	682.07	3	115.03	4	17.05	3	2.88	4	1
Co-12	2	40.00	0.08	29	44.30	31	45.00	31	1.11	31	13.76	30	1.34	31	0.34	30	0.03	31	1
Co-13	5	40.00	0.20	19	48.76	13	57.20	15	1.22	13	39.25	21	7.05	19	0.98	21	0.18	19	1
Co-14	10	40.00	0.34	15	47.65	18	55.80	16	1.19	18	64.12	15	10.29	18	1.60	15	0.26	18	1
Co-15	6	40.00	0.28	16	46.15	25	50.00	25	1.15	25	51.51	16	6.86	20	1.29	16	0.17	20	1
Co-16	22	40.00	1.20	9	46.35	24	57.80	14	1.16	24	223.43	9	30.61	10	5.59	9	0.77	10	1
Co-17	11	40.00	0.83	11	48.69	14	54.10	18	1.22	14	160.96	11	28.73	11	4.02	11	0.72	11	1
Co-18	42	40.00	2.12	7	61.20	3	527.00	1	1.53	3	519.93	6	180.11	3	13.00	6	4.50	3	3
Co-19	26	40.00	1.29	8	49.55	11	89.30	3	1.24	11	254.84	8	49.12	8	6.37	8	1.23	8	2
Co-20	3	40.00	0.12	22	47.10	20	49.00	29	1.18	20	21.90	23	3.30	26	0.55	23	0.08	26	1
Co-21	13	40.00	0.63	13	47.67	17	53.10	21	1.19	17	120.90	13	19.45	14	3.02	13	0.49	14	1
Co-22	2	40.00	0.08	27	46.40	23	51.70	23	1.16	23	15.17	29	2.09	29	0.38	29	0.05	29	1
Co-23	65	40.00	3.16	4	46.64	22	53.40	19	1.17	22	588.95	4	83.85	7	14.72	4	2.10	7	1
Co-24	5	40.00	0.20	18	55.92	6	78.10	8	1.40	6	45.42	18	12.93	17	1.14	18	0.32	17	1
Co-25	2	40.00	0.08	28	48.15	15	49.10	27	1.20	15	15.69	27	2.66	27	0.39	27	0.07	27	1
Co-26	2	40.00	0.06	30	60.60	5	72.20	9	1.52	5	15.21	28	5.17	21	0.38	28	0.13	21	1
Co-27	2	40.00	0.11	23	94.35	1	107.00	2	2.36	1	42.94	20	24.73	13	1.07	20	0.62	13	2
Co-28	1	40.00	0.02	31	88.90	2	88.90	4	2.22	2	8.33	31	4.58	23	0.21	31	0.11	23	2
Co-29	2	40.00	0.09	26	50.55	9	53.00	22	1.26	9	18.14	25	3.79	25	0.45	25	0.09	25	1
Co-30	120	40.00	6.08	1	53.54	8	81.40	7	1.34	8	1301.69	1	329.25	1	32.54	1	8.23	1	2
Co-31	6	40.00	0.50	14	47.15	19	50.70	24	1.18	19	93.57	14	14.19	16	2.34	14	0.35	16	1

Table 5 茫崖河东地区Co异常特征

Fig.10 $GA 甲 2 26$ Co综合异常剖析

Table 6 Comprehensive abnormal eigenvalue statistics of G

GA 甲 2 26

Fig.11 $GA 甲 2 16$ Cu综合异常剖析

Table 7 Comprehensive abnormal eigenvalue statistics of

GA 甲 2 16

Fig.12 Ⅰ号钴铜矿化带野外特征

Fig.13 Ⅶ号钴镍矿化带野外特征

Fig.14 Ⅶ号钴镍矿化带采样平面

Fig.15 扫描电镜下钴矿石特征

[1]	李平, 何蕾, 梁婷, 等. 钴的地球化学行为、矿床成因类型、资源分布及研究展望[J]. 新疆地质, 2023, 41(2): 210-217.
[1]	Li P, He L, Liang T, et al. Geochemical behavior,genetic type,resource distribution,and research prospect of the cobalt deposits[J]. Xinjiang Geology, 2023, 41(2): 210-217.
[2]	于晓飞, 公凡影, 李永胜, 等. 中国典型钴矿床地质特征及重点地区矿产资源预测[J]. 吉林大学学报:地球科学版, 2022, 52(5): 1377-1418.
[2]	Yu X F, Gong F Y, Li Y S, et al. Geological characteristics of typical cobalt deposits in China and predictionof mineral resources in the key areas[J]. Journal of Jilin University:Earth Science Edition, 2022, 52(5): 1377-1418.
[3]	王焰, 钟宏, 曹勇华, 等. 我国铂族元素、钴和铬主要矿床类型的分布特征及成矿机制[J]. 科学通报, 2020,65: 3825-3838.
[3]	Wang Y, Zhong H, Cao Y H, et al. Genetic classification,distribution and ore genesis of major PGE,Co and Cr deposits in China: A critical review[J]. Chin.Sci.Bull., 2020,65: 3825-3838.
[4]	刘东盛, 王学求, 聂兰仕, 等. 中国钴地球化学异常特征、成因及找矿远景区预测[J]. 地球科学, 2022, 47(8):2781-2794.
[4]	Liu D S, Wang X Q, Nie L S, et al. Cobalt geochemical anomalies characteristics and genesis in China and metallogenic prospecting areas prediction[J]. Earth Science, 2022, 47(8):2781-2794.
[5]	张照伟, 李文渊, 丰成友, 等. 中国钴镍成矿规律与高效勘查技术[J]. 西北地质, 2022, 55(2):14-34.
[5]	Zhang Z W, Li W Y, Feng C Y, et al. Study on metallogenic regularity of Co-Ni deposits in China and its efficient exploration techniques[J]. Northwestern Geology, 2022, 55(2):14-34.
[6]	王京, 石香江, 王寿成, 等. 未来中国钴资源需求预测[J]. 中国国土资源经济, 2019,10:28-33.
[6]	Wang J, Shi X J, Wang S C, et al. Demand forecast of China's cobalt resource in the future[J]. Natural Resource Economics of China, 2019,10:28-33.
[7]	张连昌, 张爱奎, 李永乐, 等. 沉积岩—变沉积岩型钴矿研究进展与问题[J]. 岩石学报, 2023, 39 (4): 981-997.
[7]	Zhang L C, Zhang A K, Liu Y L, et al. Research progresses and problems of sedimentary-metasedimentary rock-hosted cobalt deposits[J]. Acta Petrologica Sinica, 2023, 39 (4):981-997.
[8]	马忠英, 马文君, 王斌, 等. 青海省格尔木市长山—红卫山地区1:2.5万地球化学测量报告[R]. 青海省第一地质勘查院, 2023.
[8]	Ma Z Y, Ma W J, Wang B, et al. Geochemical measurement report of 1:25,000 in Changshan-Hongweishan region,Golmud City,Qinghai Province[R]. The First Geological Exploration Institute of Qinghai Province, 2023.
[9]	何书跃, 林贵, 钟世华, 等. 造山作用孕育“青海金腰带”[J]. 西北地质, 2023, 56(5):1-16.
[9]	He S Y, Lin G, Zhong S H, et al. Geological characteristics and related mineralization of“Qinghai Gold Belt” formed by orogeny[J] .Northwestern Geology, 2023, 56(5):1-16.
[10]	李凤廷, 苗虎林, 付佳, 等. 那陵郭勒河下游重磁异常与铁多金属矿找矿预测[J]. 西北地质, 2023, 56(6):155-165.
[10]	Li F T, Miao H L, Fu J, et al. Gravity and magnetic anomalies and prospecting prediction of iron polymetallic deposits in the downstream of Nalingguole river[J]. Northwestern Geology, 2023, 56(6):155-165.
[11]	李少南, 马海云, 王斌, 等. 青海省格尔木市茫崖河东地区铜多金属矿普查报告(2019-2021)[R]. 青海省第一地质勘查院, 2022.
[11]	Li S N, Ma H Y, Wang B, et al. Census report of copper polymetallic mines in Mangyahedong District,Golmud City,Qinghai Province[R]. The First Geological Exploration Institute of Qinghai Province, 2022.
[12]	青海省地质调查院, 青海省地质调查局. 青海省矿产志报造[R]. 2018.
[12]	Qinghai Geological Survey Institute, Qinghai Geological Survey Bureau. The chronicle of mineral resources report of Qinghai Province[R]. 2018.
[13]	张爱奎, 刘永乐, 刘光莲, 等. 青海祁漫塔格成矿带冰沟南地区成矿类型及找矿前景[J]. 西北地质, 2015, 48(4): 125-140.
[13]	Zhang A K, Liu Y L, Liu G L, et al. Mineralization types and prospecting potential of binggounan area in Qimantage metallogenic belt,Qinghai Procince[J]. Northwestern Geology, 2015, 48(4): 125-140.
[14]	安勇胜, 李建放, 逯积明, 等. 青海省格尔木市那陵郭勒河中游J46E019008、J46E019009、J46E019010、J46E020010、J46E020011、J46E020012六幅1:5万区域矿产调查报告[R]. 青海省地质调查院, 2008.
[14]	An Y S, Li J F, Lu J M, et al. Regional mineral survey reports of J46E019008,J46E019009,J46E019010,J46E02010,J46E020011,J46E020012 for 1:50,000 in the middle reach of the Nalinggele River,Golmud City,Qinghai Province[R]. Qinghai Institute of Geological Survey, 2008.
[15]	张伟, 安茂国, 王志鹏, 等. 青海省那陵格勒河中游地区水系沉积物地球化学特征及找矿远景[J]. 现代地质, 2023, 37(3):690-707.
[15]	Zhang W, An M G, Wang Z P, et al. Geochemical characteristics of stream sedimentsand prospecting in the middle reach of the Nalinggele River,Qinghai Province[J]. Geoscience, 2023, 37(3):690-707.
[16]	田三春, 何书跃, 东国兴, 等. 青海东昆仑西段祁漫塔格地区黑柱山—尕怒大门1:50 000矿产地球化学调查报告[R]. 青海省第三地质矿产勘查院, 2009.
[16]	Tian S C, He S Y, Dong G X, et al. Mineral geochemical survey report for 1:50,000 in Heizhushan-Ganudamen,Qimantag area,Western Kunlun,Qinghai[R].The Third Geological Exploration Institute of Qinghai Province, 2009.
[17]	苏旭亮, 赵永亮, 赵寿, 等. 青海省格尔木市克停哈尔地区铁多金属矿调查评价报告[R]. 青海省第三地质矿产勘查院, 2015.
[17]	Su X L, Zhao Y L, Zhao S, et al. Survey and evaluation report on iron polymetallic ore in Ketinghar area,Golmud City,Qinghai Province[R]. The Third Geological Exploration Institute of Qinghai Province, 2015.
[18]	梁东, 华北, 赵德怀, 等. 喀喇昆仑麦拉山地区水系沉积物地球化学特征与找矿预测[J]. 现代地质, 2023, 37(3):708-721.
[18]	Liang D, Hua B, Zhao D H, et al. Geochemical characteristics of stream sediment and ore prediction in the Malashan area of the Karakoram region[J]. Geoscience, 2023, 37(3):708-721.
[19]	胡兆国, 张少鹏, 连国建, 等. 青海省纳日宗地区水系沉积物地球化学特征及找矿远景[J]. 现代地质, 2018, 32(3):482-492.
[19]	Hu Z G, Zhang S P, Lian G J, et al. Geochemical characteristics of stream sediments and prospecting in the Narizong area,Qinghai Province[J]. Geoscience, 2018, 32(3):482-492.
[20]	徐云峰, 郝雪峰, 秦宇龙, 等. 四川岔河地区水系沉积物地球化学特征及找矿方向[J]. 物探与化探, 2021, 45(3): 624-638.
[20]	Xu Y F, Hao X F, Qin Y L, et al. Geochemical characteristics of stream sediments and prospecting direction in Chahe area of Sichuan Province[J]. Geophysical and Geochemical Exploration, 2021, 45(3): 624-638.
[21]	张嘉升, 周伟, 李伟良, 等. 陕西简池镇地区1:2.5万水系沉积物测量地球化学特征及找矿潜力[J]. 物探与化探, 2023, 47(3): 659-669.
[21]	Zhang J S, Zhou W, Li W L, et al. Geochemical characteristics and prospecting potential of Jianchi Town,Shaanxi Province,China based on 1:25,000 stream sediment survey[J]. Geophysical and Geochemical Exploration, 2023, 47(3): 659-669.
[22]	安朝, 杨敏, 陈熙, 等. 东昆仑东段都兰地区地球化学特征及其成矿意义——基于大比例尺微沟系(土壤)测量工作[J]. 地质与勘探, 2020, 56(6): 1158-1169.
[22]	An C, Yang M, Chen X, et al. Geochemical characteristics and metallogenic significance of the Dulan area in the eastern section of the East Kunlun Mountains derived from large-scale micro channel system (soil) measurement[J]. Geology and Exploration, 2020, 56(6): 1158-1169.
[23]	于俊博, 宋云涛, 郭志娟, 等. R 型聚类分析在区域化探元素分组中的作用探讨[J]. 物探化探计算技术, 2014, 36(6): 771-776.
[23]	Yu J B, Song Y T, Guo Z J, et al. Discussion on the affection of the R- cluster analysis applied in grouping elements in regional geochemical exploration[J]. Computing Techniques for Geophysical and Geochemical Exploration, 2014, 36(6): 771-776.
[24]	邱炜, 何皎, 熊寿加. 青海北祁连区域化探数据处理中异常衬值法的应用及成效[J]. 黄金科学技术, 2015, 23(1): 34-39.
[24]	Qiu W, He J, Xiong S J. The application and effect of abnormal contrast method during regionalgeochemical exploration data processing in northern Qilian,Qinghai Province[J]. Gold Science and Technology, 2015, 23(1): 34-39.
[25]	潘彤, 孙丰月. 青海东昆仑肯德可克钴铋金矿床成矿特征及找矿方向[J]. 地质与勘探, 2003, 39(1): 18-22.
[25]	Pan T, Sun F Y. The mineralization characteristic and prospecting of kendekeke co-bi-au deposit in Dunkunlun,Qinhai Provice[J]. Geology and Exploration, 2003, 39(1): 18-22.
[26]	李小亮, 杨乐, 张松涛, 等. 青海东昆仑驼路沟钴矿的成矿时代与成因[J]. 世界地质, 2022, 41(3): 483-497.
[26]	Li X L, Yang L, Zhang S T, et al. Metallogenic timing and genesis of Tuolugou cobalt deposit in eastern Kunlun,Qinghai[J]. Global Geology, 2022, 41(3): 483-497.
[27]	潘彤. 东昆仑成矿带钴矿成矿系列研究[D]. 长春: 吉林大学, 2005.
[27]	Pan T. Study on metallogenic series of cobalt deposits in EastKunlunmetallogenic belt[D]. Changchun: Jilin University, 2005.
[28]	赵财胜, 杨富全, 代军治. 青海东昆仑肯德可克钴铋金矿床成矿年龄及意义[J]. 矿床地质, 2006, 25(S1): 427-430.
[28]	Zhao C S, Yang F Q, Dai J Z. Metallogenic age of the Kendekeke Co,Bi,Au deposit in East Kunlun Mountains,Qinghai Province,and its significance[J]. Mineral Deposits, 2006, 25(S1): 427-430.
[29]	吴东倩. 青海东昆仑造山带钴矿成矿作用研究[D]. 长春: 吉林大学, 2023.
[29]	Wu D Q. Studyon cobalt mineralization in East Kunlun orogenic belt,Qinghai Province[D]. Changchun: Jilin University, 2023.

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