1∶50 000 Mineral Geological Map Database of the Panxin Map-sheet of the Songtao Manganese Deposit in Tongren, Guizhou
-
摘要:
贵州铜仁松桃锰矿盘信幅(H49E024005)1∶50 000矿产地质图数据库是以中国地质调查局《矿产地质调查技术要求(1∶50 000)》(DD2019–02)为标准, 开展的新一代1∶50 000矿产地质调查工作系列成果之一。本次工作梳理了盘信幅调查区的岩石地层层序, 厘定了39个填图单元, 划分了8个建造类型, 重点划分了5个成因相互关联的含锰建造填图单元。该数据库为MapGIS格式, 数据内容主要由地理图层、建造构造图层、矿产地图层和整饰图层等组成, 并包含150个岩石化探分析数据、333个一般岩矿分析数据、90个锆石U–Pb年龄数据、6条矿产地信息、2种矿床类型。该数据库以重点突出含矿建造、控矿构造和矿化蚀变信息为特色, 为锰矿资源研究、能源勘探、矿产资源规划等提供基础资料。
Abstract:The 1∶50 000 mineral geological map database of the Panxin Map-sheet (H49E024005) of the Songtao manganese deposit in Tongren, Guizhou represents one of the achievements of the new round of 1∶50 000 mineral geological survey work series in accordance with the Technical Requirements for Mineral Geological Survey (1∶50 000) (DD2019-02) initiated by the China Geological Survey (CGS). The work reviews the lithostratigraphic sequence of the Panxin Map-sheet surveying area, determines 39 mapping units, identified eight formation types, and emphatically divides five genetically interrelated manganese-bearing formation mapping units. The database is built in MapGIS format. It mainly includes geographic layers, formation-structure layers, mineral deposit layers, and finishing layers, covering 150 pieces of rock geochemical analysis data, 333 pieces of general rock and ore analysis data, 90 pieces of zircon U–Pb age data, 6 pieces of mineral deposit information, and two deposit types. The database highlights ore-bearing formation, ore-controlling structure and mineralization alteration information, providing base data for manganese-related resource research, energy exploration, and mineral resource planning.
-
-
图 1 黔东及毗邻区南华纪早期武陵次级裂谷盆地结构与构造古地理图(据周琦等, 2016b修改)
表 1 数据库(集)元数据简表
条目 描述 数据库(集)名称 贵州铜仁松桃锰矿盘信幅1∶50 000矿产地质图数据库 数据库(集)作者 刘 健, 贵州省地质矿产勘查开发局一〇三地质大队
袁良军, 贵州省地质矿产勘查开发局一〇三地质大队
谢小峰, 贵州省地质矿产勘查开发局一〇三地质大队
占朋才, 贵州省地质矿产勘查开发局一〇三地质大队数据时间范围 2016—2018年 地理区域 经纬度: 东经109°00′~109°15′, 北纬28°00′~28°10′ 数据格式 *.wp, *.wl, *.wt 数据量 39.7 MB 数据服务系统网址 http://dcc.cgs.gov.cn 基金项目 中国地质调查局地质调查项目“整装勘查区找矿预测与技术应用示范”子项目(121201004000160901–36)资助 语种 中文 数据库(集)组成 盘信幅1∶50 000矿产地质图数据库包括: 地理图层、建造构造图层、矿产地图层及整饰图层。地理图层包括主要行政境界、主要居民点、主要面状水系、主要线状水系、主要地理标注等。建造构造图层包括: 建造构造(地质面实体)、地质(界)线、褶皱、断裂、同沉积断层、产状要素、同位素年龄等。矿产地图层: 矿产地。整饰图层分为图内部分和图外部分, 图内整饰图层包含地质注记与建造花纹、指引线、断层倾向、倾角及断层性质、产状倾角注记、同位素注记、图切剖面等。图外整饰图层包含接图表、中国地质调查局局徽、图名、比例尺、坐标参数、责任签、图例、沉积岩建造柱状图、图切剖面图、矿种及规模、矿产地名录、所处成矿区带位置图、含矿建造分布图、典型矿床地质图及剖面图、含矿期建造柱状图、含矿建造与古喷溢口群分布图等 
下载: 导出CSV
表 2 建造构造图层数据表
序号 数据项名称 标准编码 数据类型 实例 1 地质体面实体标识号 *Feature_Id Character AH49E024005000000001 2 地质体面实体类型代码(地质代码) *Feature_Type Character O1h 3 地质体面实体名称 Geobody_Name Character 红花园组 4 地质体面实体时代 Geobody_Era Character O1h 5 建造大类 Formation Character 沉积岩建造 6 建造类型 Metallogenic Character 灰岩 7 岩石组合 Combination Character 生物碎屑灰岩、粗晶灰岩 8 大地构造环境 Structural_Env Character 上扬子地块、鄂渝湘黔前陆褶断带
下载: 导出CSV
表 3 地质(界)线图层数据表
序号 数据项名称 标准编码 数据类型 实例 1 要素标识号 *Feature_Id Character AH49E024005000000001 2 地质界线(接触)代码 *Feature_Type Character 01 3 地质界线类型 Boundary_Name Character 整合 4 界线左侧地质体代号 Left_Boundary_Code Character O1h 5 界线右侧地质体代号 Right_Boundary_Code Character O1–2d 6 界面走向/° Strike Integer 197 7 界面倾向/° Dip_Direction Integer 107 8 界面倾角/° Dip_Angle Integer 39
下载: 导出CSV
表 4 断裂图层数据表
序号 数据项名称 标准编码 数据类型 实例 1 要素分类代码 *Feature_Type Character F9 2 断层类型(地质代码) Fault_Type Character F9 3 断层名称 Fault_Name Character 水源头断层 4 断层编号 Fault_Code Character H49E024005F9 5 断层性质 Fault_Character Character 逆断层, 平移断层 6 断层上盘地质体代号 Fault_Up_Body Character S1sh, S1xt, O1–2d, O1h 7 断层下盘地质体代号 Fault_Bottom_Body Character S1l, O2–3sh–O3w, O1–2d 8 断层破碎带宽度/m Fault_Wide Character 0.6–2 9 断层走向/° Fault_Strike Integer 27–48 10 断层倾向/° Fault_Dip Integer 117–138 11 断层面倾角/° Fault_Dip_Angle Integer 43–86 12 估计断/m Fault_Distance Float 100 13 断层形成时代 Era Character 燕山期 14 活动期次 Movement_Period Character 燕山期–加里东期 15 子类型标识 Subtype Integer 1
下载: 导出CSV
表 5 褶皱图层数据表
序号 数据项名称 数据项代码 实例 1 图元编号 CHFCAC 1 2 褶皱名称 GZCAB 杉树湾向斜 3 褶皱类型 GZCE 向斜 4 褶皱形态 GZCDD 长轴 5 枢纽倾伏向 GZCCBE NE 6 枢纽倾伏角/° GZCCBF 5 7 轴面倾向 GZCCAE 近直立 8 轴面倾角/° GZCCAF 74 9 卷入褶皱的地层 GZCFA Є2p、Є 2q 10 形成时代 GZEKG Є 2q
下载: 导出CSV
表 6 同位素年龄图层数据表
序号 数据项名称 标准编码 数据类型 实例 1 要素标识号 *Feature_Id Character AH49E024005000000001 2 样品编号 Sample_Code Character HY–3 3 样品名称 Sample_Name Character 硅化白云岩 4 年龄测定方法 Measuring_Kinds Character 锆石定年 5 测定年龄/Ma Age Character 229.2±2.1 6 被测定出地质体单位及代号 Geobody_Code Character Є 3–4ls3 7 测定分析单位 Unit Character 武汉上谱分析科技有限责任公司 8 测定分析日期 Date Character 2017.9
下载: 导出CSV
表 7 产状要素图层数据表
序号 数据项名称 标准编码 数据类型 实例 1 要素标识号 *Feature_Id Character AH49E024005000000001 2 产状类型名称代码 *Feature_Type Character 01 3 产状类型名称 Attitude_Name Character 岩层产状 4 走向/° Strike Integer 161 5 倾向/° Dip_Direction Integer 71 6 倾角/° Dip_Angle Integer 19
下载: 导出CSV
表 8 矿产地图层数据表
序号 数据项名称 标准编码 数据类型 实例 1 要素标识号 *Feature_Id Character AH49E024005000000001 2 原编码 Source_Id Character 01 3 矿种代码 *Feature_Type Character CMMD010006 4 矿种名称 Commodities_Name Character 菱锰矿 5 共生矿 Paragenic_Ore Character 无 6 伴生矿 Associated_Ore Character 无 7 矿产地数 Ore_Sums Integer 1 8 矿石品位 Ore_Grade Character 矿石Mn品位15.83%~16.40%,平均16.00% 9 规模 Deposite_Size Character 超大型 10 成矿时代 Metallogenetic_Epoch Character 南华纪 11 矿产地名 Placename Character 贵州省松桃县桃子坪锰矿 12 矿化类型 Genesis_Types Character 黄铁矿化、硅化 13 成因类型 Industrial_Types Character 冶金用高磷低铁酸性锰矿石 14 子类型标识 Subtype Integer AH49E024005000000001
下载: 导出CSV
表 9 贵州铜仁松桃锰矿盘信幅(H49E024005)1∶50 000矿产地质图数据库数据
数据类型 数据量 数据基本特征 岩石化探分析数据 150件 15种元素(U、Th、Fe、Mn、Co、Ni、Cu、Pb、
Zn、Cr、Au、Ag、V、Ti、Al)一般岩矿分析数据 333件 基本化学分析 薄片鉴定数据 200片 矿物成分、含量; 岩石结构、构造等 同位素年龄数据 90点 锆石U–Pb年龄 矿产地数量 6个 锰矿(3个)、铅锌矿(2个)、汞矿(1个) 矿床类型 2种 沉积型锰矿、热液型铅锌矿、汞矿
下载: 导出CSV
Table 1. Metadata Table of Database (Dataset)
Items Description Database (Dataset) name 1∶50 000 Mineral Geological Map Database of the Panxin Map-sheet of the Songtao Manganese Deposit in Tongren, Guizhou Database (Dataset) authors Liu Jian, No.103 Geological Brigade of Guizhou Bureau of Geology and Mineral Exploration and Development
Yuan Liangjun, No.103 Geological Brigade of Guizhou Bureau of Geology and Mineral Exploration and Development
Xie Xiaofeng, No.103 Geological Brigade of Guizhou Bureau of Geology and Mineral Exploration and Development
Zhan Pengcai, No.103 Geological Brigade of Guizhou Bureau of Geology and Mineral Exploration and DevelopmentData acquisition time 2016–2018 Geographic area 109°00′–109°15E, 28°00′–28°10′N Data format *.wp, *.wl, *.wt Data size 39.7 MB Data service system URL http://dcc.cgs.gov.cn Fund project Funded by a subproject (121201004000160901–36) of China Geological Survey Project entitled Prospecting Prediction and Technical Application Demonstration in Integrated Exploration Areas Language Chinese Database (Dataset) composition The 1∶50 000 mineral geological map database of the Panxin Map-sheet includes geographic layers, formation–structure layers, mineral layers, and finishing layers. The geographic layers include main administrative boundaries, main settlements, main areal drainage systems, main linear drainage systems, and main geographic tags. The formation–structure layers include formations and structures (geological plane entity), geological (boundary) lines, folds, faults, synsedimentary faults, attitude features, and isotopic ages. The mineral deposit layer includes mineral deposits. The finishing layers include an internal and an external part. The internal finishing layer includes geological annotations and formation patterns, leader lines, fault dip directions, angles and fault natures, attitude dip angle annotations, isotope annotations, and transverse cutting profiles. The external finishing layer includes the index map, CGS emblem, map name, scale, coordinate parameter, duty tag, legend, columnar section of sedimentary rock formations, transverse cutting profile map, mineral species & size, mineral deposit directory, metallogenic zone location map, ore-bearing formation distribution map, typical deposit geological map and profile map, ore-bearing formation columnar section, and ore-bearing formation and ancient spray overflow port group distribution map.
下载: 导出CSV
Table 2. Datatable of the formation–structure layer
SN Data Name Standard Code Data Type Example 1 Geobody ID *Feature_Id Character AH49E024005000000001 2 Geobody Type Code(geological code) *Feature_Type Character O1h 3 Geobody name Geobody_Name Character Honghuayuan Fm 4 Geobody era Geobody_Era Character O1h 5 Formation category Formation Character Sedimentary rock formation 6 Formation type Metallogenic Character Limestone 7 Rock combination Combination Character Bioclastic limestone, coarse-grained limestone 8 Tectonic environment Structural_Env Character Upper Yangtze block, Hubei-Chongqing-Hunan-Guizhou foreland fold-fault zone
下载: 导出CSV
Table 3. Datatable of the geological (boundary) line layer
SN Data Name Standard Code Data Type Example 1 Feature ID *Feature_Id Character AH49E024005000000001 2 Geological boundary (contact) code *Feature_Type Character 01 3 Geological boundary type Boundary_Name Character Conformity 4 Geobody code in the left-side of boundary Left_Boundary_Code Character O1h 5 Geobody code in the right-side of boundary Right_Boundary_Code Character O1–2d 6 Interface strike/° Strike Integer 197 7 Interface dip direction/° Dip_Direction Integer 107 8 Interface dip angle/° Dip_Angle Integer 39
下载: 导出CSV
Table 4. Datatable of the fault layer
SN Data Name Standard Code Data Type Example 1 Feature classification code *Feature_Type Character F9 2 Fault type (geological code) Fault_Type Character F9 3 Fault name Fault_Name Character Shuiyuantou fault 4 Fault code Fault_Code Character H49E024005F9 5 Fault nature Fault_Character Character Reverse fault, strike-slip fault 6 Fault upside geobody ID Fault_Up_Body Character S1sh, S1xt, O1–2d, O1h 7 Fault downside geobody ID Fault_Bottom_Body Character S1l, O2–3sh–O3w, O1–2d 8 Fault fracture zone width/m Fault_Wide Character 0.6–2 9 Fault strike/° Fault_Strike Integer 27–48 10 Fault dip direction/° Fault_Dip Integer 117–138 11 Fault dip angle/° Fault_Dip_Angle Integer 43–86 12 Estimated fault distance/m Fault_Distance Float 100 13 Fault era Era Character Yanshanian 14 Movement period Movement_Period Character Yanshanian–Caledonian 15 Subtype ID Subtype Integer 1
下载: 导出CSV
Table 5. Datatable of the fold layer
SN Data Name Data Code Example 1 Pixel No. CHFCAC 1 2 Fold name GZCAB Shanshuwan syncline 3 Fold type GZCE Syncline 4 Fold shape GZCDD Major axis 5 Hub pitch direction GZCCBE NE 6 Hub pitch angle/° GZCCBF 5 7 Axis dip direction GZCCAE Nearly vertical 8 Axis dip angle/° GZCCAF 74 9 Strata involved in the fold GZCFA Є2p、Є 2q 10 Forming era GZEKG Є2q
下载: 导出CSV
Table 6. Datatable of the isotopic age layer
SN Data Name Standard Code Data Type Example 1 Feature ID *Feature_Id Character AH49E024005000000001 2 Sample code Sample_Code Character HY–3 3 Sample name Sample_Name Character Silicified dolomite 4 Age measured method Measuring_Kinds Character Zircon dating 5 Measured age/Ma Age Character 229.2±2.1 6 Unit & code of measured geobody Geobody_Code Character Є 3–4ls3 7 Unit of measurement Unit Character Wuhan Sample Solution Analytical Technology Co., Ltd. 8 Date of measurement Date Character 2017.9
下载: 导出CSV
Table 7. Datatable of the attitude feature layer
SN Data Name Standard Code Data Type 1 Feature ID *Feature_Id Character AH49E024005000000001 2 Name code of attitude type *Feature_Type Character 01 3 Name of attitude type Attitude_Name Character Rock attitude 4 Strike/° Strike Integer 161 5 Dip direction/° Dip_Direction Integer 71 6 Dip angle/° Dip_Angle Integer 19
下载: 导出CSV
Table 8. Datatable of the mineral deposit layer
SN Data Name Standard Code Data Type 1 Feature ID *Feature_Id Character AH49E024005000000001 2 Source ID Source_Id Character 01 3 Mineral species code *Feature_Type Character CMMD010006 4 Mineral species name Commodities_Name Character Rhodochrosite 5 Syngenetic ore Syngenetic_Ore Character Null 6 Associated ore Associated_Ore Character Null 7 Sum of mineral deposits Ore_Sums Integer 1 8 Ore grade Ore_Grade Character Mn ore’s grade: 15.83%–16.40%, avg. 16.00% 9 Size Deposit_Size Character Superlarge 10 Metallogenetic epoch Metallogenetic_Epoch Character Nanhuanian 11 Place name Placename Character Taoziping Mn deposit in Songtao, Guizhou 12 Mineralization type Genesis_Types Character Pyritization, silicification 13 Genesis type Industrial_Types Character High-P low-Fe acidic rhodochrosite ore for metallurgy 14 Subtype ID Subtype Integer AH49E024005000000001
下载: 导出CSV
Table 9. The 1∶50 000 mineral geological map database of the Panxin Map-sheet (H49E024005) of the Songtao Manganese Deposit in Tongren, Guizhou
Data Type Data quantity Data description Petrochemical exploration analysis data 150 15 elements (U, Th, Fe, Mn, Co, Ni, Cu, Pb, Zn, Cr, Au, Ag, V, Ti, Al) General rock/ore analysis data 333 General chemical analysis Thin section identification data 200 Mineral composition & contents; rock texture & structure Isotopic age data 90 spots Zircon U–Pb age Sum of mineral deposits 6 Mn deposit (3), Pb-Zn deposit (2), Hg deposit (1) Mineral deposit type 2 Sedimentary Mn deposit, hydrothermal Pb-Zn deposit and Hg deposit
下载: 导出CSV
-
[1] 陈甲赋, 马茁卉, 朱欣然, 殷俐娟. 2015. 主要矿产品供需形势分析报告(2015年)[M]. 北京: 地质出版社.
[2] 李永胜, 张生辉, 张彤, 何进忠, 张家瑞, 杜泽忠, 甄世民, 公凡影, 吕鑫. 2020. 1∶50 000 矿产地质图编制与数据库建设要求[J]. 中国地质, 47(S2): 1−15. https://www.cnki.com.cn/Article/CJFDTOTAL-DIZI2018S2001.htm
[3] 刘健, 袁良军, 谢小峰, 占朋才. 2020. 贵州铜仁松桃锰矿盘信幅 1∶50 000 矿产地质图数据库[DB/OL]. 地质科学数据出版系统. (2020-12-30).DOI: 10.35080/data.C.2020.P34.
[4] 刘雨, 周琦, 袁良军, 潘文, 张遂, 余文超, 王萍, 徐源, 洪万华. 2015a. 黔东松桃大塘坡地区南华系大塘坡组锰矿相带及分布规律[J]. 地质科技情报, 34(6): 40−46.
[5] 刘雨, 周琦, 袁良军, 张遂, 王萍. 2015b. 黔东大塘坡锰矿区古天然气渗漏喷溢口群发现及地质意义[J]. 贵州地质, 32(4): 250−255. https://www.cnki.com.cn/Article/CJFDTOTAL-GZDZ201504002.htm
[6] 潘桂棠, 肖庆辉, 陆松年, 邓晋福, 冯益民, 张克信, 张志勇, 王方国, 邢光福, 郝国杰, 冯艳芳. 2009. 中国大地构造单元划分[J]. 中国地质, 36(1): 1−28. doi: 10.3969/j.issn.1000-3657.2009.01.001
[7] 徐志刚, 陈毓川, 王登红, 陈郑辉. 2008.中国成矿带划分方案[M]. 北京: 地质出版社. 86 − 110.
[8] 周琦, 杜远生. 2012. 古天然气渗漏与锰矿成矿——以黔东地区南华纪“大塘坡式”锰矿为例[J]. 北京: 地质出版社. 1–110.
[9] 周琦, 杜远生, 覃英. 2013. 古天然气渗漏沉积型锰矿床成矿系统与成矿模式: 以黔湘渝毗邻区南华纪“大塘坡式”锰矿为例[J]. 矿床地质, 32(3): 457−466. doi: 10.3969/j.issn.0258-7106.2013.03.001
[10] 周琦, 杜远生, 袁良军, 张遂, 安正泽, 潘文, 杨炳南, 谢小峰, 余文超, 尹森林, 王萍, 吕代和, 徐源. 2016a. 贵州铜仁松桃锰矿国家整装勘查区地质找矿主要进展及潜力预测[J]. 贵州地质, 33(4): 237−244. doi: 10.3969/j.issn.1000-5943.2016.04.001
[11] 周琦, 杜远生, 袁良军, 张遂, 余文超, 杨胜堂, 刘雨. 2016b. 黔湘渝毗邻区南华纪裂谷盆地结构及其对锰矿的控制作用[J]. 地球科学, (2): 177−188. https://www.cnki.com.cn/Article/CJFDTOTAL-DQKX201602001.htm
[12] 周琦, 杜远生, 袁良军, 张遂, 杨炳南, 潘文, 余文超, 王萍, 徐源, 齐靓, 刘雨, 覃永军, 谢小峰. 2017. 古天然气渗漏沉积型锰矿床找矿模型——以黔湘渝毗邻区南华纪“大塘坡式”锰矿为例[J]. 地质学报, 91(10): 2285−2298. doi: 10.3969/j.issn.0001-5717.2017.10.010
[13] 周琦, 杜远生. 2019. 华南古天然气渗漏沉积型锰矿[M]. 北京: 科学出版社.
[14] 中国地质调查局. 2006. DD2006–06数字地质图空间数据库标准.
[15] 中国地质调查局. 2019. DD2019–02矿产地质调查技术要求(1∶50 000).
[1] Chen Jiafu, Ma Zhuhui, Zhu Xinran, Yin Lijuan. 2015. Analytical report on supply and demand situation of main mineral products (2015) [M]. Beijing: Geological Publishing House (in Chinese).
[2] China Geological Survey. 2006. DD2006–06 Digital Geological Map Spatial Database Standard (in Chinese).
[3] China Geological Survey. 2019. DD2019–02 Technical Requirements For Mineral Geological Survey (1∶50 000) (in Chinese).
[4] Li Yongsheng, Zhang Shenghui, Zhang Tong, He Jinzhong, Zhang Jiarui, Du Zezhong, Zhen Shimin, Gong Fanying, Lyu Xin. 2020. Requirements of map compilation and database building of 1∶50 000 mineral geological maps[J]. Geology in China, 47(S2): 1−23.
[5] Liu Jian, Yuan Liangjun, Xie Xiaofeng, Zhan Pengcai. 2020. 1∶50 000 Mineral Geological Map Database of the Panxin Map-sheet of the Songtao Manganese Deposit in Tongren, Guizhou[DB/OL]. Geoscientific Data & Discovery Publishing System. (2020-12-30). DOI: 10.35080/data.C.2020.P34.
[6] Liu Yu, Zhou Qi, Yuan Liangjun, Pan Wen, Zhang Sui, Yu Wenchao, Wang Ping, Xu Yuan, Hong Wanhua. 2015a. Manganese ore phase and distribution of Nanhua Datangpo Formation in Datangpo area, Songtao, East Guizhou[J]. Geological Science and Technology Information, 34(6): 40−46 (in Chinese with English abstract).
[7] Liu Yu, Zhou Qi, Yuan Liangjun, Zhang Sui, Wang Ping. 2015b. The found of the ancient natural gas leakage spray overflow port group and its geological significance in Datangpo mining of East Guizhou[J]. Guizhou Geology, 32(4): 250−255 (in Chinese with English abstract).
[8] Pan Guitang, Xiao Qinghui, Lu Songnian, Deng Jinfu, Feng Yimin, Zhang Kexin, Zhang Zhiyong, Wang Fangguo, Xing Guangfu, Hao Guojie, Feng Yanfang. 2009. Subdivision of tectonic units in China[J]. Geology in China, 36(1): 1−28 (in Chinese with English abstract).
[9] Xu Zhigang, Chen Yuchuan, Wang Denghong, Chen Zhenghui. 2008. Division scheme of metallogenic belts in China[M]. Beijing: Geological Publishing House, 86−110(in Chinese).
[10] Zhou Qi, Du Yuansheng. 2012. Ancient natural gas leakage and manganese metallogenesis: a case study of the Nanhuaian “Datangpo-type” manganese deposit in East Guizhou[J]. Beijing: Geological Publishing House, : 1−110 (in Chinese).
[11] Zhou Qi, Du Yuansheng, Qin Ying. 2013. Ancient natural gas seepage sedimentary-type manganese metallogenic system and ore-forming model: A case study of 'Datangpo type' manganese deposits formed in rift basin of Nanhua Period along Guizhou-Hunan-Chongqing border area[J]. Mineral Deposits, 32(3): 457−466 (in Chinese with English abstract
[12] Zhou Qi, Du Yuansheng, Yuan Liangjun, Zhang Sui, An Zhengze, Pan Wen, Yang Bingnan, Xie Xiaofeng, Yu Wenchao, Yin Linlin, Wang Ping, Lyu Daihe, Xu Yuan. 2016a. Prediction of Geologic Exploration in Songtao Manganese National Fully Equipped Exploration District in Tongren, Guizhou[J]. Guizhou Geology, 33(4): 237−244 (in Chinese with English abstract).
[13] Zhou Qi, Du Yuansheng, Yuan Liangjun, Zhang Sui, Yu Wenchao, Yang Shengtang, Liu Yu. 2016b. The structure of the Wuling rift basin and its control on the manganese deposit during the Nanhua Period in Guizhou-Hunan-Chongqing border area, South China[J]. Earth Science, 41(2): 177−188 (in Chinese with English abstract).
[14] Zhou Qi, Du Yuansheng, Yuan Liangjun, Zhang Sui, Yang Bingnan, Pan Wen, Yu Wenchao, Wang Ping, Xu Yuan, Qi Liang, Liu Yu, Qin Yongjun, Xie Xiaofeng. 2017. Exploration models of ancient natural gas seep sedimentary-type manganese ore deposit: A case study of the Nanhua Period “Datangpo” type manganese ore in the conjunction area of Guizhou, Hunan and Chongqing[J]. Acta Geologica Sinica, 91(10): 2285−2298 (in Chinese with English abstract).
[15] Zhou Qi, Du Yuansheng. 2019. Ancient natural gas leakage sedimentary manganese deposits in South China[M]. Beijing: Science Press (in Chinese).
-
图(8)
表(18)
计量
- 文章访问数: 1644
- PDF下载数: 115
- 施引文献: 0