The 1:50 000 MineralGeological Map Dataset of the Yinkeng Map-sheet, Yudu Au-Ag Multi-metal Ore Integrated Area, South Jiangxi
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摘要:
本数据集综合应用岩性-构造-矿化蚀变专项填图、遥感、物探、化探、钻探等多种方法进行数据采集,完成路线调查长度520.65 km,采集水系沉积物样品2 047件,遥感数据解译面积461 km2,化学分析样167件。重点对燕山早期成矿岩浆岩、含矿建造、控岩控矿构造,以及矿化蚀变标志等进行了调查划分,明确区内银金多金属矿主要成矿地质体为燕山早期花岗闪长岩,控岩控矿构造为北东向逆冲断裂及其次级裂隙。在此基础上,编制了1:50 000银坑幅建造构造图,利用数字化填图系统(DGSS)创建了区内矿产地质图数据库,全面汇编了重要建造构造、地质界线、断裂、岩浆岩等图层属性库;完善了银坑式中低温岩浆期后热液矿床找矿预测模型,突出了区内矿产与建造构造之间的成因联系。
Abstract:In order to develop this dataset, data were acquired comprehensively by using multiple methods such as mapping which is specific for lithology, structures and mineralized alterations, remote-sensing, geophysical/geochemical and drilling exploration. A route of 520.65 km was surveyed, with 2 047 stream sediment samples and 167 chemical analytical samples collected, and 461 km2 area interpreted based on remote-sensing data. Emphasis was placed on survey and division of early-Yanshanian metallogenic magmatite, ore-bearing formations, rock-control and ore-control structures, and mineralized alteration marks etc., so that it could be verified that the main metallogenic geological bodies for Au-Ag multi-metal ores within the area were early-Yanshanian granodiorite and that the rock-control and ore-control formations were a NE-strike thrust fault and its secondary fissures. Building on this, the 1: 50 000 formation and tectonic map of the Yinkeng Map-sheet was compiled, the mineral geological map dataset was established by using a digital mapping system (DGSS), a map layer property database on key formations & tectonics, geological boundaries, fractures and magmatite etc. was comprehensively compiled; the prospecting prediction model for Yinkeng-style mid-low temperature post-magmatic hydrothermal deposits in the area was improved, highlighting the causal relationship between deposits and the formations or structures in the area.
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图 3 Prospection prediction model for low- and medium-temperature post-magma-period hydrothermal-solution-type Au-Ag multi-metal deposits in the style of Yinkeng, South Jiangxi
表 1 数据库(集)元数据简表
条目 描述 数据库(集)名称 赣南于都金银多金属矿整装勘查区1∶50 000银坑幅矿产地质图数据集 数据库(集)作者 贺根文,江西省地质矿产勘查开发局赣南地质调查大队
于长琦,江西省地质矿产勘查开发局赣南地质调查大队
李 伟,江西省地质矿产勘查开发局赣南地质调查大队
刘孝滨,江西省地质矿产勘查开发局赣南地质调查大队
周兴华,江西省地质矿产勘查开发局赣南地质调查大队数据时间范围 2016−2018 地理区域 江西省赣州市,东经115°30′~115°45′,北纬26°10′~26°20′ 数据格式 *.wp,*.wl,*.wt,*.docx 数据量 59.5 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(121201004000160910-13)资助 语种 中文 数据库(集)组成 该数据集主要由矿产地质图(MapGIS格式)及矿产信息卡片(Word格式)组成。矿产地质图主要由主图、综合柱状图、镶图、地质构造格架剖面图、成矿区带图及图例组成。镶图包括牛形坝银金矿和狮吼山矽卡岩型硫铁多金属矿2个典型矿床的平面图和剖面图;图例包括构造、蚀变矿化、岩脉、矿产图例;修饰内容主要包括责任表、中国地质调查局局徽及图幅索引。银坑幅矿产信息卡片汇编了图幅内主要的矿床、矿点情况,包括金属矿产、能源矿产和非金属矿产,共16个矿区的基本矿产地质信息。 
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表 2 赣南银坑式中低温岩浆期后热液型银金多金属矿预测要素表
预测要素 描述内容 分类 成矿地质背景 大地构造位置 武夷隆起西缘,宁都−南城拗陷断束南端和信丰−于都拗陷褶束交接部位的青塘−银坑拗陷带 重要 区域成矿带 雩山隆褶带W−Ag−Pb−Zn−Au−Sn成矿亚带 重要 岩浆岩带 于山岩浆岩褶隆带 重要 成矿时代 燕山早期 重要 矿床特征 成矿地质体 燕山早期的花岗闪长斑岩、花岗闪长岩 必要 含矿建造 中新元古代浅变质沉火山碎屑岩建造 重要 成矿构造及
结构面破碎蚀变岩型银铅锌矿主要受青塘−于都银坑叠瓦状逆冲推覆构造带的控制,由一系列北北东向呈“S”状延伸的叠瓦状逆冲断裂组成。赋矿构造为近东西向张性断裂。 重要 成矿作用特征 矿体
特征矿体以似层状、透镜状产出为主,沿走向及倾斜方向上具膨大缩小、分支复合及尖灭再现等现象,产状较陡。 重要 矿物
组合主要矿石矿物为方铅矿、黄铁矿、闪锌矿、黄铜矿、自然金等;脉石矿物为石英、方解石等。 必要 主金属元素 Pb、Zn、Cu、Au、Ag 次要 矿床分带性 靠近江背花岗岩为W、Mo等中高温矿化组合,靠近高山角岩体为Pb、Zn、Ag、Au等中低温矿化组合。 重要 蚀变
类型以硅化为主,次为黄铁矿化、绢云母化、绿泥石化及碳酸盐化 重要 成矿模式 岩浆期后中低温热液脉型银金铅锌(铜)矿床 重要 物化遥综合信息 化探异常 Au、Ag、Pb、Zn、As等元素水系沉积物化探异常,汞气异常。 重要 物探异常 岩体位于负重力异常区,高磁异常;矿体位于正低磁异常。 重要 遥感异常 环形、弧形构造,羟基、铁染异常明显 重要
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表 3 银坑幅矿产地质图建造-构造图层属性表
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 字符串 AG50E011007000000035 2 地质体面实体类型代码(地质代码) Feature_Type 字符串 Pt31bk2 3 地质体面实体名称 Geobody_Name 字符串 青白口系库里组二段 4 地质体面实体时代 Geobody_Era 字符串 Pt3 5 建造大类 Formation 字符串 变质岩建造 6 建造类型 Metallogenic 字符串 变质粉屑沉凝灰岩变质建造 7 岩石组合 Combination 字符串 变质粉屑沉凝灰岩 8 大地构造环境 Structural_Env 字符串 大地构造位置处于武夷块体与罗霄块体的交接带上
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表 4 银坑幅矿产地质图地质界线属性表
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 字符串 AG50E011007000001818 2 地质界线(接触)代码 Feature_Type 字符串 F5 3 地质界线类型 Boundary_Name 字符串 断层接触 4 界线左侧地质体代号 Left_Boundary_Code 字符串 Pt31bk2 5 界线右侧地质体代号 Right_Boundary_Code 字符串 J2l2 6 界面走向 Strike 整数型 19 7 界面倾向 Dip_Direction 整数型 109 8 界面倾角 Dip_Angle 整数型 72
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表 5 银坑幅矿产地质图断裂构造属性表
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 字符串 F1 2 断层类型(地质代码) Fault_Type 字符串 F1 3 断层名称 Fault_Name 字符串 牛形坝−岩前断层F1 4 断层编号 Fault_Code 字符串 G50E011007F1 5 断层性质 Fault_Character 字符串 逆冲断层 6 断层上盘地质体代号 Fault_Up_Body 字符串 Nh1s,J2l2,Pt31bk2,D2y,P3l,P2c 7 断层下盘地质体代号 Fault_Bottom_Body 字符串 D2-3z-D3zd,Pt31bk2,J2l2,Nh1s 8 断层破碎带宽度 Fault_Wide 字符串 20~30m 9 断层走向 Fault_Strike 整数型 26 10 断层倾向 Fault_Dip 整数型 58 11 断层面倾角 Fault_Dip_Angle 整数型 116 12 估计断距 Fault_Distance 浮点型 1 000m 13 断层形成时代 Era 字符串 燕山期 14 活动期次 Movement_Period 字符串 燕山期
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表 6 银坑幅矿产地质图矿产地属性表
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 字符串 AG50E011007000000007 2 矿种代码 Feature_Type 字符串 2202、2007、2008、2201、2006 3 矿种名称 Commodities_Name 字符串 Ag、Pb、Zn、Au、Cu 4 共生矿 Paragenic_Ore 字符串 Ag、Pb、Zn 5 伴生矿 Associated_Ore 字符串 Au、Cu 6 矿产地数 Ore_Sums 整数型 1 7 矿石品位 Ore_Grade 字符串 Au2.3g/t、Ag160g/t、Pb+Zn7%、Cu0.3% 8 规模 Deposite_Size 字符串 大型银矿床、中型金矿床 9 成矿时代 Metallogenetic_Epoch 字符串 燕山早期 10 矿产地名 Placename 字符串 牛形坝金银多金属矿 11 矿化类型 Genesis_Types 字符串 破碎蚀变岩型 12 成因类型 Industrial_Types 字符串 中低温岩浆期后热液
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表 7 银坑幅矿产地质图侵入岩建造图层属性表
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 字符串 AG50E011007000000001 2 岩体填图单位名称 Intru_Body_Name 字符串 岽下山岩体 3 岩体填图单位符号 Intru_Body_Code 字符串 ηγβJ3D 4 岩石名称 Rock_Name 字符串 中细粒斑状黑云母二长花岗岩 5 岩石颜色 Color 字符串 浅肉红色 6 岩石结构 Rock_Texture 字符串 中细粒似斑状结构 7 岩石构造 Rock_Structure 字符串 块状构造 8 主要矿物及含量 Primary_Mineral 字符串 石英35%,钾长石30%,斜长石30% 9 次要矿物及含量 Secondary_Mineral 字符串 黑云母5% 10 与围岩接触关系 Contact_Relation 字符串 侵入接触 11 形成时代 Era 字符串 燕山期 12 含矿性 Commodities 字符串 W、Sn
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表 1 Metadata Table of Database (Dataset)
Items Description Database(dataset) name 1∶50 000 Mineral Geological Map Dataset of the Yinkeng Map-sheet, Yudu Au-Ag Multi-metal Ore Integrated Area, South Jiangxi Database(dataset) authors He Genwen, Gannan Geological Party, JBED GMR
Yu Changqi, Gannan Geological Party, JBED GMR
Li Wei, Gannan Geological Party, JBED GMR
Liu Xiaobin, Gannan Geological Party, JBED GMR
Zhou Xinghua, Gannan Geological Party, JBED GMRData acquision time 2016—2018 Geographic area Ganzhou City, Jiangxi Province; East Longitude: 115°30′~115°45′; North Latitude: 26°10′~26°20′ Data format *.wp, *.wl, *.wt, *.docx Data size 59.5 MB Data service system URL http://dcc.cgs.gov.cn Fund project China Geological Survey Project “Demonstration Sub-project for Prospecting Prediction and Technical Application in Integrated Survey Areas” (121201004000160910-13). Language Chinese Database(dataset) composition The dataset mainly consists of the mineral geological maps (MapGIS) and mineral information cards (Word). The mineral geological maps mainly include master maps, overall histograms, mosaic maps, geological tectonic framework profiles, metallogenic zone/belt maps and legends. Mosaic maps include plans and profiles of 2 typical deposits, Niuxingbao Au deposit and Shihoushan skarn-type ferrous-sulfide multi-metal deposit; legends include those for tectonic, altered mineralization, vein and minerals; decorations mainly include the responsibility matrix, CGS logo and map-sheet index. The Yinkeng-map-sheet information cards contain basic mineral geological information in 16 mining areas such as primary deposits and mineral occurrences in the map sheet, including metal, energy and non-metal minerals.
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表 2 Elements for the prediction of the low- and medium-temperature post-magma-period hydrothermal-solution-type Au-Ag multi-metal ores in the style of Yinkeng, South Jiangxi
Element for prediction Description Classification Metallogenic geological background Geotectonic location Qingtang-Yinkeng depression zone, in the western margin of the Wuyi uplift, at the intersection of the south end of the Ningdu-Nancheng depression fault bundle and the Xinfeng-Yudu depression fold important Regional metallogenic zone W−Ag−Pb−Zn−Au−Sn metallogenic sub-zone of the Yu-mountain uplift fold zone important Magmatite zone Yushan magmatite fold-uplift zone important Mineralogenetic epoch Early Yanshanian important Deposit feature Metallogenic geological body early-Yanshanian granodiorite porphyry, and granodiorite necessary Deposit feature Ore-bearing formation mid-Neoproterozoic epimetamorphic sed-volcanic pyroclastic rock formation important Metallogenic tectonic and
structural placeBroken-altered-rock-type Ag-Pb-Zn deposit is mainly under control of the Qingtan-Yudu Yinkeng imbricated reverse-thrust napped structural zone, and is composed of a series of imbricated reverse-thrust fractures which extend with NNE strike in the shape of a letter ‘S’. Its ore-occurrence structure is the nearly EW extension fracture. important Features of metallogenesis Features of mineral bodies Most mineral bodies are bedded and lentoid, there are phenomena such as expansion and contraction, branching and then combination, or thinning-out and recurrence in their strike and their slant direction, with steeper altitude. important Ore combination Ores are mainly galena, pyrite, sphalerite, chalcopyrite and native gold etc; gangue ores are quartz and calcite etc. necessary Main metal elements Pb. Zn. Cu. Au. Ag secondary Deposit zonation Near the Jiangbei granite are mid-and-high temperature mineralization combinations of W and Mo etc. while near the Gaoshanjiao rock mass are mid-and low-temperature mineralization combinations of Pb, Zn, Ag and Au. important Alteration type Primarily silicification, secondarily pyritization, sericitization, chloritization and carbonatization important Metallogenic mode Post-magma-period, mid- and low-temperature hydrothermal-solution-type Ag-Au-Pb(-Cu) deposit important Combined information from geochemical and geophysical exploration and remote-sensing Anomaly from geochemical exploration Anomaly from stream sediments of elements such as Au, Ag, Pb, Zn and As from geochemical and geophysical exploration, and anomaly in mercury-vapour. important Anomaly from geophysical exploration Rock mass is located in a negative-gravity anomaly region, with a high magnetic anomaly; the mineral body is located in the positive low-magnetic anomaly area. important Anomaly from remote-sensing Structure in the shape of ring and arc, with a clear hydroxyl and iron-stained anomaly. important
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表 3 Property table of formation - tectonic map layer in mineral geological map of the Yinkeng map-sheet
No. Name of data item Standard code Data category Real example 1 Mark number of geological body’s planar map layer Feature_Id Character string AG50E011007000000035 2 Type code of geological body’s planar map layer (geological code) Feature_Type Character string Pt31bk2 3 Name of geological body’s planar map layer Geobody_Name Character string Member #2 of the Qingbaikou-system Kuli Formation 4 Era of geological body’s planar map layer Geobody_Era Character string Pt3 5 Formation category Formation Character string Metamorphic rock formation 6 Formation type Metallogenic Character string Metamorphic powder tuffite metamorphic formation 7 Rock combination Combination Character string Metamorphic powder tuffite 8 Geotectonic setting Structural_Env Character string Regarding its geotectonic location, it is located at the connecting zone between the Wuyi and Luoxiao blocks.
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表 4 Geological boundary property table of the mineral geological map of the Yinkeng map-sheet
No. Name of data item Standard code Data category Real example 1 Element identification number Feature_Id Character string AG50E011007000001818 2 Geological boundary (contact) code Feature_Type Character string F5 3 Geological boundary type Boundary_Name Character string Fault contact 4 Code of geological body to the left of the boundary Left_Boundary_Code Character string Pt31bk2 5 Code of geological body to the right of the boundary Right_Boundary_Code Character string J2l2 6 Interface strike Strike Integer 19 7 Interface dip Dip_Direction Integer 109 8 Interface dip angle Dip_Angle Integer 72
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表 5 Fracture property table of the mineral geological map of the Yinkeng map-sheet
No. Name of data item Standard code Data category Real example 1 Element classification code Feature_Type Character string F1 2 Fault type (geological code) Fault_Type Character string F1 3 Fault name Fault_Name Character string Niuxingba − Yanqian fault F1 4 Fault code Fault_Code Character string G50E011007F1 5 Fault property Fault_Character Character string Thrust fault fault 6 Code of geological body overlying the fault Fault_Up_Body Character string Nh1s,J2l2,Pt31bk2,D2y,P3l,P2c 7 Code of geological body underlying the fault Fault_Bottom_Body Character string D2-3z-D3zd,Pt31bk2,J2l2,Nh1s 8 Width of crushed zone
of faultFault_Wide Character string 20~30 m 9 Fault strike Fault_Strike Integer 26 10 Fault dip Fault_Dip Integer 58 11 Fault dip angle Fault_Dip_Angle Integer 116 12 Estimated fault displacement Fault_Distance Floating-point type 1 000 m 13 Era of fault generation Era Character string Yanshanian 14 Movement periods Movement_Period Character string Yanshanian
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表 6 Deposit site property table of the mineral geological map of the Yinkeng map-sheet
No. Name of data item Standard code Data category Real example 1 Element identification number Feature_Id Character string AG50E011007000000007 2 Ore type code Feature_Type Character string 2202, 2007, 2008, 2201, 2006 3 Ore name Commodities_Name Character string Ag, Pb, Zn, Au, Cu 4 Paragenic ore Paragenic_Ore Character string Ag, Pb, Zn 5 Associated ore Associated_Ore Character string Au, Cu 6 Number of deposit sites Ore_Sums Integer 1 7 Ore grade Ore_Grade Character string Au 2.3 g/t, Ag 160 g/t, Pb+Zn 7%, Cu 0.3% 8 Scale Deposite_Size Character string Large Ag deposit, and medium Au deposit 9 Metallogenic epoch Metallogenic_Epoch Character string Early Yanshanian 10 Deposit site name Placename Character string Niuxingba Au-Ag multi-metal deposit 11 Mineralization types Genesis_Types Character string Crushed altered rock 12 Genesis type Industrial_Types Character string Low- and mid post-magma-period hydrothermal solution
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表 7 Intrusive rock formation property table of the mineral geological map of the Yinkeng map-sheet
No. Name of data item Standard code Data category Real example 1 Element identification number Feature_Id Character string AG50E011007000000001 2 Name of rock mass mapped Intru_Body_Name Character string Dongxiashan rock mass 3 Symbol of rock mass mapped Intru_Body_Code Character string ηγβJ3D 4 Rock name Rock_Name Character string Medium/fine-grain porphyritic biotite monzonitic granite 5 Rock color Color Character string Light pink 6 Rock texture Rock_Texture Character string Medium/fine-grain porphyritic-like texture 7 Rock structure Rock_Structure Character string Blocky structure 8 Primary mineral and content Primary_Mineral Character string Quartz: 35%; K-feldspar: 30%; plagioclase: 30% 9 Secondary mineral and content Secondary_Mineral Character string Biotite: 5% 10 Contact relation with wall rock Contact_Relation Character string Intrusive contact 11 Generation era Era Character string Yanshanian 12 Ore-bearing potential Commodities Character string W, Sn
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