Research progress of quantitative determination of mineral content in China
MA Chi1,2, WANG Shoujing1,2
1. Zhengzhou Institute of Multipurpose Utilization of Mineral Resources,Chinese Academy of Geological Science,Zhengzhou 450006,China; 2. China National Engineering Research Center for Utilization of Industrial Minerals,Zhengzhou 450006,China
Abstract:In the studies of geology, mineral processing, metallurgy and mineral materials, the quantitative analysis of mineral content is a very important basic work, which is helpful to identify the occurrence state of minerals and determine the composition, grade, economic value of materials as well as the method of beneficiation and smelting. Due to the differences in particle size, crystallization degree, chemical composition and occurrence state of minerals, it is generally difficult for a single mineral quantitative method to meet the requirements of practical work. If necessary, two or more mineral quantitative methods need to be used for joint determination. At present, optical microscopy, physicochemical separation, X-ray diffraction,characteristic element chemical calculation,infrared spectroscopy, and automatic scanning electron microscopy system quantification as well as other analytical methods are mostly used for mineral content determination. The research progress of various measurement methods are discussed, the specific requirements, advantages and disadvantages of these methods are summarized, and the research directions in future are proposed .
马驰, 王守敬. 我国矿物含量定量测定的研究进展[J]. 冶金分析, 2023, 43(6): 47-54.
MA Chi, WANG Shoujing. Research progress of quantitative determination of mineral content in China. , 2023, 43(6): 47-54.
[1] 张瀚之,鹿化煜,周亚利,等.渭河流域沉积矿物组合定量分析及示踪[J].沉积学报,2022,40(4):944-956. ZHANG Hanzhi,LU Huayu,ZHOU Yali,et al.Quantitative analysis of the clastic mineral composition in sediments from the Weihe River basin by scanning electron microscope and its implication for provenance[J].Acta Sedimentologica Sinica,2022,40(4):944-956. [2] 程建伟,任瑞晨.Rietveld全谱拟合在矿物加工工程中的应用[J].有色矿冶,2006(S1):25-27. CHENG Jianwei,REN Ruichen.Application of Rietveld full spectrum fitting in mineral processing engineering[J].Non-Ferrous and Metallurgy,2006(S1):25-27. [3] 付伟,彭召,曾祥伟,等.基于XRD-Rietveld全谱拟合技术定量分析花岗岩风化壳中矿物组成[J].光谱学与光谱分析,2018,38(7):2290-2295. FU Wei,PENG Zhao,ZENG Xiangwei,et al.Quantitative analysis of mineral composition in Granite Regolith based on XRD-Rietveld full-spectrum fitting method[J].Spectroscopy and Spectral Analysis,2018,38(7):2290-2295. [4] 任瑞晨,梁天书,李彩霞,等.论矿物材料计算与设计[J].资源科学,2005(3):167-174. REN Ruichen,LIANG Tianshu,LI Caixia,et al.Calculation and design of mineral materials[J].Resources Science,2005(3):167-174. [5] 程寄皋,龚文浩.体视学在工艺矿物学定量中的应用[J].武汉冶金科技大学学报,1996,19(2):135-137. CHENG Jigao,GONG Wenhao.Application of Stereology in process mineral quantification[J].Journal of Wuhan Yejin University of Science and Technology,1996,19(2):135-137. [6] 杨炳飞,冯安生.旋转载物台显微镜下矿物定量及其精确性研究[J].岩矿测试,2018,37(3):292-297. YANG Bingfei,FENG Ansheng.Study on accuracy of quantitative analysis of minerals under rotating stage microscopy[J].Rock and Mineral Analysis,2018,37(3):292-297. [7] 邹金生.矿物定量的新方法-化学全物相分析法[J].矿物学报,1983,12(4):289-294. ZOU Jinsheng.Chemico-physical phase analysis-a new method for quantitative determination of mineral composition[J].Acta Mineralogica Sinica,1983,12(4):289-294. [8] 黄易勤.中越边境某氧化镍矿石的矿物定量方法[J].中国矿业,2007,16(5):110-112. HUANG Yiqin.Chinese and Vietnamese frontier some oxidation ore mineral quantitative method[J].China Mining Magazine,2007,16(5):110-112. [9] 夏新媛,王恒,乔柱,等.手工内磁选-重铬酸钾滴定法测定铜磁铁矿中磁性铁含量[J].化学分析计量,2015,24(5):27-30. XIA Xinyuan,WANG Heng,QIAO Zhu,et al.Detrmination of magnet iron content in copper magnetite by manual inside magnetic separation-potassium dichromate titration method[J].Chemical Analysis and Meterage,2015,24(5):27-30. [10] 吴晗,刘嵘,钟志华.一种新型的地质样品分离技术:电力学崩解法的工作原理及应用前景[J].地质科技情报,2016,35(6):257-261. WU Han,LIU Rong,ZHONG Zhihua.A new seperation technology of geological samples: working principles and application prospects of electrodynamic disaggregation method[J].Geological Science and Technology Information,2016,35(6):257-261. [11] 杨炳红,符招弟,傅饶,等.复杂钼矿石中钼的化学物相分析[J].冶金分析,2020,40(4):23-28. YANG Binghong,FU Zhaodi,FU Rao,et al.Chemical phase analysis of molybdenum in complex molybdenum ore[J].Metallurgical Analysis,2020,40(4):23-28. [12] 夏传波,王卿,张文娟,等.钛矿石化学成分及物相分析方法研究进展[J].冶金分析,2021,41(11):21-30. XIA Chuanbo,WANG Qing,ZHANG Wenjuan,et al.Research progress in Chemical composition and phase analysis methods for titanium ore[J].Metallurgical Analysis,2021,41(11):21-30. [13] 杜晓冉,智红梅,张金矿,等.X射线衍射法定量分析蓝晶石样品[J].理化检验(化学分册),2013,49(4):402-404. DU Xiaoran,ZHI Hongmei,ZHANG Jinkuang,et al.Quantitative analysis of Kyanite sample with X-ray diffractometry[J].Physical Testing and Chemical Analysis(Part B:Chemical Analysis),2013,49(4):402-404. [14] 王芙云.采用X射线衍射法分析耐火材料中非晶相含量[J].耐火与石灰,2020,45(6):35-40. WANG Fuyun.Determination of amorphous phases in refractory materials by X-ray diffraction[J].Refractories & Lime,2020,45(6):35-40. [15] 郝原芳,赵爱林.方解石、白云石定量分析-X射线衍射法快速分析[J].有色矿冶,2005,21(5):58-60. HAO Yuanfang,ZHAO Ailin.A simple method of quantitative analysis for Calcite and Dolomite in rock by X-ray diffraction[J].Non-ferrous Mining and Metallurgy,2005,21(5):58-60. [16] 袁珂,廖立兵,万红波,等.膨润土中方石英和α-石英的定量相分析——X射线衍射外标法和K值法的对比[J].硅酸盐学报,2011,39(2):377-382. YUAN Ke,LIAO Libing,WAN Hongbo,et al.Quantitative analysis of cristobalite and α-quartz in bentonite by X-ray powder diffraction-comparison between external standard and K-value method[J].Journal of the Chinese Ceramic Society,2011,39(2):377-382. [17] 赵伟,封亚辉,李建军.X射线衍射法快速测定矿产品中的主要物相和主元素含量[J].理化检验(化学分册),2015,51(4):523-527. ZHAO Wei,FENG Yahui,LI Jianjun.XRD determination of the main phase and the main elements of mineral[J].Physical Testing and Chemical Analysis(Part B:Chemical Analysis),2015,51(4):523-527. [18] 陆琦,刘惠芳,雷新荣.蒙脱石+伊/蒙混层+伊利石等粘土矿物混合物相X 射线定量分析方法-模拟定量法[J].矿物学报,1993,13(1):12-20. LU Qi,LIU Huifang,LEI Xinrong.Simulating quantitative analysis method-quantitative analysis of clay mineral mixtures of montmorillonite, illite/smectite interstratified clay minerals,illite,chlorite and some others[J].Acta Mineralogica Sinica,1993,13(1):12-20. [19] 黄志良.化学成分满足法测算高分散度粉体的矿物含量[J].武汉化工学院学报,1995,17(3):45-49. HUANG Zhiliang.The method of satisfied chemical compositions for determination and calculation of mineral content of undue pulverious materials[J].Journal of Wuhan Institute of Chemical Technology,1995,17(3):45-49. [20] 黄智龙,朱丹.云南镇沅金矿区煌斑岩矿物含量统计及其意义[J].地质地球化学,1997(3):19-24. HUANG Zhilong,ZHU Dan.The statistics and significance of mineral contents for lamprophynes in Zhenyuan gold deposit Yunnan province[J].Geology Geochemistry,1997(3):19-24. [21] 李光明,陈昭奎.山东省某榴辉岩矿床矿物含量计算方法的研究与应用[J].中国非金属矿工业导刊,2001(2):21-24. LI Guangming,CHEN Zhaokui.The research and application of calculational methods about a eclogite deposite mineral contents in Shandong province,China[J].China Non-Metallic Minerals Industry,2001(2):21-24. [22] 刘玉瑛,金明鸥,张甲珩.线性规划在白云鄂博矿物定量中的应用[J].包头钢铁学院学报,1997,16(2):156-161. LIU Yuying,JIN Ming’ou,ZHANG Jiahang.The application of linear programming in Baiyunebo mineral measurement[J].Journal of Baotou University of Iron and Steel Technology,1997,16(2):156-161. [23] 郭泽泽,李喜安,陈阳,等.基于SEM-EDS的湿陷性黄土黏土矿物定量分析[J].工程地质学报,2016,24(5):899-906. GUO Zeze,LI Xi’an,CHEN Yang,et al.Analysis of clay minerals in collapsible loess with SEM-EDS[J].Journal of Engineering Geology,2016,24(5):899-906. [24] 王守敬,卞孝东,马驰.某榴辉岩工艺矿物学及矿物快速定量方法研究[J].矿产保护与利用,2011,12(5):24-27. WANG Shoujing,BIAN Xiaodong,MA Chi.Study on process mineralogy of an eclogite and the mineral fast quantitative method[J].Conservation and Utilization of Mineral Resources,2011,12(5):24-27. [25] 郝立波,赵洪振,陆继龙,等.中酸性火山岩中造岩矿物含量的定量计算方法[J].岩石学报,2006,22(2):480-484. HAO Libo,ZHAO Hongzhen,LU Jilong,et al.The quantitative calculation method of the petrogenetic mineral content in intermediate-acid volcanic rock[J].Acta Petrologica Sinica,2006,22(2):480-484. [26] 夏玉容,周伟.线性规划在矿物含量定量中的应用[J].金属矿山(Metal Mine),1991,20(3):46-50. [27] 刘飞,陈岳龙,蒋丽婷.MATLAB在碎屑沉积岩矿物含量计算中的应用[J].沉积学报,2006(2):229-234. LIU Fei,CHEN Yuelong,JIANG Liting.The application of MATLAB in calculation of mineral contents in clastic sedimentary rocks[J].Acta Sedimentologica Sinica,2006(2):229-234. [28] 杜谷,王坤阳,冉敬,等.红外光谱/扫描电镜等现代大型仪器岩石矿物鉴定技术及其应用[J].岩矿测试,2014(5):625-633. DU Gu,WANG Kunyang,RAN Jing,et al.Application of IR/SEM and other modern instruments for mineral identification[J].Rock and Mineral Analysis,2014(5):625-633. [29] 袁明洋,黄必胜,余驰,等.8种含碳酸盐的矿物类中药近红外定性定量模型的建立[J].中国中药杂志,2014(2):267-272. YUAN Mingyang,HUANG Bisheng,YU Chi,et al.A NIR qualitative and quantitative model of 8 kinds of carbonate-containing mineral Chinese medicines[J].China Journal of Chinese Materia Medica,2014(2):267-272. [30] 范利群,张莉萍,夏光荣,等.傅立叶变换红外光谱仪(FTIR)在矿物含量分析中的应用[J].内蒙古石油化工,2010,36(7):26-28. FAN Liqun,ZHANG Liping,XIA Guangrong,et al.The applications of quantitative mineral analysis by FTIR[J].Inner Mongolia Petrochemical Industry,2010,36(7):26-28. [31] 陈龙,袁明洋,余驰,等.8种含碳酸盐的矿物类中药的近红外光谱特征谱段分析[J].药物分析杂志,2015(4):654-658. CHEN Long,YUAN Mingyang,YU Chi,et al.Analysis on NIR characteristic spectral bands of 8 kinds of carbonate mineral traditional Chinese medicines[J].Chinese Journal of Pharmaceutical Analysis,2015(4):654-658. [32] 张弘,高鹏鑫,高卿楠.热红外反射光谱技术在石英含量评价中的应用[J].岩矿测试,2021(5):710-719. ZHANG Hong,GAO Pengxin,GAO Qingnan.Application of thermal infrared reflectance spectroscopy in the evaluation of quartz content[J].Rock and Mineral Analysis,2021(5):710-719. [33] 郭帮杰,张杰林,武鼎.热红外高光谱遥感回归分析定量反演石英含量[J].科学技术与工程, 2018(17):125-130. GUO Bangjie,ZHANG Jielin,WU Ding.Thermal hyperspectral remote rensing for the quantitative inversion of quartz content by regression analysis[J].Science Technology and Engineering,2018(17):125-130. [34] 史维鑫,易锦俊,王浩,等.马坑铁矿钻孔岩心红外光谱特征及蚀变分带特征研究[J].岩矿测试,2020(6):934-943. SHI Weixin,YI Jinjun,WANG Hao,et al.Study on the characteristics of the infrared spectrum and the alteration zoning of drill core in the makeng iron deposit[J].Rock and Mineral Analysis,2020(6):934-943. [35] 温利刚,曾普胜,詹秀春,等.矿物表征自动定量分析系统(AMICS)技术在稀土稀有矿物鉴定中的应用[J].岩矿测试,2018,37(2):121-129. WEN Ligang,ZENG Pusheng,ZHAN Xiuchun,et al.Application of the automated mineral identification and characterization system(AMICS) in the identification of rare earth and rare minerals[J].Rock and Mineral Analysis,2018,37(2):121-129. [36] 贾木欣,周俊武,应平,等.工艺矿物学自动测试系统BPMA的研制及应用[J].有色冶金设计与研究,2017,38(4):1-12,16. JIA Muxin,ZHOU Junwu,YING Ping,et al.Development and application of bgrimm process mineralogy analyzing system(BPMA)[J].Nonferrous Metals Engineering & Research,2017,38(4):1-12,16. [37] 欧阳菲,潘法忠,杨柳.电子探针快速自动定量矿石中矿物的方法研究[J].岩矿测试,1991(4):267-270. OUYANG Fei,PAN Fazhong,YANG Liu.Rapid automatic quantification of minerals in rocks and ores by EPMA[J].Rock and Mineral Analysis,1991(4):267-270. [38] 张然,叶丽娟,党飞鹏,等.自动矿物分析技术在鄂尔多斯盆地砂岩型铀矿矿物鉴定和赋存状态研究中的应用[J].岩矿测试,2021,40(1):61-73. ZHANG Ran,YE Lijuan,DANG Feipeng,et al.Application of automatic mineral analysis technology to identify minerals and occurrences of elements in sandstone-type uranium deposits in the ordos basin[J].Rock and Mineral Analysis,2021,40(1):61-73. [39] 李波,梁冬云,张莉莉.石英细脉型复杂钨钼多金属矿石工艺矿物学研究[J].中国钨业,2013,28(5):28-31. LI Bo,LIANG Dongyun,ZHANG Lili.Process mineralogy of quartz veinlet-type complex tungsten-molybdenum polymetallic ore[J].China Tungsten Industry,2013,28(5):28-31. [40] 苏秀珠,黄志华,衷水平,等.卡林型金矿石中金的赋存状态分析新方法[J].岩矿测试,2013,32(3):474-482. SU Xiuzhu,HUANG Zhihua,ZHONG Shuiping,et al.New analysis method for gold occurrence in carlin-type gold ore[J].Rock and Mineral Analysis,2013,32(3):474-482. [41] 杨占峰,李强,王振江,等.白云鄂博矿床萤石型铁矿石中稀土分布规律研究[J].中国稀土学报,2017,35(4):520-527. YANG Zhanfeng,LI Qiang,WANG Zhenjiang,et al.Distribution regularity of rare earth in fluorite type iron ore in Bayan Obo[J].Journal of the Chinese Society of Rare Earths,2017,35(4):520-527. [42] 韩彬,童雄,张国浩,等.某铜炉渣的工艺矿物学研究[J].矿产保护与利用,2015(1):63-68. HAN Bin,TONG Xiong,ZHANG Guohao,et al.Process mineralogy study on a copper slag[J].Conservation and Utilization of Mineral Resources,2015(1):63-68. [43] YU D X,XU M H,ZHANG L,ET AL.Computer-controlled scanning electron microscopy (CCSEM) investigation on the heterogeneous nature of mineral matter in six typical chinese coals[J].Energy & Fuels,2007,21(2):468-476.
