Research Progress of Provenance Tracing Method for Heavy Mineral Analysis
Received date: 2020-12-04
Revised date: 2021-01-25
Online published: 2021-04-19
Supported by
the National Natural Science Foundation of China “Provenance identification of late cenozoic sediments in the Eastern Pamir Front: Constraints for the starting time of the Kongur Shan extensional system”(41902204);The Open Fund of Key Laboratory of Tectonic Controlled Mineralization and Oil Reservoir of Ministry of Natural Resources(gzck201904)
The traditional heavy mineral analysis is a fundamental and cheap provenance tracing method for clastic sediments. It provides comprehensive provenance information and irreplaceable background data for the single-mineral methods of provenance tracing. There are new progresses in basic theory and technology in recent years, but a systematic summary is still lacking. This paper summarizes the progress and development trend of heavy mineral analysis, which is shown in the following aspects:
Miaomiao XU , Xiaochun WEI , Rong YANG , Ping WANG , Xiaogan CHENG . Research Progress of Provenance Tracing Method for Heavy Mineral Analysis[J]. Advances in Earth Science, 2021 , 36(2) : 154 -171 . DOI: 10.11867/j.issn.1001-8166.2021.021
| 1 | WELTJE G J, EYNATTEN H VON. Quantitative provenance analysis of sediments: Review and outlook[J]. Sedimentary Geology, 2004, 171(1): 1-11. |
| 2 | LIU Baojun, ZENG Yongfu. Basis and working methods of lithofacies paleogeography[M]. Beijing:Beijing Publishing House,1985. |
| 2 | 刘宝珺, 曾永孚. 岩相古地理基础和工作方法[M]. 北京: 地质出版社, 1985. |
| 3 | ZHU Hongtao, XU Changgui, ZHU Xiaomin, et al. Advances of the source-to-sink units and coupling model research in continental basin[J]. Earth Science, 2017, 42 (11): 1 851-1 870. |
| 3 | 朱红涛, 徐长贵, 朱筱敏, 等. 陆相盆地源—汇系统要素耦合研究进展[J]. 地球科学, 2017, 42 (11): 1 851-1 870. |
| 4 | YANG Jianghai, MA Yan. Paleoclimate perspectives of source-to-sink sedimentary processes[J]. Earth Science,2017, 42(11): 1 910-1 921. |
| 4 | 杨江海, 马严. 源-汇沉积过程的深时古气候意义[J]. 地球科学, 2017, 42(11): 1 910-1 921. |
| 5 | LIN Changsong, XIA Qinglong, SHI Hesheng, et al. Geomorphological evolution,source to sink system and basin analysis[J]. Earth Science Frontiers, 2015, 22(1): 9-20. |
| 5 | 林畅松, 夏庆龙, 施和生, 等. 地貌演化、源—汇过程与盆地分析[J]. 地学前缘, 2015, 22(1): 9-20. |
| 6 | WANG Chengshan, LI Xianghui. Sedimentary basin:From principles to analyses[M]. Beijing:Higher Education Press, 2003. |
| 6 | 王成善, 李祥辉. 沉积盆地分析原理与方法[M]. 北京:高等教育出版社, 2003. |
| 7 | MA Shouxian, MENG Qingren, Qu Yongqiang. Development on provenance analysis of light minerals[J]. Acta Petrologica Sinica, 2014, 30(2): 597-608. |
| 7 | 马收先, 孟庆任, 曲永强. 轻矿物物源分析研究进展[J]. 岩石学报, 2014, 30(2): 597-608. |
| 8 | XU Jie, JIANG Zaixing. Provenance analysis of clastic rocks: Current research status and prospect: 03[J]. Journal of Palaeogeography, 2019, 21(3): 379-396. |
| 8 | 徐杰, 姜在兴. 碎屑岩物源研究进展与展望: 03[J]. 古地理学报, 2019, 21(3): 379-396. |
| 9 | YANG Renchao, LI Jinbu, FAN Aiping, et al. Research progress and development tendency of provenance analysis on terrigenous sedimentary rocks: 01[J]. Acta Sedimentologica Sinica, 2013, 31(1): 99-107. |
| 9 | 杨仁超, 李进步, 樊爱萍, 等. 陆源沉积岩物源分析研究进展与发展趋势: 01[J]. 沉积学报, 2013, 31(1): 99-107. |
| 10 | ZHAO Hongge, LIU Chiyang. Approaches and prospects of provenance analysis[J]. Acta Sedimentologica Sinica, 2003, 21(3): 409-415. |
| 10 | 赵红格, 刘池洋. 物源分析方法及研究进展[J]. 沉积学报, 2003, 21(3): 409-415. |
| 11 | EYNATTEN H VON, DUNKL I. Assessing the sediment factory: The role of single grain analysis[J]. Earth-Science Reviews, 2012, 115(1): 97-120. |
| 12 | MANGE M A, MAURER H. Heavy minerals in colour[M]. Netherlands: Springer Netherlands, 1992. |
| 13 | GARZANTI E, ANDò S. Heavy minerals for junior woodchucks[J]. Minerals, 2019, 9(3): 148. |
| 14 | MANGE M A, WRIGHT D T. Heavy minerals in use[M]. Amsterdam, Boston: Elsevier, 2007. |
| 15 | Institute of Geology and Mineral Resources, Chinese Academy of Geological Sciences. Manual of sand mineral identification[M]. Beijing: Geological Publishing House,1977. |
| 15 | 中国地质科学院地矿所. 砂矿物鉴定手册[M]. 北京: 地质出版社, 1977. |
| 16 | THüRACH H. über das verkommen mikrospokischer zirkone und titanmineralien in des gesteinen.[J]. Verhandlungen der Physikalisch-Medizinischen Gesellschaft zu Würzburg, 1884, 18: 203-284. |
| 17 | GEHRELS G. Detrital zircon U-Pb geochronology applied to tectonics[J]. Annual Review of Earth and Planetary Sciences, 2014, 42(1): 127-149. |
| 18 | ZHANG Ling, WANG Ping, CHEN Xiyun, et al. Review in detrital Zircon U-Pb geochronology:Data acquisition,analysis and comparison[J]. Advances in Earth Science, 2020, 35(4): 414-430. |
| 18 | 张凌, 王平, 陈玺赟, 等. 碎屑锆石U-Pb年代学数据获取、分析与比较[J]. 地球科学进展, 2020, 35(4): 414-430. |
| 19 | WANG Jiangang, HU Xiumian. Applications of geochemistry and geochronology of accessory minerals in sandstone to provenance analysis[J].Geological Review, 2008, 54(5):670-678. |
| 19 | 王建刚, 胡修棉. 砂岩副矿物的物源区分析新进展[J]. 地质论评, 2008, 54(5): 670-678. |
| 20 | JIAN Xing, GUAN Ping, ZHANG Wei. Detrital rutile: A sediment provenance indicator[J]. Advances in Earth Science, 2012, 27(8): 828-846. |
| 20 | 简星, 关平, 张巍. 碎屑金红石:沉积物源的一种指针[J]. 地球科学进展, 2012, 27(8): 828-846. |
| 21 | GUO Pei, LIU Chiyang, WANG Jianqiang, et al. Considerations on the application of detrital-zircon geochronology to sedimentary provenance analysis[J]. Acta Sedimentologica Sinica , 2017, 35(1): 46-56. |
| 21 | 郭佩, 刘池洋, 王建强, 等. 碎屑锆石年代学在沉积物源研究中的应用及存在问题[J]. 沉积学报, 2017, 35(1): 46-56. |
| 22 | MOECHER D P, SAMSON S D. Differential zircon fertility of source terranes and natural bias in the detrital zircon record: Implications for sedimentary provenance analysis[J]. Earth and Planetary Science Letters, 2006, 247(3): 252-266. |
| 23 | DICKINSON W R. Impact of differential zircon fertility of granitoid basement rocks in North America on age populations of detrital zircons and implications for granite petrogenesis[J]. Earth and Planetary Science Letters, 2008, 275(1): 80-92. |
| 24 | GARZANTI E. From static to dynamic provenance analysis—Sedimentary petrology upgraded[J]. Sedimentary Geology, 2016, 336: 3-13. |
| 25 | MORTON A C, HALLSWORTH C. Identifying provenance-specific features of detrital heavy mineral assemblages in sandstones[J]. Sedimentary Geology, 1994, 90(3): 241-256. |
| 26 | SCHULZ B, SANDMANN D, GILBRICHT S. SEM—Based automated mineralogy and its application in geo- and material sciences: 11[J]. Minerals, 2020, 10(11): 1 004. |
| 27 | MORTON A C. Value of heavy minerals in sediments and sedimentary rocks for provenance, transport history and stratigraphic correlation[J]. Mineralogical Association of Canada Short Course Series, 2012, 42: 133-165. |
| 28 | HE Zhonghua, LIU Zhaojun, ZHANG Feng. Latest progress of heavy mineral research in the basin analysis [J]. Bulletin of Geological Science and Technology, 2001, 20(4): 29-32. |
| 28 | 和钟铧, 刘招君, 张峰. 重矿物在盆地分析中的应用研究进展 [J]. 地质科技情报, 2001, 20(4): 29-32. |
| 29 | YUE Yan. Introduction of the provenance analysis of heavy mineral:12[J]. Journal of Library and Information Science, 2010, 20(12): 138-139,146. |
| 29 | 岳艳. 浅谈重矿物物源分析方法: 12[J]. 科技情报开发与经济, 2010, 20(12): 138-139,146. |
| 30 | DUNKL I, EYNATTEN H VON, Andò S, et al. Comparability of heavy mineral data-the first interlaboratory round robin test[J]. Earth-Science Reviews, 2020, 211: 103210. |
| 31 | MORTON A C, HALLSWORTH C R. Processes controlling the composition of heavy mineral assemblages in sandstones[J]. Sedimentary Geology, 1999, 124(1): 3-29. |
| 32 | BURLEY S D, KANTOROWICZ J D, WAUGH B. Clastic diagenesis[J]. Geological Society, London, Special Publications, 1985, 18(1): 189-226. |
| 33 | JOHNSSON M J, STALLARD R F, LUNDBERG N. Controls on the composition of fluvial sands from a tropical weathering environment: Sands of the Orinoco River drainage basin, Venezuela and Colombia[J]. GSA Bulletin, 1991, 103(12): 1 622-1 647. |
| 34 | MILLIKEN K L. Chapter 8 provenance and diagenesis of heavy minerals, cenozoic units of the Northwestern Gulf of Mexico sedimentary basin[M]// Mange M A, Wright D T. Developments in Sedimentology. Elsevier, 2007: 247-261. |
| 35 | RAHMANI R A. Grain surface etching features of some heavy minerals[J]. Journal of Sedimentary Research, 1973, 43(3): 882-888. |
| 36 | TURNER G, MORTON A C. Chapter 14 the effects of burial diagenesis on detrital heavy mineral grain surface textures[M]//MANGE M A, WRIGHT D T. Developments in sedimentology. Elsevier, 2007: 393-412. |
| 37 | KOMAR P D, LI Z. Applications of grain-pivoting and sliding analyses to selective entrapment of gravel and to flow-competence evaluations[J]. Sedimentology, 1988, 35(4): 681-695. |
| 38 | CHENG Niansheng. Simplified settling velocity formula for sediment particle[J]. Journal of Hydraulic Engineering, 1997, 123(2): 149-152. |
| 39 | RUBEY W W. The size distribution of heavy minerals within a water-laid sandstone[J]. Journal of Sedimentary Research, 1933, 3(1): 3-29. |
| 40 | HAND B M. Differentiation of beach and dune sands, using settling velocities of light and heavy minerals[J]. Journal of Sedimentary Research, 1967, 37(2): 514-520. |
| 41 | KOMAR P D, WANG C. Processes of selective grain transport and the formation of placers on beaches[J]. The Journal of Geology, 1984, 92(6): 637-655. |
| 42 | SLINGERLAND R L. The effects of entrainment on the hydraulic equivalence relationships of light and heavy minerals in sands[J]. Journal of Sedimentary Research, 1977, 47(2): 753-770. |
| 43 | REID L, FROSTICK L E. Beach orientation, bar morphology and the concentration of metalliferous placer deposits: A case study, Lake Turkana, N Kenya[J]. Journal of the Geological Society, 1985, 142(5): 837-848. |
| 44 | GARZANTI E, ANDò S, VEZZOLI G. Settling equivalence of detrital minerals and grain-size dependence of sediment composition[J]. Earth and Planetary Science Letters, 2008, 273(1): 138-151. |
| 45 | FLORES R M, SHIDELER G L. Factors controlling heavy-mineral variations on the south texas outer continental shelf, Gulf of Mexico[J]. Journal of Sedimentary Research, 1978, 48(1): 269-280. |
| 46 | DOYLE L J, CARDER K L, STEWARD R G. The hydraulic equivalence of mica[J]. Journal of Sedimentary Research, 1983, 53(2): 643-648. |
| 47 | GARZANTI E, ANDò S, VEZZOLI G, et al. Petrology of the Namib Sand Sea: Long-distance transport and compositional variability in the wind-displaced orange delta[J]. Earth-Science Reviews, 2012, 112(3): 173-189. |
| 48 | Morton A, Mundy D, Bingham G. High-frequency fluctuations in heavy mineral assemblages from Upper Jurassic sandstones of the Piper Formation, UK North Sea: Relationships with sea-level change and floodplain residence[J]. Journal of African Economies, 2012, 23(1):175-190. |
| 49 | MIAO Xiaolong, DU Yan. Discussion with Hu:Significant influence of mixing action to clastic particles during the process of flowing transportation and sedimentation[J]. Journal of Palaeogeography, 2017, 19(4): 648-652. |
| 49 | 苗小龙, 杜燕. 与胡修棉的讨论:水流搬运与沉积过程中掺和作用对碎屑颗粒的重要影响[J]. 古地理学报, 2017, 19(4): 648-652. |
| 50 | HU Xiumian. A misunderstanding in provenance analysis:Sand changes of mineral,roundness,and size in flowing-wate transportation[J]. Journal of Palaeogeography , 2017, 19(1): 175-184. |
| 50 | 胡修棉. 物源分析的一个误区:砂粒在河流搬运过程中的变化[J]. 古地理学报, 2017, 19 (1): 175-184. |
| 51 | GARZANTI E, RESENTINI A, ANDò S, et al. Physical controls on sand composition and relative durability of detrital minerals during ultra‐long distance littoral and aeolian transport (Namibia and southern Angola)[J]. Sedimentology, 2015, 62(4): 971-996. |
| 52 | RUSSELL R D. Mineral composition of Mississippi River sands[J]. GSA Bulletin, 1937, 48(9): 1 307-1 348. |
| 53 | MORTON A, HALLSWORTH C, KUNKA J, et al.Heavy-mineral stratigraphy of the clair group (Devonian-Carboniferous) in the clair field, West of Shetland, U.K.[M]//RATCLIFFE K T, ZAITLIN B A. Application of modern stratigraphic techniques: Theory and case histories. SEPM Society for Sedimentary Geology, 2010. |
| 54 | BLATT H, SUTHERLAND B. Intrastratal solution and non-opaque heavy minerals in shales[J]. Journal of Sedimentary Research, 1969, 39(2): 591-600. |
| 55 | MORTON A C, HALLSWORTH C. Chapter 7 stability of detrital heavy minerals during burial diagenesis[M]//MANGE M A, WRIGHT D T. Developments in sedimentology. Elsevier, 2007: 215-245. |
| 56 | YURKOVA R M. Comparison of post-sedimentary alterations of oil-, gas- and water-bearing rocks[J]. Sedimentology, 1970, 15(1/2): 53-68. |
| 57 | MILLIKEN K L, MACK L E. Subsurface dissolution of heavy minerals, frio formation sandstones of the Ancestral Rio Grande Province, South Texas[J]. Sedimentary Geology, 1990, 68(3): 187-199. |
| 58 | MORTON A C. Stability of detrital heavy minerals in tertiary sandstones from the North Sea Basin[J]. Clay Minerals, 1984, 19(3): 287-308. |
| 59 | MORTON A C. Dissolution of Apatite in North Sea Jurassic Sandstones: Implications for the generation of secondary porosity[J]. Clay Minerals, 1986, 21(4): 711-733. |
| 60 | SMALE D, MORTON A C. Heavy mineral suites of core samples from the McKee Formation (Eocene—Lower Oligocene), Taranaki: Implications for provenance and diagenesis[J]. New Zealand Journal of Geology and Geophysics, 1987, 30(3): 299-306. |
| 61 | TSUTSUMI Y, C-S LEE, SHEN J J, et al. Stability and dissolution of heavy minerals in the neogene-pleistocene sandstones from Western Foothills, Taiwan(natural history researches of the island arcs in the Western Pacific I. Taiwan and the Philippines)[J]. Memoirs of the National Science Museum, 2006, 44: 195-204. |
| 62 | MORTON A C. Heavy minerals in provenance studies[M]// Zuffa G G. Provenance of Arenites. Dordrecht: Springer Netherlands, 1985: 249-277. |
| 63 | CARVER R E. Heavy-mineral separation[M]//Procedures in sedimentary petrology. New York: Wiley-Interscience, 1931: 653. |
| 64 | BATEMAN R M, CATT J A. Chapter 5 Provenance and Palaeoenvironmental Interpretation of Superficial Deposits, with Particular Reference to Post-Depositional Modification of Heavy Mineral Assemblages[M]// MANGE M A, WRIGHT D T. Developments in sedimentology. Elsevier, 2007: 151-188. |
| 65 | TJEERD H A. Recent marine sediments of Gulf of California [C]. American Association of Petroleum Geologists, 1964. |
| 66 | GALEHOUSE J S. Provenance and Paleocurrents of the Paso Robles Formation, California[J]. GSA Bulletin, 1967, 78(8): 951-978. |
| 67 | RICE R M, GORSLINE D S, OSBORNE R H. Relationships between sand input from rivers and the composition of sands from the beaches of Southern California[J]. Sedimentology, 1976, 23(5): 689-703. |
| 68 | GARZANTI E, ANDò S, VEZZOLI G. Grain-size dependence of sediment composition and environmental bias in provenance studies[J]. Earth and Planetary Science Letters, 2009, 277(3): 422-432. |
| 69 | SCHNITZER W A. Zur problematik der schwermineralanalyse am beispiel triassischer sedimentgesteine[J]. Geologische Rundschau, 1983, 72(1): 67-75. |
| 70 | HE Shaowu. Mineral identification manual[M]. Changchun: Changchun College of Geology, 1980. |
| 70 | 何绍武. 矿物鉴定手册[M]. 长春: 长春地质学院, 1980. |
| 71 | GLAGOLEV A A. On geometrical methods of quantitative mineralogical analysis of rocks[M]. Moscow: Transactions of the Institute Economic Mineralogy, 1933. |
| 72 | CHAYES F. The theory of thin-section analysis[J]. The Journal of Geology, 1954, 62(1): 92-101. |
| 73 | GARZANTI E, ANDò S. Chapter 20 heavy mineral concentration in modern sands: Implications for provenance interpretation[M]//MANGE M A, WRIGHT D T. Heavy minerals in use. Radarweg: Elsevier, 2007: 517-545. |
| 74 | LI Linlin, GUO Zhaojie, GUAN Shuwei, et al. Heavy mineral assemblage characteristics and the Cenozoic paleogeographic evolution in southwestern Qaidam Basin[J]. Science China: Earth Sciences, 2015, 45(6): 780-798,1-6. |
| 74 | 李林林, 郭召杰, 管树巍, 等. 柴达木盆地西南缘新生代碎屑重矿物组合特征及其古地理演化[J]. 中国科学:地球科学, 2015, 45(6): 780-798,1-6. |
| 75 | SUN Xiaoxia, LI Yong, QIU Dongzhou, et al. The heavy minerals and provenances of the Neogene Guantao Formation in the Huanghua depression:03[J]. Sedimentary Geology and Tethyan Geology, 2006, 26(3): 61-66. |
| 75 | 孙小霞, 李勇, 丘东洲, 等. 黄骅坳陷新近系馆陶组重矿物特征及物源区意义: 03[J]. 沉积与特提斯地质, 2006, 26(3): 61-66. |
| 76 | DERKACHEV A N, NIKOLAEVA N A. Chapter 17 multivariate analysis of heavy mineral assemblages of sediments from the marginal seas of the Western Pacific[M]// Mange M A, Wright D T. Developments in Sedimentology. Elsevier, 2007: 439-464. |
| 77 | IMBRIE J, ANDEL T H VAN. Vector analysis of heavy-mineral data[J]. GSA Bulletin, 1964, 75 (11): 1 131-1 156. |
| 78 | WANG Kunshan, SHI Xuefa, LIN Zhenhong. Assemblages, provinces and provenances of heavy minerals on the Shelf of the Southern Yellow Sea and Northern East China Sea: 01[J]. Advances in Marine Science, 2003, 21(1): 31-40. |
| 78 | 王昆山, 石学法, 林振宏. 南黄海和东海北部陆架重矿物组合分区及来源: 01[J]. 海洋科学进展, 2003, 21(1): 31-40. |
| 79 | WU Fadong, LU Yongchao, RUAN Xiaoyan, et al. Application of heavy minerals cluster analysis to study of clastic sources and stratigraphic correlation [J].Geoscience, 1996,10(3): 106-112. |
| 79 | 武法东, 陆永潮, 阮小燕,等. 重矿物聚类分析在物源分析及地层对比中的应用——以东海陆架盆地西湖凹陷平湖地区为例 [J]. 现代地质, 1996, 10(3): 106-112. |
| 80 | PIRKLE F L, PIRKLE E C, PIRKLE W A, et al. Evaluation through correlation and principal component analyses of a delta origin for the Hawthorne and Citronelle Sediments of Peninsular Florida[J]. The Journal of Geology, 1985, 93(4): 493-501. |
| 81 | VERMEESCH P, RESENTINI A, GARZANTI E. An R package for statistical provenance analysis[J]. Sedimentary Geology, 2016, 336 (): 14-25. |
| 82 | HUBERT J F. A Zircon-Tourmaline-Rutile maturity index and the interdependence of the composition of heavy mineral assemblages with the gross composition and texture of sandstones[J]. Journal of Sedimentary Research, 1962, 32(3): 440-450. |
| 83 | GARZANTI E, VEZZOLI G, LOMBARDO B, et al. Collision‐Orogen Provenance (Western Alps): Detrital signatures and unroofing trends[J]. The Journal of Geology, 2004, 112(2): 145-164. |
| 84 | GARZANTI E, ANDò S, VEZZOLI G. The continental crust as a source of sand (Southern Alps Cross Section, Northern Italy)[J]. The Journal of Geology, 2006, 114(5): 533-554. |
| 85 | GARZANTI E, DOGLIONI C, VEZZOLI G, et al. Orogenic belts and orogenic sediment provenance[J]. The Journal of Geology, 2007, 115(3): 315-334. |
| 86 | MORTON A, MCGILL P. Correlation of hydrocarbon reservoir sandstones using heavy mineral provenance signatures: Examples from the North Sea and adjacent areas: 12[J]. Minerals, 2018, 8(12): 564. |
| 87 | LEWIN A, MEINHOLD G, HINDERER M, et al. Heavy minerals as provenance indicator in glaciogenic successions: An example from the palaeozoic of ethiopia[J]. Journal of African Earth Sciences, 2020, 165: 103813. |
| 88 | BUSH M A, SAYLOR J E, HORTON B K, et al. Growth of the Qaidam Basin during Cenozoic exhumation in the northern Tibetan Plateau: Inferences from depositional patterns and multiproxy detrital provenance signatures[J]. Lithosphere, 2016, 8(1): 58-82. |
| 89 | MORTON A C, WHITHAM A G, FANNING C M. Provenance of late cretaceous to paleocene submarine fan sandstones in the norwegian sea: Integration of heavy mineral, mineral chemical and Zircon Age Data[J]. Sedimentary Geology, 2005, 182(1): 3-28. |
| 90 | NAUTON‐FOURTEU M, TYRRELL S, MORTON A. Heavy mineral variations in mid-carboniferous deltaic sandstones: Records of a pre-depositional sediment history?[J]. The Depositional Record, 2021, 7(1): 52-63. |
| 91 | HANSLEY P L. Petrologic and experimental evidence for the etching of garnets by organic acids in the Upper Jurassic Morrison Formation, Northwestern New Mexico[J]. Journal of Sedimentary Research, 1987, 57(4): 666-681. |
| 92 | MORTON A C. Influences of provenance and diagenesis on detrital garnet suites in the paleocene forties sandstone, Central North Sea[J]. Journal of Sedimentary Research, 1987, 57(6): 1 027-1 032. |
| 93 | RITTENHOUSE G. Transportation and deposition of heavy mineral[J]. GSA Bulletin, 1943, 54(12): 1 725-1 780. |
| 94 | HATTUM M W A VAN, HALL R, PICKARD A L, et al. Southeast Asian sediments not from Asia: Provenance and geochronology of North Borneo Sandstones[J]. Geology, 2006, 34(7): 589-592. |
| 95 | GARZANTI E, ANDò S. Chapter 20 heavy mineral concentration in modern sands: Implications for provenance interpretation[M]// MANGE M A, WRIGHT D T. Heavy minerals in use. Amsterdam; Boston: Elsevier, 2007: 517-545. |
| 96 | GARZANTI E, VEZZOLI G, ANDò S, et al. Petrology of Rifted‐Margin Sand (Red Sea and Gulf of Aden, Yemen): 3[J]. The Journal of Geology, 2001, 109(3): 277-297. |
| 97 | GARZANTI E, ANDò S, VEZZOLI G, et al. From rifted margins to foreland basins: Investigating provenance and sediment dispersal across Desert Arabia (Oman, U.A.E.): 4[J]. Journal of Sedimentary Research, 2003, 73 (4): 572-588. |
| 98 | GARZANTI E, VEZZOLI G, ANDò S, et al. Sand petrology and focused Erosion in collision orogens: The Brahmaputra Case: 1[J]. Earth and Planetary Science Letters, 2004, 220(1): 157-174. |
| 99 | GARZANTI E, VEZZOLI G. A classification of metamorphic grains in sands based on their composition and grade[J]. Journal of Sedimentary Research, 2003, 73(5): 830-837. |
| 100 | GARZANTI E, ANDò S. Chapter 29 plate tectonics and heavy mineral suites of modern sands[M]// MANGE M A, WRIGHT D T. Developments in Sedimentology. Elsevier, 2007: 741-763. |
| 101 | WELTJE G J. End-member modeling of compositional data: Numerical-statistical algorithms for solving the explicit mixing problem: 4[J]. Mathematical Geology, 1997, 29(4): 503-549. |
| 102 | GARZANTI E, VEZZOLI G, ANDò S, et al. Petrology of Indus River sands: A key to interpret erosion history of the Western Himalayan Syntaxis[J]. Earth and Planetary Science Letters, 2005, 229(3): 287-302. |
| 103 | GARZANTI E, ANDò S, VEZZOLI G, et al. Petrology of Nile River Sands (Ethiopia and Sudan): Sediment budgets and erosion patterns: 3[J]. Earth and Planetary Science Letters, 2006, 252(3): 327-341. |
| 104 | VEZZOLI G, GARZANTI E, MONGUZZI S. Erosion in the Western Alps (Dora Baltea Basin): 1. Quantifying sediment provenance: 1[J]. Sedimentary Geology, 2004, 171(1): 227-246. |
| 105 | LIU Teng, CHEN Gang, XU Xiaogang, et al. Methods and development trend of provenance analysis[J]. Northwestern Geology, 2016, 49(4): 121-128. |
| 105 | 刘腾, 陈刚, 徐小刚, 等. 物源分析方法及其发展趋势[J]. 西北地质, 2016, 49(4): 121-128. |
| 106 | ALIGHOLI S, LASHKARIPOUR G R, KHAJAVI R, et al. Automatic mineral identification using color tracking[J]. Pattern Recognition, 2017, 65: 164-174. |
| 107 | ROSS B J, FUETEN F, YASHKIr D Y. Automatic mineral identification using genetic programming[J]. Machine Vision and Applications, 2001, 13(2): 61-69. |
| 108 | THOMPSON S, FUETEN F, BOCKUS D. Mineral identification using artificial neural networks and the rotating polarizer stage[J]. Computers & Geosciences, 2001, 27(9): 1 081-1 089. |
| 109 | ANDò S, GARZANTI E. Raman spectroscopy in heavy-mineral studies[J]. Geological Society, London, Special Publications, 2014, 386(1): 395-412. |
| 110 | ISHIKAWA S T, GULICK V C. An automated mineral classifier using raman spectra[J]. Computers & Geosciences, 2013, 54: 259-268. |
| 111 | HADDAD J EL, DE LIMA FILHO E S, VANIER F, et al. Multiphase mineral identification and quantification by laser-induced breakdown spectroscopy[J]. Minerals Engineering, 2019, 134: 281-290. |
| 112 | RIFAI K, MICHAUD PARADIS M-C, SWIERCZEK Z, et al. Emergences of new technology for ultrafast automated mineral phase identification and quantitative analysis using the CORIOSITY Laser-Induced Breakdown Spectroscopy (LIBS) system: 10[J]. Minerals, 2020, 10(10): 918. |
| 113 | FREI D, KNUDSEN C, MCLIMANS R K, et al. Fully automated analysis of chemical and physical properties of individual mineral species in heavy mineral sands by computer controlled scanning electron microscopy (CCSEM)[C]//2005 Heavy Minerals Conference, HMC2005, October16, 2005 - October 19, 2005. Jacksonville, FL, United states: Society for Mining, Metallurgy and Exploration, 2005: 103-108. |
| 114 | GRAHAM S, BROUGH C, CROPP A. An introduction to ZEISS mineralogic mining and the correlation of light microscopy with automated mineralogy: A case study using BMS and PGM analysis of samples from a PGE-bearing chromitite prospect[C]. Precious Metals, 2015. |
| 115 | GU Y. Automated scanning electron microscope based mineral liberation analysis an introduction to JKMRC/FEI mineral liberation analyser: 1[J]. Journal of Minerals and Materials Characterization and Engineering, 2003, 2 (1): 33-41. |
| 116 | HRSTKA T, GOTTLIEB P, SKALA R, et al. Automated mineralogy and petrology-applications of TESCAN Integrated Mineral Analyzer (TIMA)[J]. Journal of Geosciences, 2018, 63(1): 47-63. |
| 117 | PIRRIE D, BUTCHER A R, POWER M R, et al. Rapid quantitative mineral and phase analysis using automated scanning electron microscopy (QemSCAN): Potential applications in forensic geoscience[J]. Geological Society, London, Special Publications, 2004, 232(1): 123-136. |
| 118 | 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. |
| 118 | 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. |
| 119 | SANDMANN D. Method development in automated mineralogy[D]. Freiberg: verleihende / prüfende Institution TU Bergakademie Freiberg, 2015. |
| 120 | KENIS P, SKURZY?SKI J, JARY Z, et al. A new methodological approach (QEMSCAN?) in the mineralogical study of Polish Loess: Guidelines for further research[J]. Open Geosciences, 2020, 12(1): 342-353. |
| 121 | NIE Junsheng, PENG Wenbin. Automated SEM-EDS heavy mineral analysis reveals No Provenance Shift between glacial loess and interglacial paleosol on the Chinese Loess Plateau[J]. Aeolian Research, 2014, 13: 71-75. |
| 122 | GUO Ronghua, HU Xiumian, GARZANTI E, et al. How faithfully do the geochronological and geochemical signatures of Detrital Zircon, Titanite, Rutile and Monazite record magmatic and metamorphic events?A case study from the Himalaya and Tibet[J]. Earth-Science Reviews, 2020, 201: 103082. |
| 123 | JIAN Xing, GUAN Ping, ZHANG Daowei, et al. Provenance of tertiary sandstone in the Northern Qaidam Basin, Northeastern Tibetan Plateau: Integration of framework petrography, heavy mineral analysis and mineral chemistry[J]. Sedimentary Geology, 2013, 290: 109-125. |
| 124 | ZHENG Dewen, WANG Fei, ZHANG Peizhen, et al. Apatite U-Th/He dating method—A low temperature thermochronometer[J]. Seismology and Geology, 2000, 22(4): 427-435. |
| 124 | 郑德文, 王非, 张培震, 等. 磷灰石U-Th/He法—— 一种低温热年代计[J]. 地震地质, 2000, 22(4): 427-435. |
| 125 | CAO Kai, WANG Guocan, BERNET M, et al. Exhumation history of the West Kunlun Mountains, northwestern Tibet: Evidence for a long-lived, rejuvenated orogen[J]. Earth and Planetary Science Letters, 2015, 432: 391-403. |
| 126 | DENG Bin, ZENG Lu, ZHOU Qing, et al. A review of detrital apatite single-grain LA-ICPMS multi-dating[J]. Bulletin of Geological Science and Technology, 2017, 36(1): 77-86. |
| 126 | 邓宾, 曾璐, 周庆, 等. 碎屑岩磷灰石单矿物多法定年进展与应用[J]. 地质科技情报, 2017, 36(1): 77-86. |
| 127 | SUN Xilin, LI Changjiang, KUIPER K F, et al. Geochronology of detrital muscovite and zircon constrains the sediment provenance changes in the Yangtze River during the late Cenozoic[J]. Basin Research, 2018, 30: 636-649. |
| 128 | CLIFT P D, HODGES K V, HESLOP D, et al. Correlation of Himalayan Exhumation Rates and Asian Monsoon Intensity[J]. Nature Geoscience, 2008, 1(12): 875-880. |
| 129 | NIE Junsheng, STEVENS T, RITTNER M. Loess Plateau storage of Northeastern Tibetan Plateau-Derived Yellow River Sediment: 1[J]. Nature Communications, 2015, 6(1): 8 511. |
| 130 | RITTNER M, VERMEESCH P, CARTER A, et al. The provenance of Taklamakan desert sand[J]. Earth and Planetary Science Letters, 2016, 437: 127-137. |
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