Advances on Exploration Indicators of Mineral VNIR-SWIR Spectroscopy and Chemistry: A Review

Establishing exploration vectors to infer the properties of ore-forming fluids, locate blind ore bodies with the aid of visible to near-infrared (VNIR) and short-wave infrared (SWIR) spectroscopy, and infer the chemistry of minerals, is a new research interest for economic geology. Common alterations and clay minerals, including sericite, chlorite, epidote, alunite, kaolinite, tourmaline, etc., are ideal objects for the study of exploration indicators due to their sensitivity to variations in the nature of hydrothermal fluid. The diagnostic spectral feature and chemistry vary spatially and systematically with physicochemical change. VNIR spectroscopy can characterize the REE-bearing clay minerals directly. Obtaining spectral or chemical parameters with the aid of VNIR-SWIR spectroscopy, electron probe micro-analyzer (EPMA) or laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) can help to establish exploration vectors. This paper systematically summarizes recent advances in mineral exploration indicators (MEIs) of VNIR-SWIR spectroscopy and chemistry, and compares them in different regions or deposits. We found that some MEI spatial variation trends are random, even the same type of deposit can show an opposite trend. The controlling factors that limit the application of the established MEIs are vague. Conducting further research on petrology and mineralogy with the aids of observation under microscopy, X-ray diffraction (XRD), TESCAN Integrated Mineral Analyzer (TIMA), and EPMA are suggested to discover alteration mineral assemblage, alteration stages, and behaviors of “the pathfinder elements” related to mineralization. Based on the above research, the physicochemical properties of ore-forming fluids and their control over MEIs can be inferred. Refining the theoretical basis is critical to understanding and popularization of spectral and chemical MEIs.

[1]  Yuzhou Feng,et al.  Short-wave infrared (SWIR) spectral and geochemical characteristics of hydrothermal alteration minerals in the Laowangou Au deposit: Implications for ore genesis and vectoring , 2021, Ore Geology Reviews.

[2]  Chaoqun Zhang,et al.  Visible/near infrared reflectance (VNIR) spectral features of ion-exchangeable Rare earth elements hosted by clay minerals: Potential use for exploration of regolith-hosted REE deposits , 2021, Applied Clay Science.

[3]  T. Cudahy,et al.  FEASIBILITY OF VISIBLE SHORT-WAVE INFRARED REFLECTANCE SPECTROSCOPY TO CHARACTERIZE REGOLITH-HOSTED RARE EARTH ELEMENT MINERALIZATION , 2021, Economic Geology.

[4]  Fang-Jun Zhang,et al.  Tourmaline as a potential mineral for exploring porphyry deposits: a case study of the Bilihe gold deposit in Inner Mongolia, China , 2021, Mineralium Deposita.

[5]  W. Xiao,et al.  Hydrothermal alteration characteristics of the Chating Cu-Au deposit in Xuancheng City, Anhui Province, China: Significance of sericite alteration for Cu-Au exploration , 2020 .

[6]  Jing Tian,et al.  Chlorite as an exploration indicator for concealed skarn mineralization: Perspective from the Tonglushan Cu–Au–Fe skarn deposit, Eastern China , 2020 .

[7]  Cooke,et al.  Epidote Trace Element Chemistry as an Exploration Tool in the Collahuasi District, Northern Chile , 2020, Economic Geology.

[8]  G. Dipple,et al.  Chemical Variations in Hydrothermal White Mica Across the Highland Valley Porphyry Cu-Mo District, British Columbia, Canada , 2020, Economic Geology.

[9]  Cooke,et al.  Using Mineral Chemistry to Aid Exploration: A Case Study from the Resolution Porphyry Cu-Mo Deposit, Arizona , 2020 .

[10]  Huayong Chen,et al.  Elemental behavior during chlorite alteration: New insights from a combined EMPA and LA-ICPMS study in porphyry Cu systems , 2020, Chemical Geology.

[11]  Cooke,et al.  A Microscale Analysis of Hydrothermal Epidote: Implications for the Use of Laser Ablation-Inductively Coupled Plasma-Mass Spectrometry Mineral Chemistry in Complex Alteration Environments , 2020 .

[12]  Cooke,et al.  Chlorite and Epidote Mineral Chemistry in Porphyry Ore Systems: A Case Study of the Northparkes District, New South Wales, Australia , 2020, Economic Geology.

[13]  Cooke,et al.  Exploration Targeting in Porphyry Cu Systems Using Propylitic Mineral Chemistry: A Case Study of the El Teniente Deposit, Chile , 2020, Economic Geology.

[14]  Jennifer A. Thompson,et al.  Recent advances in the application of mineral chemistry to exploration for porphyry copper–gold–molybdenum deposits: detecting the geochemical fingerprints and footprints of hypogene mineralization and alteration , 2020, Geochemistry: Exploration, Environment, Analysis.

[15]  张宇,et al.  鄂东南矿集区典型矽卡岩-斑岩矿床蚀变矿物短波红外(SWIR)光谱研究与勘查应用 , 2019 .

[16]  Juxing Tang,et al.  Mineral chemistry of magmatic and hydrothermal biotites from the Bangpu porphyry Mo (Cu) deposit, Tibet , 2019 .

[17]  Chao Wu,et al.  Alteration mapping with short wavelength infrared (SWIR) spectroscopy on Xiaokelehe porphyry Cu-Mo deposit in the Great Xing’an Range, NE China: Metallogenic and exploration implications , 2019, Ore Geology Reviews.

[18]  N. White,et al.  Chemical and boron isotope compositions of tourmaline in the Hadamiao porphyry gold deposit, Inner Mongolia, China , 2019, Chemical Geology.

[19]  A. Boyce,et al.  A new paradigm for the origin of propylitic alteration in porphyry ore systems , 2019, Applied Earth Science.

[20]  P. Hollings,et al.  Hydrothermal alteration and short wavelength infrared (SWIR) characteristics of the Tongshankou porphyry-skarn Cu-Mo deposit, Yangtze craton, Eastern China , 2018, Ore Geology Reviews.

[21]  P. Afzal,et al.  Alteration Mapping for Porphyry Copper Exploration Using ASTER and QuickBird Multispectral Images, Sonajeel Prospect, NW Iran , 2018, Journal of the Indian Society of Remote Sensing.

[22]  D. Lentz,et al.  Comparative study of mineral chemistry of four biotite types as geochemical indicators of mineralized and barren intrusions in the Sungun Porphyry Cu-Mo deposit, northwestern Iran , 2018, Ore Geology Reviews.

[23]  Benoit Rivard,et al.  Visible and short-wave infrared reflectance spectroscopy of selected REE-bearing silicate minerals , 2018, American Mineralogist.

[24]  Toshihiko Hayashi,et al.  Potential for Porphyry Copper Mineralization Below the Kasuga Lithocap, Nansatsu District, Japan , 2018 .

[25]  Huang Zhicai,et al.  Extraction of Alteration Information and Establishment of Prospecting Model for Porphyry Copper\|gold Deposits in Luzon , 2018 .

[26]  Lejun Zhang,et al.  Lithological and Hydrothermal Alteration Mapping of Epithermal, Porphyry and Tourmaline Breccia Districts in the Argentine Andes Using ASTER Imagery , 2018, Remote. Sens..

[27]  Jinsheng Han,et al.  Alteration zonation and short wavelength infrared (SWIR) characteristics of the Honghai VMS Cu-Zn deposit, Eastern Tianshan, NW China , 2017, Ore Geology Reviews.

[28]  Chaohao Xu,et al.  Chlorite and epidote chemistry of the Yandong Cu deposit, NW China: Metallogenic and exploration implications for Paleozoic porphyry Cu systems in the Eastern Tianshan , 2017, Ore Geology Reviews.

[29]  Thomas Cudahy,et al.  White mica as a hyperspectral tool in exploration for the sunrise dam and Kanowna belle gold deposits, Western Australia , 2017 .

[30]  Cooke,et al.  Lithocaps – characteristics, origins and significance for porphyry and epithermal exploration , 2017 .

[31]  N. White,et al.  Alteration and mineralization of Xinan Cu-Mo ore deposit in Zijinshan orefield, Fujian Province, and application of short wavelength infra-red technology (SWIR) to exploration , 2017 .

[32]  Benoit Rivard,et al.  Visible and short-wave infrared reflectance spectroscopy of REE phosphate minerals , 2016 .

[33]  H. White,et al.  Short-Wave Infrared Spectral and Geochemical Characteristics of Hydrothermal Alteration at the Archean Izok Lake Zn-Cu-Pb-Ag Volcanogenic Massive Sulfide Deposit, Nunavut, Canada: Application in Exploration Target Vectoring , 2016 .

[34]  Bin Huang,et al.  [Research on Assessment Methods of Spectrum Data Quality of Core Scan]. , 2015, Guang pu xue yu guang pu fen xi = Guang pu.

[35]  J. Gemmell,et al.  The chlorite proximitor: A new tool for detecting porphyry ore deposits , 2015 .

[36]  Chengjiang Zhang,et al.  Discussion on Changdagou Porphyry Copper Deposits Mineralization Model in Dege, Sichuan Province , 2014 .

[37]  R. Sillitoe Geological Criteria for Porphyry Copper Exploration , 2014 .

[38]  Mahdieh Hosseinjani Zadeh,et al.  Spectral characteristics of minerals in alteration zones associated with porphyry copper deposits in the middle part of Kerman copper belt, SE Iran , 2014 .

[39]  Benoit Rivard,et al.  Visible and short-wave infrared reflectance spectroscopy of REE fluorocarbonates , 2014 .

[40]  D. Cooke,et al.  Geochemistry of Porphyry Deposits , 2014 .

[41]  J. W. Hedenquist,et al.  Modeling the Formation of Advanced Argillic Lithocaps: Volcanic Vapor Condensation Above Porphyry Intrusions , 2013 .

[42]  E. Westman,et al.  Temporal and spatial distribution of alteration, mineralization and fluid inclusions in the transitional high-sulfidation epithermal-porphyry copper system at Red Mountain, Arizona , 2013 .

[43]  Zhiming Yang,et al.  EVALUATION OF INTER-INSTRUMENT VARIATIONS AMONG SHORT WAVELENGTH INFRARED (SWIR) DEVICES , 2012 .

[44]  I. Yusta,et al.  Mineralogical, IR-spectral and geochemical monitoring of hydrothermal alteration in a deformed and metamorphosed Jurassic VMS deposit at Arroyo Rojo, Tierra del Fuego, Argentina , 2012 .

[45]  J. Gemmell,et al.  Exploration Tools for Linked Porphyry and Epithermal Deposits: Example from the Mankayan Intrusion-Centered Cu-Au District, Luzon, Philippines , 2011 .

[46]  J. Huntington,et al.  Variations in composition and abundance of white mica in the hydrothermal alteration system at Helly , 2011 .

[47]  R. Sillitoe Porphyry Copper Systems , 2010 .

[48]  Yao Mei-juan APPLICATION OF PORTABLE INFRARED MINERAL ANALYZER(PIMA) IN THE QIANHE GOLD MINE,HENAN PROVINCE , 2008 .

[49]  Holliday Advances in Geological Models and Exploration Methods for Copper ± Gold Porphyry Deposits , 2007 .

[50]  J. Huntington,et al.  Infrared spectral reflectance characterization of the hydrothermal alteration at the Tuwu Cu–Au deposit, Xinjiang, China , 2005 .

[51]  Sarah Jones,et al.  Short Wavelength Infrared Spectral Characteristics of the HW Horizon:Implications for Exploration in the Myra Falls Volcanic-Hosted Massive Sulfide Camp, Vancouver Island, British Columbia, Canada , 2005 .

[52]  Mark G. Doyle,et al.  Short Wavelength Infrared (SWIR) Spectral Analysis of Hydrothermal Alteration Zones Associated with Base Metal Sulfide Deposits at Rosebery and Western Tharsis, Tasmania, and Highway-Reward, Queensland , 2001 .

[53]  J. Boardman,et al.  Mapping hydrothermal alteration in the Comstock mining district, Nevada, using simulated satellite‐borne hyperspectral data , 1999 .

[54]  H. Richard Exploration of porphyry copper lithocaps , 1995 .

[55]  Rocnn E. SrorrnncnN,et al.  An experimental study of Na-K exchange between alunite and aqueous sulfate solutions , 1990 .