Log InRegister
Quick Links : The Mindat ManualThe Rock H. Currier Digital LibraryMindat Newsletter [Free Download]
Home PageAbout MindatThe Mindat ManualHistory of MindatCopyright StatusWho We AreContact UsAdvertise on Mindat
Donate to MindatCorporate SponsorshipSponsor a PageSponsored PagesMindat AdvertisersAdvertise on Mindat
Learning CenterWhat is a mineral?The most common minerals on earthInformation for EducatorsMindat ArticlesThe ElementsThe Rock H. Currier Digital LibraryGeologic Time
Minerals by PropertiesMinerals by ChemistryAdvanced Locality SearchRandom MineralRandom LocalitySearch by minIDLocalities Near MeSearch ArticlesSearch GlossaryMore Search Options
Search For:
Mineral Name:
Locality Name:
Keyword(s):
 
The Mindat ManualAdd a New PhotoRate PhotosLocality Edit ReportCoordinate Completion ReportAdd Glossary Item
Mining CompaniesStatisticsUsersMineral MuseumsClubs & OrganizationsMineral Shows & EventsThe Mindat DirectoryDevice SettingsThe Mineral Quiz
Photo SearchPhoto GalleriesSearch by ColorNew Photos TodayNew Photos YesterdayMembers' Photo GalleriesPast Photo of the Day GalleryPhotography

Large, Ross R. (2025) Simple graphical tools to understand the relationship between porphyry composition, hydrothermal alteration, mineralogy and copper-gold grades in porphyry copper deposits. Ore Geology Reviews, 182. doi:10.1016/j.oregeorev.2025.106581

Advanced
   -   Only viewable:
Reference TypeJournal (article/letter/editorial)
TitleSimple graphical tools to understand the relationship between porphyry composition, hydrothermal alteration, mineralogy and copper-gold grades in porphyry copper deposits
JournalOre Geology Reviews
AuthorsLarge, Ross R.Author
Year2025 (July)Volume182
PublisherElsevier BV
DOIdoi:10.1016/j.oregeorev.2025.106581Search in ResearchGate
Generate Citation Formats
Mindat Ref. ID18433025Long-form Identifiermindat:1:5:18433025:6
GUID0
Full ReferenceLarge, Ross R. (2025) Simple graphical tools to understand the relationship between porphyry composition, hydrothermal alteration, mineralogy and copper-gold grades in porphyry copper deposits. Ore Geology Reviews, 182. doi:10.1016/j.oregeorev.2025.106581
Plain TextLarge, Ross R. (2025) Simple graphical tools to understand the relationship between porphyry composition, hydrothermal alteration, mineralogy and copper-gold grades in porphyry copper deposits. Ore Geology Reviews, 182. doi:10.1016/j.oregeorev.2025.106581
In(2025) Ore Geology Reviews Vol. 182. Elsevier BV

References Listed

These are the references the publisher has listed as being connected to the article. Please check the article itself for the full list of references which may differ. Not all references are currently linkable within the Digital Library.

Ahmed, A.D., 2019. Epidote and chlorite mineral chemistry from the Yerington porphyry copper district, USA: genetic and exploration implications(Doctoral dissertation, University of Tasmania), 349 p.
Bachmann, K., Gutzmer, J. and Mac Fjellerad Persson, N.J., 2013. Alteration in the area of the Kristineberg VHMS deposit, Skellefte district, Sweden. In12th Biennial SGA Meeting on Mineral Deposit Research for a High-Tech World Conference Location Uppsala, SWEDEN(p. 498). SGU-SVERIGES GEOLOGISKA UNDERSOKNING-GEOLOGY SURVEY SWEDEN Location UPPSALA.
Burrows, David R., Rennison, Michael, Burt, David, Davies, Rod (2020) The Onto Cu-Au Discovery, Eastern Sumbawa, Indonesia: A Large, Middle Pleistocene Lithocap-Hosted High-Sulfidation Covellite-Pyrite Porphyry Deposit. Economic Geology, 115 (7). 1385-1412 doi:10.5382/econgeo.4766
CATHLES, L, SHANNON, R (2007) How potassium silicate alteration suggests the formation of porphyry ore deposits begins with the nearly explosive but barren expulsion of large volumes of magmatic water. Earth and Planetary Science Letters, 262 (1) 92-108 doi:10.1016/j.epsl.2007.07.029
Chitalin, A.F., Formichev, E., Usenko, V., Agapitov D. and Shtengelow, A., 2012, Structural model of Peschanka porphyry Cu-Au-Mo deposit, Western Chukotka, Russia: Structural Geology and Resources, Conference paper, p. 21-27.
Not Yet Imported: - book-chapter : 10.5382/SP.18.07

If you would like this item imported into the Digital Library, please contact us quoting Journal ID
Cook (2000) Environment, Analysis 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,Geochemistry: Exploration 20, 176
Creasey, Saville Cyrus (1959) Some phase relations in the hydrothermally altered rocks of porphyry copper deposits. Economic Geology, 54 (3) 351-373 doi:10.2113/gsecongeo.54.3.351
Eastoe, Christopher J., Solomon, M., Walshe, J. L. (1987) District-scale alteration associated with massive sulfide deposits in the Mount Read Volcanics, western Tasmania. Economic Geology, 82 (5) 1239-1258 doi:10.2113/gsecongeo.82.5.1239
Escolme, Angela, Berry, Ron F., Hunt, Julie, Halley, Scott, Potma, Warren (2019) Predictive Models of Mineralogy from Whole-Rock Assay Data: Case Study from the Productora Cu-Au-Mo Deposit, Chile. Economic Geology, 114 (8) 1513-1542 doi:10.5382/econgeo.2019.4650
Not Yet Imported: Seventy-Fifth Anniversary Volume - book-chapter : 10.5382/AV75.15

If you would like this item imported into the Digital Library, please contact us quoting Book ID 9781934969533
Gard, Matthew, Hasterok, Derrick, Halpin, Jacqueline A. (2019) Global whole-rock geochemical database compilation. Earth System Science Data, 11 (4). 1553-1566 doi:10.5194/essd-11-1553-2019
Gifkins (2005) , 156
Not Yet Imported: - journal-article : 10.5194/se-12-1931-2021

If you would like this item imported into the Digital Library, please contact us quoting Journal ID
Guilbert (2007) , 985
Gustafson, Lewis B., Hunt, John P. (1975) The porphyry copper deposit at El Salvador, Chile. Economic Geology, 70 (5) 857-912 doi:10.2113/gsecongeo.70.5.857
Halley, Scott (2020) Mapping Magmatic and Hydrothermal Processes from Routine Exploration Geochemical Analyses. Economic Geology, 115 (3). 489-503 doi:10.5382/econgeo.4722
Halley, S., 2021, Porphyry Copper Workshop; Part 2 Alteration Geochemistry: Workshop presented to CODES masters course, 2021, 28p. https://www.scotthalley.com.au/tutorials.
Hedenquist, Jeffrey W., Watanabe, Yasushi, Arribas, Antonio (2020) HYPOGENE ALUNITE FROM THE EL SALVADOR DISTRICT, CHILE, INDICATES POTENTIAL FOR A BLIND PORPHYRY COPPER CENTER. Economic Geology, 115 (2) 231-239 doi:10.5382/econgeo.4712
Hemley, J. J., Hunt, J. P. (1992) Hydrothermal ore-forming processes in the light of studies in rock-buffered systems; II, Some general geologic applications. Economic Geology, 87 (1) 23-43 doi:10.2113/gsecongeo.87.1.23
Herrmann (2002) Environment, Analysis MINSQ–a least squares spreadsheet method for calculating mineral proportions from whole rock major element analyses:Geochemistry: Exploration 4, 361
Hollister (1974) Transactions of SME-AIME Regional characteristics of porphyry copper deposits of South America 256, 45
Hollister (1978) N. Y. Geology of the Porphyry Copper Deposits of the Western Hemisphere: AIME , 177
Kirwin (2005) Geodynamics and Metallogeny of Mongolia with a Special Emphasis on Copper and Gold Deposits: SEG-IAGOD Field Trip Exploration history, geology, and mineralisation of the Kharmagtai gold–copper porphyry district, South Gobi region, Mongolia 14, 16p
Krushnisky, Alexandre, Mercier-Langevin, Patrick, Ross, Pierre-Simon, Goutier, Jean, McNicoll, Vicki, Moore, Lyndsay, Monecke, Thomas, Jackson, Simon E., Yang, Zhaoping, Petts, Duane C., Pilote, Claude (2023) Geology and Controls on Gold Enrichment at the Horne 5 Deposit and Implications for the Architecture of the Gold-Rich Horne Volcanogenic Massive Sulfide Complex, Abitibi Greenstone Belt, Canada. Economic Geology, 118 (2) 285-318 doi:10.5382/econgeo.4978
Large (2001) Economic Geology The Alteration Box Plot: A Simple Approach to Understanding the Relationship between Alteration Mineralogy and Lithogeochemistry Associated with Volcanic-Hosted Massive Sulfide Deposits 96, 957
Large, R. R. (1977) Chemical evolution and zonation of massive sulfide deposits in volcanic terrains. Economic Geology, 72 (4) 549-572 doi:10.2113/gsecongeo.72.4.549
Leveille (2012)
Lowell, J. David, Guilbert, John M. (1970) Lateral and vertical alteration-mineralization zoning in porphyry ore deposits. Economic Geology, 65 (4) 373-408 doi:10.2113/gsecongeo.65.4.373
McNulty, Brian A., Gemmell, J. Bruce, Davidson, Garry, Fox, Nathan (2023) Integrated stratigraphy, lithofacies, and U–Pb geochronology of the Myra Falls VHMS deposits, British Columbia, Canada: implications for episodic volcanism and ore deposit formation. Mineralium Deposita, 58 (2) 307-335 doi:10.1007/s00126-022-01124-0
Meyer (1967) , 166
Middlemost, Eric A.K. (1994) Naming materials in the magma/igneous rock system. Earth-Science Reviews, 37 (3) 215-224 doi:10.1016/0012-8252(94)90029-9
Mills, Hannah K., Piercey, Stephen J., Toole, Trish (2016) Geology, alteration, and lithogeochemistry of the Hood volcanogenic massive sulfide (VMS) deposits, Nunavut, Canada. Mineralium Deposita, 51 (4) 533-556 doi:10.1007/s00126-015-0612-1
Ohmoto, Hiroshi (1996) Formation of volcanogenic massive sulfide deposits: The Kuroko perspective. Ore Geology Reviews, 10 (3). doi:10.1016/0169-1368(95)00021-6
Pacey, Adam, Wilkinson, Jamie J., Cooke, David R. (2020) Chlorite and Epidote Mineral Chemistry in Porphyry Ore Systems: A Case Study of the Northparkes District, New South Wales, Australia. Economic Geology, 115 (4). 701-727 doi:10.5382/econgeo.4700
Pour (2011) SE Iran:Journal of Asian Earth Sciences Identification of hydrothermal alteration minerals for exploring of porphyry copper deposit using ASTER data 42, 1309
Rodrigues (2016) APEA Journal Core scanner technologies – take everything without breaking. APPEA - Oil and Gas Conference and Exhibition 56, 595
Seedorff, E., Dilles, J.H., Proffett, J.M., Einaudi, M.T., Zurcher, L., Stavast, W.J., Johnson, D.A. and Barton, M.D., 2005, Porphyry deposits: Characteristics and origin of hypogene features: Economic Geology 100th Anniversary volume, p.251-298.
Sharma, R. K. (2014) Hydrothermal alteration associated with copper-gold mineralisation at Dhani Basri, Dausa district, Rajasthan. Journal of the Geological Society of India, 84 (6) 709-726 doi:10.1007/s12594-014-0182-3
Sharkhuu, L., 1980, Report on results of exploration and evaluation works with the scale of 1:50 000. 1:10 000 conducted in Kharmagtai copper ore field in 1979-1980: Report 3366, Geological Information Center, Mongolian Geological Survey, p. 159 (in Russian).
Not Yet Imported: - book-chapter : 10.5382/AV100.26

If you would like this item imported into the Digital Library, please contact us quoting Journal ID
Sillitoe, R.H., 1993, Gold-rich porphyry copper deposits: Geological model and exploration implications: in Kirkham, R.V., Sinclair, W.D., Thorpe, R.I. and Duke, J.M., eds., Mineral Deposit modeling, Geological Association of Canada, Special paper 40, p. 465-478.
Sillitoe (2000) Econ. Geol. Gold-rich porphyry deposits: descriptive and genetic models and their role in exploration and discovery: in Gold in 2000; reviews v. 13, 315
Sillitoe, R. H. (2010) Porphyry Copper Systems. Economic Geology, 105 (1) 3-41 doi:10.2113/gsecongeo.105.1.3
Sillitoe (1984) Publication Philippine porphyry copper deposits: Geological setting and characteristics: CCOP technical 14, 89p
Sorrentino, Anna; Chirico, Rita; Corrado, Francesca; Laukamp, Carsten; Di Martire, Diego; Mondillo, Nicola (2024) The application of PRISMA hyperspectral satellite imagery in the delineation of distinct hydrothermal alteration zones in the Chilean Andes: The Marimaca IOCG and the RĂ­o Blanco-Los Bronces Cu-Mo porphyry districts. Ore Geology Reviews, 167. doi:10.1016/j.oregeorev.2024.105998
Theart, H.F.J., Ghavami-Riabi, R., Mouri, H., Gräser, P. (2011) Applying the box plot to the recognition of footwall alteration zones related to VMS deposits in a high-grade metamorphic terrain, South Africa, a lithogeochemical exploration application. Geochemistry, 71 (2) 143-154 doi:10.1016/j.chemer.2010.09.002
Titley (1982) The style and progress of mineralisation and alteration in porphyry copper systems, American south-west, in Titley SR., Advances in the geology of porphyry copper deposits , 93
Vila (1991) Northern Chile: Economic Geology Gold-rich porphyry systems in the Maricunga Belt 88, 1238
Wilkinson, Jamie J., Chang, Zhaoshan, Cooke, David R., Baker, Michael J., Wilkinson, Clara C., Inglis, Shaun, Chen, Huayong, Bruce Gemmell, J. (2015) The chlorite proximitor: A new tool for detecting porphyry ore deposits. Journal of Geochemical Exploration, 152. 10-26 doi:10.1016/j.gexplo.2015.01.005
Zhou, Yuanzhi, Zhang, Zhenjie, Yang, Jie, Ge, Yunzhao, Cheng, Qiuming (2022) Machine Learning and Singularity Analysis Reveal Zircon Fertility and Magmatic Intensity: Implications for Porphyry Copper Potential. Natural Resources Research, 31 (6) 3061-3078 doi:10.1007/s11053-022-10122-y

See Also

These are possibly similar items as determined by title/reference text matching only.

Large, Ross R. (2025) Simple graphical tools to understand the relationship between porphyry composition, hydrothermal alteration, mineralogy and copper-gold grades in porphyry copper deposits. Ore Geology Reviews, 182. 106581 doi:10.1016/j.oregeorev.2025.106581
Pour, Amin Beiranvand; Hashim, Mazlan (2012) The application of ASTER remote sensing data to porphyry copper and epithermal gold deposits. Ore Geology Reviews, 44. doi:10.1016/j.oregeorev.2011.09.009
Deng, Siyuan; Guo, Na; Tang, Nan; Shi, Weixin; Li, Xuerui; Li, Chunhao; Zhou, Weirui; Huang, Chao; Luo, Haiyang (2025) Indicator mineral characteristics of potassic alteration zones in porphyry copper deposits based on infrared spectroscopy technology: A case study of the Qulong porphyry copper deposit, Tibet. Ore Geology Reviews, 178. doi:10.1016/j.oregeorev.2025.106475
Pizarro, H.; Campos, E.; Bouzari, F.; Rousse, S.; Bissig, T.; Gregoire, M.; Riquelme, R. (2020) Porphyry indicator zircons (PIZs): Application to exploration of porphyry copper deposits. Ore Geology Reviews, 126. doi:10.1016/j.oregeorev.2020.103771
Xu, Xing-Wang; Mao, Qian; Li, Xian-Hua; Pirajno, Franco M.; Qu, Xun; Deng, Gang; Chen, Dai-Zhao; Zhang, Bao-Lin; Dong, Lian-Hui (2014) Copper–zinc albite porphyry in the Hersai porphyry copper deposit, East Junggar, China: A transition between late magmatic and hydrothermal porphyry copper deposit. Ore Geology Reviews, 61. doi:10.1016/j.oregeorev.2014.01.009
Pizarro, H.; Campos, E.; Bouzari, F.; Rousse, S.; Bissig, T.; Gregoire, M.; Riquelme, R. (2021) Corrigendum to “Porphyry indicator zircons (PIZs): Application to exploration of porphyry copper Deposits” [Ore Geol. Rev. 126 (2020) 103771]. Ore Geology Reviews, 129. doi:10.1016/j.oregeorev.2020.103891
Japas, M.S.; Rubinstein, N.A.; GĂłmez, A.L.R. (2022) Revisiting reverse osmosis as a mechanism contributing to metal zoning in porphyry copper deposits. Ore Geology Reviews, 143. doi:10.1016/j.oregeorev.2022.104746
Gilmour, Paul (1982) Grades and Tonnages of Porphyry Copper Deposits, in Titley, S.R., editor, Advances in Geology of the Porphyry Copper Deposits Southwestern North America: Tucson, University of Arizona Press: 736.
Hosseinjani Zadeh, Mahdieh; Tangestani, Majid H.; Velasco Roldan, Francisco; Yusta, Iñaki (2014) Spectral characteristics of minerals in alteration zones associated with porphyry copper deposits in the middle part of Kerman copper belt, SE Iran. Ore Geology Reviews, 62. doi:10.1016/j.oregeorev.2014.03.013
Sadigh, Sareh; Mirmohammadi, Mirsaleh; Asghari, Omid; Porwal, Alok (2023) Spatial distribution of porphyry copper deposits in Kerman Belt, Iran. Ore Geology Reviews, 153. doi:10.1016/j.oregeorev.2022.105251
Schwartz, George Melvin (1947) Hydrothermal alteration in the "porphyry copper" deposits. Economic Geology, 42 (4) 319-352 doi:10.2113/gsecongeo.42.4.319
 
and/or  
Mindat.org is an outreach project of the Hudson Institute of Mineralogy, a 501(c)(3) not-for-profit organization.
Copyright © mindat.org and the Hudson Institute of Mineralogy 1993-2025, except where stated. Most political location boundaries are © OpenStreetMap contributors. Mindat.org relies on the contributions of thousands of members and supporters. Founded in 2000 by Jolyon Ralph.
To cite: Ralph, J., Von Bargen, D., Martynov, P., Zhang, J., Que, X., Prabhu, A., Morrison, S. M., Li, W., Chen, W., & Ma, X. (2025). Mindat.org: The open access mineralogy database to accelerate data-intensive geoscience research. American Mineralogist, 110(6), 833–844. doi:10.2138/am-2024-9486.
Privacy Policy - Terms & Conditions - Contact Us / DMCA issues - Report a bug/vulnerability Current server date and time: August 13, 2025 23:29:41
Go to top of page