Maghfouri, Sajjad, Rastad, Ebrahim, Lentz, David R., Mousivand, Fardin, Choulet, Flavien (2018) Mineralogy, microchemistry and fluid inclusion studies of the Besshi-type Nudeh Cu-Zn VMS deposit, Iran. Geochemistry, 78 (1) 40-57 doi:10.1016/j.chemer.2017.11.005

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.

	Agard, P., Jolivet, L., Vrielynck, B., Burov, E., Monié, P. (2007) Plate acceleration: The obduction trigger?. Earth and Planetary Science Letters, 258 (3) 428-441 doi:10.1016/j.epsl.2007.04.002
	Aghanabati (1998) Geosciences Major sedimentary and structural units of Iran (map) 7, 29
	Aghanabati (2004) , 600
	Alavi, Mehdi (1996) Tectonostratigraphic synthesis and structural style of the alborz mountain system in Northern Iran. Journal of Geodynamics, 21 (1). 1-33 doi:10.1016/0264-3707(95)00009-7
	Almodóvar (1998) Miner. Deposita Geology and genesis of the Aznalcóllar massive sulphide deposits Iberian Pyrite Belt, Spain 33, 111
	Badrzadeh, Zahra, Barrett, Timothy J., Peter, Jan M., Gimeno, Domingo, Sabzehei, Mossaieb, Aghazadeh, Mehraj (2011) Geology, mineralogy, and sulfur isotope geochemistry of the Sargaz Cu–Zn volcanogenic massive sulfide deposit, Sanandaj–Sirjan Zone, Iran. Mineralium Deposita, 46 (8) 905-923 doi:10.1007/s00126-011-0357-4
	Bajwah (1985)
	Bani-Adam (2000)
	Barrett, T. J., MacLean, W. H. (1991) Chemical, mass, and oxygen isotope changes during extreme hydrothermal alteration of an Archean rhyolite, Noranda, Quebec. Economic Geology, 86 (2) 406-414 doi:10.2113/gsecongeo.86.2.406
	Barrett (1994) Explor. Min. Geol. Mass changes in hydrothermal alteration zones associated with VMS deposits of the Noranda area 3, 131
	Bischoff, J. L., Pitzer, K. S. (1989) Liquid-vapor relations for the system NaCl-H 2 O; summary of the P-T-x surface from 300 degrees to 500 degrees C. American Journal of Science, 289 (3) 217-248 doi:10.2475/ajs.289.3.217
	Bischoff, J. L., Rosenbauer, R. J. (1985) An empirical equation of state for hydrothermal seawater (3.2 percent NaCl) American Journal of Science, 285 (8) 725-763 doi:10.2475/ajs.285.8.725
	Bodnar (1985) Rev. Econ. Geol. Fluid-inclusion systematics in epithermal systems 2, 73
	Bodnar (2014) Fluid inclusions in hydrothermal ore deposits
	Bodnar, R.J. (1993) Revised equation and table for determining the freezing point depression of H2O-Nacl solutions. Geochimica et Cosmochimica Acta, 57 (3) 683-684 doi:10.1016/0016-7037(93)90378-a
	Bralia, A., Sabatini, G., Troja, F. (1979) A revaluation of the Co/Ni ratio in pyrite as geochemical tool in ore genesis problems. Mineralium Deposita, 14 (3) doi:10.1007/bf00206365
	Bryndzia (1983) Mineralogy, geochemistry, and mineral chemistry of siliceous ore and altered footwall rocks in the Uwamuki 2 and 4 deposits, Kosaka mine, Hokuroku district, Japan , 507
	Cambel (1968) Proc. 23rd Int. Geol. Congress Geochemistry of nickel and cobalt in pyrrhotines of different genetic types 6, 169
	Campbell (1984) Can. Mineral. Nickel and cobalt in pyrrhotite and pyrite from the Faro and Sullivan orebodies 22, 503
	Carstens (1941) Nor. Geol. Tidsskr. Om geokjemiske undersokelser av malmer 21, 213
	Coad (1985) CIM Bull. Rhyolite geology at Kidd Creek − a progress report 78, 70
	Costa, U. R., Barnett, R. L., Kerrich, R. (1983) The Mattagami Lake Mine Archean Zn-Cu sulfide deposit, Quebec; hydrothermal coprecipitation of talc and sulfides in a sea-floor brine pool; evidence from geochemistry, 18 O/ 16 O, and mineral chemistry. Economic Geology, 78 (6) 1144-1203 doi:10.2113/gsecongeo.78.6.1144
	Crawford (1981) Mineral. Assoc. Canada Short Course Handb. Phase equilibria in aqueous fluid inclusions 6, 75
	Czamanske, Gerald K. (1974) The FeS Content of Sphalerite Along the Chalcopyrite-Pyrite-Bornite Sulfur Fugacity Buffer. Economic Geology, 69 (8) 1328-1334 doi:10.2113/gsecongeo.69.8.1328
	De Ronde (1995) Mineral. Assoc. Canada Short Course Ser. Fluid chemistry and isotopic characteristics of seafloor hydrothermal systems and associated VMS deposits: potential for magmatic contribution 23, 479
	Dill, H. (1979) Lagerst�ttenkundliche Untersuchungen zur Entstehung der Pyrit-f�hrenden Blei-Kupfer-Zink-Lagerst�tte Accesa (SW-Toskana) Mineralium Deposita, 14 (1) doi:10.1007/bf00201867
	Franklin (2005) , 523
	Frater (1978)
	Gavelin, S., Gabrielson, O., 1947. Spectrochemical investigation of sulfide minerals from ores of the Skellefte district. The significance of minor constituents for certain practical and theoretical problems of economic geology. Sver. Geol. Undersokn. Ser. C 491, Arsbok 41 (10).
	Gehrisch, W., Maucher, A., Nielsen, H. (1975) Sulfur-isotope and trace element analyses from the sulitjelma ore bodies, Northern Norway. Mineralium Deposita, 10 (1) 57-69 doi:10.1007/bf00207461
	Ghasemi, A., Talbot, C.J. (2006) A new tectonic scenario for the Sanandaj–Sirjan Zone (Iran) Journal of Asian Earth Sciences, 26 (6) 683-693 doi:10.1016/j.jseaes.2005.01.003
	Gibson, H. L., Watkinson, D. H., Comba, C. D. A. (1983) Silicification; hydrothermal alteration in an Archean geothermal system within the Amulet Rhyolite Formation, Noranda, Quebec. Economic Geology, 78 (5) 954-971 doi:10.2113/gsecongeo.78.5.954
	Gökçe, Ahmet, Bozkaya, Gülcan (2003) Fluid-Inclusion and Stable-Isotope Characteristics of the Inler Yaylasi Lead-Zinc Deposits, Northern Turkey. International Geology Review, 45 (11) 1044-1054 doi:10.2747/0020-6814.45.11.1044
	Goldstein (1994) SEPM (Soc. Sedim. Geol.) Short Course Systematics of fluid inclusions in diagenetic minerals 31, 214
	Goodfellow (2003) Econ. Geol. Monogr. Geological and genetic attributes of volcanic sediment-hosted massive sulfide deposits of the Bathurst Mining Camp, northern New Brunswick—a synthesis 11, 245
	Goodfellow, Wayne D., Peter, Jan M. (1996) Sulphur isotope composition of the Brunswick No. 12 massive sulphide deposit, Bathurst Mining Camp, New Brunswick: implications for ambient environment, sulphur source, and ore genesis. Canadian Journal of Earth Sciences, 33 (2) 231-251 doi:10.1139/e96-020
	Gottesman (2007) Geochim. Cosmochim. Acta Zn/Cd ratios in calcsilicate-hosted sphalerite ores at Tumurtijn-Ovoo, Mongolia 67, 323
	Green, G. R., Solomon, M., Walshe, J. L. (1981) The formation of the volcanic-hosted massive sulfide ore deposit at Rosebery, Tasmania. Economic Geology, 76 (2) 304-338 doi:10.2113/gsecongeo.76.2.304
	Hall, Wayne E., Rose, Harry J., Simon, Frederick (1971) Fractionation of minor elements between galena and sphalerite, Darwin lead-silver-zinc mine, Inyo County, California and its significance in geothermometry. Economic Geology, 66 (4) 602-606 doi:10.2113/gsecongeo.66.4.602
	Hannington (1999) Econ. Geol. Sulfide mineralogy, geochemistry, and ore genesis of the Kidd Creek deposit: part I. North: central and south orebodies 10, 163
	Hannington (1999) Econ. Geol. Sulfide mineralogy geochemistry, and ore genesis of the Kidd Creek deposit: part II. the Bornite zone 10, 225
	Hannington (2004) Geol. Surv. Canada Open File A global database of seafloor hydrothermal systems, including a digital database of geochemical analyses of seafloor polymetallic sulfides 4598
	Hass (1976) US Geol. Surv. Bull. Thermodynamic properties of the coexisting phases and thermochemical properties of the NaCl component in boiling NaCl solutions , 1421
	Hawley, J. E., Nichol, Ian (1961) Trace elements in pyrite, pyrrhotite and chalcopyrite of different ores. Economic Geology, 56 (3) 467-487 doi:10.2113/gsecongeo.56.3.467
	Hegemann (1943) Z. Angew. Mineral Die geochemische Bedeutung von Kobalt und Nickel im pyrit 4, 122
	Holland, R. A. G., Bray, C. J., Spooner, E. T. C. (1978) A method for preparing doubly polished thin sections suitable for microthermometric examination of fluid inclusions. Mineralogical Magazine, 42 (323) 407-408 doi:10.1180/minmag.1978.042.323.15
	Huston, David L., Sie, Soey H., Suter, Gary F., Cooke, David R., Both, Ross A. (1995) Trace elements in sulfide minerals from eastern Australian volcanic-hosted massive sulfide deposits; Part I, Proton microprobe analyses of pyrite, chalcopyrite, and sphalerite, and Part II, Selenium levels in pyrite; comparison with delta 34 S values and implications for the source of sulfur in volcanogenic hydrothermal systems. Economic Geology, 90 (5) 1167-1196 doi:10.2113/gsecongeo.90.5.1167
	Ioannou, S. E., Spooner, E. T. C., Barrie, C. T. (2007) Fluid Temperature and Salinity Characteristics of the Matagami Volcanogenic Massive Sulfide District, Quebec. Economic Geology, 102 (4) 691-715 doi:10.2113/gsecongeo.102.4.691
	Johan, Z. (1988) Indium and germanium in the structure of sphalerite: an example of coupled substitution with Copper. Mineralogy and Petrology, 39 (3) 211-229 doi:10.1007/bf01163036
	Jonasson (1978) Geol. Surv. Canada Bull. Zn/Cd ratios for sphalerites from some Canadian sulfide ore samples 78, 195
	Knight (2000)
	Lavery, Norman G. (1985) Quantifying chemical changes in hydrothermally altered volcanic sequences — silica enrichment as a guide to the crandon massive sulfide deposit, Wisconsin, U.S.A. Journal of Geochemical Exploration, 24 (1) 1-27 doi:10.1016/0375-6742(85)90002-0
	Layton-Matthews, D., Peter, J. M., Scott, S. D., Leybourne, M. I. (2008) Distribution, Mineralogy, and Geochemistry of Selenium in Felsic Volcanic-Hosted Massive Sulfide Deposits of the Finlayson Lake District, Yukon Territory, Canada. Economic Geology, 103 (1) 61-88 doi:10.2113/gsecongeo.103.1.61
	Legendre, O., 1994. Indium in base-metal sulfides from various occurrences: new data. Int. Mineral. Assoc., 16th Gen. Meeting (Pisa), 237 (abstr.).
	Lentz, David R., Goodfellow, Wayne D. (1996) Intense silicification of footwall sedimentary rocks in the stockwork alteration zone beneath the Brunswick No. 12 massive sulphide deposit, Bathurst, New Brunswick. Canadian Journal of Earth Sciences, 33 (2) 284-302 doi:10.1139/e96-022
	Loftus-Hills, G., Solomon, M. (1967) Cobalt, nickel and selenium in sulphides as indicators of ore genesis. Mineralium Deposita, 2 (3) doi:10.1007/bf00201918
	Lusk, John, Calder, Brian O.E (2004) The composition of sphalerite and associated sulfides in reactions of the Cu–Fe–Zn–S, Fe–Zn–S and Cu–Fe–S systems at 1 bar and temperatures between 250 and 535 °C. Chemical Geology, 203 (3) 319-345 doi:10.1016/j.chemgeo.2003.10.011
	Lydon (1996) Bol. Geológico y Minero Characteristics of volcanogenic massive sulfide deposits: interpretation in terms of hydrothermal convection systems and magmatic hydrothermal systems 107, 215
	Macdonald, A. J., Spooner, E. T. C. (1981) Calibration of a Linkam TH 600 programmable heating-cooling stage for microthermometric examination of fluid inclusions. Economic Geology, 76 (5) 1248-1258 doi:10.2113/gsecongeo.76.5.1248
	Maghfouri (2011) Ore facies in the Nudeh volcanogenic massive sulfide deposit, Southwest Sabzevar zone
	Maghfouri (2015) J. Earth Sci. Iran Nudeh volcanogenic massive sulfide (VMS) deposit, a Besshi-type VMS deposit, southwest sabzevar
	Maghfouri (2012)
	Marcoux, E. (1997) Lead isotope systematics of the giant massive sulphide deposits in the Iberian Pyrite Belt. Mineralium Deposita, 33 (1) 45-58 doi:10.1007/s001260050132
	Maslennikov, V. V., Maslennikova, S. P., Large, R. R., Danyushevsky, L. V. (2009) Study of Trace Element Zonation in Vent Chimneys from the Silurian Yaman-Kasy Volcanic-Hosted Massive Sulfide Deposit (Southern Urals, Russia) Using Laser Ablation-Inductively Coupled Plasma Mass Spectrometry (LA-ICPMS) Economic Geology, 104 (8) 1111-1141 doi:10.2113/gsecongeo.104.8.1111
	Masoudi (2008)
	Mookherjee, A., Philip, R. (1979) Distribution of copper, cobalt and nickel in ores and host-rocks, Ingladhal, Karnataka, India. Mineralium Deposita, 14 (1) doi:10.1007/bf00201866
	Mousivand (2007) Neues Jahrbuch für Mineralogie Abhandlungen The Bavanat Cu–Zn–Ag orebody: first recognition of a Besshi-type VMS deposit in Iran 183, 297
	Mousivand (2008) An overview of volcanogenic massive sulfide deposits of Iran
	Mousivand, Fardin, Rastad, Ebrahim, Meffre, Sebastien, Peter, Jan M., Solomon, Mike, Zaw, Khin (2011) U–Pb geochronology and Pb isotope characteristics of the Chahgaz volcanogenic massive sulphide deposit, southern Iran. International Geology Review, 53 (10) 1239-1262 doi:10.1080/00206811003783364
	Nehlig, P., Cassard, D., Marcoux, E. (1997) Geometry and genesis of feeder zones of massive sulphide deposits: constraints from the Rio Tinto ore deposit (Spain) Mineralium Deposita, 33 (1) 137-149 doi:10.1007/s001260050137
	Nishiyama (1974) Minor elements in some sulfide minerals from the Kuroko deposits of the Shakanai mine , 37l
	Ohmoto, Hiroshi (1996) Formation of volcanogenic massive sulfide deposits: The Kuroko perspective. Ore Geology Reviews, 10 (3) 135-177 doi:10.1016/0169-1368(95)00021-6
	Pattrick (1991) The substitution of indium and copper in natural sphalerite: a study using electron microscopy , 223
	Peter (1999) Rev. Econ. Geol. Windy craggy, northwestern british columbia: the world's largest besshi deposit 8, 261
	Pisutha-Arnond (1983) Econ. Geol. Monogr. Thermal history: and chemical and isotopic compositions of the ore-forming fluids responsible for the Kuroko massive sulfide deposits in the Hokuroko district of Japan 5, 523
	Potter (1977) U.S. Geol. Surv. J. Res. Pressure corrections for fluid-inclusion homogenization temperatures based on the volumetric properties of the system NaCl-H2O 5, 603
	Price (1972)
	Rastad (2002) Islamic Republ. Iran Sheikh-Ali copper deposit, a Cyprus-type VMS deposit in southeast Iran Journal of Sciences 13, 51
	Roedder, E, Bodnar, R J (1980) Geologic Pressure Determinations from Fluid Inclusion Studies. Annual Review of Earth and Planetary Sciences, 8. 263-301 doi:10.1146/annurev.ea.08.050180.001403
	Roscoe (1965) Can. J. Earth Sci. Geochemical and isotopic studies in the Noranda and Matagami areas 68, 9
	Rossetti, Federico, Nasrabady, Mohsen, Vignaroli, Gianluca, Theye, Thomas, Gerdes, Axel, Razavi, Mohammad Hossein, Vaziri, Hosein Moin (2010) Early Cretaceous migmatitic mafic granulites from the Sabzevar range (NE Iran): implications for the closure of the Mesozoic peri-Tethyan oceans in central Iran. Terra Nova, 22 (1). 26-34 doi:10.1111/j.1365-3121.2009.00912.x
	Sánchez-España, Javier, Velasco, Francisco, Yusta, Iñaki (2000) Hydrothermal alteration of felsic volcanic rocks associated with massive sulphide deposition in the northern Iberian Pyrite Belt (SW Spain) Applied Geochemistry, 15 (9) 1265-1290 doi:10.1016/s0883-2927(99)00119-5
	Sánchez-España, Javier, Velasco, Francisco, Boyce, Adrian J., Fallick, Anthony E. (2003) Source and evolution of ore-forming hydrothermal fluids in the northern Iberian Pyrite Belt massive sulphide deposits (SW Spain): evidence from fluid inclusions and stable isotopes. Mineralium Deposita, 38 (5) 519-537 doi:10.1007/s00126-002-0326-z
	Sangameshwar (1972)
	Sato (1972) Mining Geol. Behaviours of ore-forming solutions in seawater 22, 31
	Scott, S. D., Barnes, H. L. (1971) Sphalerite geothermometry and geobarometry. Economic Geology, 66 (4) 653-669 doi:10.2113/gsecongeo.66.4.653
	Scott (1997) Submarine hydrothermal systems and deposits , 797
	Seyfried, W.E., Ding, Kang, Berndt, M.E. (1991) Phase equilibria constraints on the chemistry of hot spring fluids at mid-ocean ridges. Geochimica et Cosmochimica Acta, 55 (12) 3559-3580 doi:10.1016/0016-7037(91)90056-b
	Shanks (2010) Volcanogenic massive sulfide occurrence model
	Shepherd (1985)
	Sieh (1983) Geol. Soc. China Mem. S Geochemical study of the pyrites in the Tamayenshan area, eastern Taiwan , 167
	Simon, Grigore, Essene, Eric J. (1996) Phase relations among selenides, sulfides, tellurides, and oxides; I, Thermodynamic properties and calculated equilibria. Economic Geology, 91 (7) 1183-1208 doi:10.2113/gsecongeo.91.7.1183
	Solomon, M., Tornos, F., Large, R.R., Badham, J.N.P., Both, R.A., Zaw, Khin (2004) Zn–Pb–Cu volcanic-hosted massive sulphide deposits: criteria for distinguishing brine pool-type from black smoker-type sulphide deposition. Ore Geology Reviews, 25 (3) 259-283 doi:10.1016/j.oregeorev.2004.01.003
	Solomon, Mike (2008) Brine pool deposition for the Zn–Pb–Cu massive sulphide deposits of the Bathurst mining camp, New Brunswick, Canada. I. Comparisons with the Iberian pyrite belt. Ore Geology Reviews, 33 (3) 329-351 doi:10.1016/j.oregeorev.2007.04.001
	Solomon, Mike (2008) Brine-pool deposition for the Zn–Pb–Cu massive sulphide deposits of the Bathurst mining camp, New Brunswick, Canada. II. Ocean anoxia during mineralisation. Ore Geology Reviews, 33 (3) 352-360 doi:10.1016/j.oregeorev.2007.04.002
	Sutherland (1967) Can. Mineral. The chemistry of some New Brunswick pyrites 9, 7l
	Tischendrof (1964) Geochem. Int. On the conditions of formation of clausthalite galena and some observations on the distribution of Se in galena as function of oxidation potential and pH 1, 1205
	Toscano (1997) Multi-scale fluid evolution in the masa valverde stockwork (Iberian pyrite belt): evidence from fluid inclusions [abs.] , 101
	Turner, J.S., Campbell, I.H. (1987) Temperature, density and buoyancy fluxes in “black smoker” plumes, and the criterion for buoyancy reversal. Earth and Planetary Science Letters, 86 (1) 85-92 doi:10.1016/0012-821x(87)90191-9
	Urabe, Tetsuro, Scott, S. D. (1983) Geology and footwall alteration of the South Bay massive sulphide deposit, northwestern Ontario, Canada. Canadian Journal of Earth Sciences, 20 (12) 1862-1879 doi:10.1139/e83-176
	Vahdati Daneshmand (1999)
	Viets, John G., Hopkins, Roy T., Miller, Bruce M. (1992) Variations in minor and trace metals in sphalerite from mississippi valley-type deposits of the Ozark region; genetic implications. Economic Geology, 87 (7) 1897-1905 doi:10.2113/gsecongeo.87.7.1897
	Walker, R. R., Matulich, A., Amos, A. C., Watkins, J. J., Mannard, G. W. (1975) The geology of the Kidd Creek Mine. Economic Geology, 70 (1) 80-89 doi:10.2113/gsecongeo.70.1.80
	Walshe, J. L., Solomon, M. (1981) An investigation into the environment of formation of the volcanic-hosted Mt. Lyell copper deposits using geology, mineralogy, stable isotopes, and a six-component chlorite solid solution model. Economic Geology, 76 (2) 246-284 doi:10.2113/gsecongeo.76.2.246
	Xuexin, Song (1984) Minor elements and ore genesis of the Fankou lead-zinc deposit, China. Mineralium Deposita, 19 (2) doi:10.1007/bf00204667
	Yamamoto, M. (1976) Relationship between Se/S and sulfur isotope ratios of hydrothermal sulfide minerals. Mineralium Deposita, 11 (2) doi:10.1007/bf00204481
	Yarmohammadi (2006)
	Zaw, Khin, Large, R. R. (1996) Petrology and geochemistry of sphalerite from the Cambrian VHMS deposits in the Rosebery-Hercules district, western Tasmania: Implications for gold mineralisation and Devonian metamorphic-metasomatic processes. Mineralogy and Petrology, 57 (1) 97-118 doi:10.1007/bf01161624

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