Study of mass changes of elements during skarnification processes in east of Sungun-Chay river, NE of Tabriz, Iran.

Abstract

Copper-bearing skarn zone in east of Sungun-Chay river is
located about 100 km NE of Tabriz, and was developed along the contact of
the mineralized porphyry granitoid stock (Oligo-Miocene) with impure
carbonate rocks (Upper Cretaceous). Both endoskarn and exoskarn occurred
in this zone. Endoskarn is narrow (~0.5-2m) whereas exoskarn is relatively
broad (25-55m) and contains minerals such as calc-silicates (grandite,
diopside-hedenbergite, tremolite-actinolite, epidote), silicates (quartz,
chlorite, and clays), sulfides (pyrite, chalcopyrite, sphalerite, galena,
bornite), oxides (magnetite, hematite), and carbonates (calcite, ankerite).
Skarnification processes occurred in two distinct stages, including
progradation and retrogradation. Calculations of chemical index of alteration
(CIA) indicate that the exoskarn underwent metasomatic alteration within
the range of 8.41% to 57.29%. Analysis studies of mass changes of
elements, on the basis of Nb (as a monitor immobile element), indicate that
considerable amounts of elements such as Fe, Si, Mg, S, Cu, Pb, and Zn
were added to the skarn system by hydrothermal fluids from the side of
pluton, while substantial amounts of Ca was leached out of the system. The
overall obtained results show that elements such as Fe, Si, and Mg were
introduced into the skarn system by metasomatizing fluids during both
progradatian and retrogradatian stages whereas the ore-forming elements
such as Cu, Pb, Zn, and S were added to the system mainly during retrograde
stage. The inharmonious mass increase of Al and portion of mass changes of
Si are due to the local variations of pelitic impurities within the carbonate
rocks (as protolith).

Keywords

References

[1] Khadem N., "Types of copper ore deposits in Iran", Geological Survey

of Iran, Tehran, Internal Report, (1965) 1-6.

[2] Vosooghzadeh G.H., Tadaiyon A.H., "Report on Geochemical studies in

northwest of Ahar", Barmolk, Kighal, and Sungun, Geological Survey of

Iran, Internal Report, (1973) 1-23.

[3] Calagari A.A., Hosseinzadeh G., "The mineralogy of copper-bearing

skarn in the east of Sungun-Chay river", East-Azarbaidjan, Iran, J. of Asian

Earth Sciences, (in press).

[4] Hezarkhani A., "Mass changes durig hydrothermal alteration/

mineralization in a porphyry copper deposit", eastern Sungun, northwestern

Iran, J. of Asian Earth Sciences, (in press).

[5] Mehrpartou M., "Contributions to the geology, geochemistry, ore

genesis, and fluid inclusion investigations on Sungun Cu-Mo porphyry

deposit", NW of Iran, PhD dissertation, University of Hamburg, Germany,

(1993) 1-245.

[6] Emami M.H., Babakhani A.R., "Studies of geology, petrology, and lithogeochemistry

of Sungun Cu-Mo deposi", Iranian Ministry of Mines and

Metals, (1991) 1- 61.

[7] Calagari A.A., "Geology and fracture-related hypogene hydrothermal

alteration and mineralization of porphyry copper deposit at Sungun", J. of

Geological Society of India 64, No.5, ( 2004) 595-618.

[8] Calagari A.A., Pattrick R. A. D., Polya D. A., "Veinlets and microveinlets

studies in Sungun porphyry copper deposit", East Azarbaidjan, Iran,

Quaternary J. of Geosciences, Geological Survey of Iran 10, No. 39-40,

(2001) 70-79.

[9] Meinert L.D., "Compositional variation of igneous rocks associated with

skarn deposits- chemical evidence for a genetic connection between

petrogenesis and mineralization, In Magmas", Fluids, and Ore Deposits.Edited by J.F.H. Thompson. Mineralogical Association of Canada Short

Course 23, (1995) 401-418.

[10] Ray G.E., Webster I.C.L., Ettlinger A.D., "The distribution of skarns in

British Columbia and the chemistry and ages of their related plutonic

rocks", Economic Geology 90, (1995) 920-937.

[11] Meinert L.D., "Application of skarn deposit zonation models to mineral

exploration", Exploration and Mining Geology 6, (1997) 185-208.

[12] Einaudi M.T., "General features and origin of skarns associated with

porphyry copper plutons",southwestern North America, Advances in

Geology of Porphyry Copper Deposits, Southwestern North America,

(1982) 185-209.

[13] Gresens R. L., "Composition-volume relationships of metasomatism",

Chemical Geology 2, (1967) 47-55.

[14] Grant J. A., "The isocon diagram – a simple solution to Gresen’s

equation for metasomatic alteration", Economic Geology 81, (1986) 1976-

1982.

[15] Millot G., Bonifas M., "Transformations isovolumetriques dans les

phenomenes de laterisation et bauxitisation", Bulletin Service Carte

Geologie Alsace Lorraine 8, (1955) 3-20.

[16] Nesbitt H.W., "Mobility and fractionation of rare elements during

weathering of a granodiorite", Nature 279, (1979) 206-210.

[17] Nesbitt H.W., Markovics G., Price R.C., "Chemical processes affecting

alkalis and alkaline earths during continental weathering", Geochimica et

Cosmochimica Acta 44, (1980) 1659-1666.

[18] MacLean W. H., Kranidiotis P., "Immobile elements as monitors of

mass transfer in hydrothermal alteration: Phelps Dodge massive sulfide

deposit", Matagami. Quebec.Economic Geology 82, (1987) 951-962.

[19] MacLean W. H., "Mass change calculations in altered rock series",

Mineralium Deposita 25, (1990) 44-49.

[20] Brimhall G. H., Dietrich W. E., "Constitutive mass balance relations

between chemical composition", volume, density, porosity and strain in

metasomatic hydrochemical systems: results of weathering and pedogenesis,

Geochimica et Cosmochimica Acta 51, (1987) 567-587.

[21] Nesbitt H.W., Wilson R. E., "Recent chemical weathering of basalts",

American J. of Science 292, (1992) 740-777.

[22] Chadwick O.A., Brimhall G. H., Hendricks D.M., "From a black box to

a grey box-a mass balance interpretation of pedogenesis", Geomorphology

3, (1990) 369-390.[23] Brimhall G. H., Lewis C. J., Ague J.J., Dietrich W.E., Hampel J.,

Teague T., Rix P., "Metal enrichment in bauxites by deposition of chemically

mature Aeolian dust", Natuer 333, (1988) 819-824.

[24] Brimhall G. H., Lewis C.J., Ford C., Bratt J., Taylor G., Warin O.,

"Quantitative geochemical approach to petrogenesis : importance of parent

material reduction", volumetric expansion, and eolian influx in laterization,

Geoderma 51, (1991) 51-91.

[25] Brimhall G. H., Chadwick O. A., Lewis. C. J., Compson W., Williams

I. S., Danty K. J., Dietrich W. E., Power M. E., Hendricks D., Bratt J.,

"Deformational mass transfer and invasive processes in soil evolution",

Science 255, (1992) 695-702.

[26] Colin F., Brimhall G.H., Nahon D., Lewis C. J., Baronnet A., Danti K.,

"Equatorical rain forest lateritic mantles: a geomembrane filter", Geology

20, (1992) 523-526.

[27] Bestland E.A., Retallack G.J., Rice A., Mindszenty A., "Late Eocene

detrital laterites in central Oregon: mass balance geochemistry",

depositional setting and landscape evolution, Ecological Society of

American Bulletin 108, (1996) 285-302.

[28] Nahon D., Merino E., "Pseudomorphic replacement in tropical

weathering: evidence", geochemical consequences, and kinetic-rheological

origin, American J. of Science 297, (1997) 393-417.

[29] Nesbitt H.W., Markovics G., "Weathering of granodioritic crust, longterm

storage of elements in weathering profiles, and petrogenesis of

siliciclastic sediments", Geochimica et Cosmochimica Acta. 61, (1997)

1653-1670.

[30] Braun J.J., Pagel A., Herbillon A., Rosin C., "Mobilization and

redistribution of REEs and thorium in a syenitic laterite profile: a mass

balance study", Geochimica et Cosmochimica Acta 57, (1993) 4419-4434.

[31] MacLean W.H., Barrett T.J., "Lithogeochemical techniques using

immobile elements", Geochemical Exploration 48, (1993) 109-133.

[32] Kurtz A.C., Louis Derry L.A., Chadwick O.A., Alfano M. J.,

"Refractory element mobility in volcanic soils", Geology 28, (2000) 683-

686.

[33] Rollinson H., "Using geochemical data: evaluation", presentation,

interpretation, Longman Scientific and Technical, (1993) 1-352.

[34] Nesbitt H.W., Young G.M., "Early Proterozoic climate and plate

motions inferred from major element chemistry of lutites", Nature 299,

(1982) 715-717.

[35] Fedo C.M., Nesbitt P., Young G.M., "Unraveling the effect of

potassium metasomatism in sedimentary rocks and paleosols", withimplications for paleoweathering conditions and provenance, Geology 23,

(1995) 363-381.

Files

History

  • Receive Date: 02 July 2025
  • Revise Date: 04 February 2026
  • Accept Date: 02 July 2025

Share

How to cite

Statistics