Τα κοιτάσματα skarn εμφανίζονται σε όλο τον κόσμο και έχουν γίνει αντικείμενο εκμετάλλευσης για διάφορα στοιχεία. Χωρίζονται σε επτά βασικές κατηγορίες οι οποίες είναι: σιδήρου, βολφραμίου, μολυβδαινίου, χαλκού, κασσίτερου, ψευδαργύρου και χρυσού. Ο σχηματισμός τους λαμβάνει χώρα σε ποικίλα βάθη και γεωτεκτονικά περιβάλλοντα. Τα skarn δημιουργούνται από την αντικατάσταση ανθρακικών πετρωμάτων μέσω διεργασιών περιοχικής μεταμόρφωσης ή μεταμόρφωσης επαφής και μετασωμάτωσης. Στον ελληνικό χώρο τα μεγαλύτερα κοιτάσματα skarn βρίσκονται στη Σέριφο, στο Λαύριο και στην Ξάνθη.

Skarn deposits occur throughout the world and have been exploited for various elements. They are divided into seven main categories including iron, tungsten, molybdenum, copper, tin, zinc and gold. Formation of skarns take place at various depths and geotectonic environments. Skarns are formed from the replacement of carbonate rocks through processes of regional or thermal metamorphism and metasomatism. In the Greek area, the largest skarn deposits occur in Serifos, Laurium and Xanthi.

Aleksandrov, S. M. (1974) Geochemistry of boron-tin mineralization in the magnesian skarns of the eastern Chukotka: Geochemistry Internat., v. 11, p. 532-539.

Alpers, C. N. (1980). Mineralogy, paragenesis, and zoning of the Luz vein, Uchucchacua, Peru: B. A. thesis, Harvard Univ., 138 p.

Barrell, (1907). Geology of the Marysville mining district, Montana: U. S. Geol. Survey Prof. Paper 57, 178 p.

Blackwell, D.D., Steele, J.L., Frohme, C.F., Priest, G.R. and Black, G.L. (1990). Heat flow in the Oregon Cascade Range and its correlation with regional gravity, Curie Point depths, and geology: Journal of Geophysical Research, v. 95-B12, p. 19475-19493.

Bowers, J.R., Kerrick, D.M. and Furlong, K.P. (1990). Conduction model for the thermal evolution of the Cupsuptic aureole, Maine: American Journal of Science, v. 290, p. 644-665.

Burt, D.M. (1977). Mineralogy and petrology of skarn deposits: Soc. Italiana Mineralogia Petrologia Rendiconti, v. 33, p. 859-873

Burt, D.M. (1978). Tin silicate-borate-oxide equilibria in skarns and greisens-the system CaO- ----: ECON. GEOL., v. 73, p. 269-282.

Cooper, J. R. (1957). Metamorphism and volume loss in carbonate rocks near Johnson Camp, Cochise County, Arizona: Geol. Soc. America Bull., v. 68, p. 577-610.

Corsini, F., Cortecci, G., Leone, G., and Tanelli, G. (1980). Sulfur iotopic study of the skarn-(Cu-Pb-Zn) sulfide deposit of Valle del Temperino, Campiglia Marittima, Tuscany, Italy: ECON. GEOL., v. 75, p. 83-96.

Dick, L. A. (1976). Metamorphism and metasomatism at the MacMillan Pass tungsten deposit, Yukon and District of MacKenzie, Canada: M.S. thesis, Queens Univ., Kingston, 226 p.

Ducoux, M., Branquet, Y., Arbaret, L., Grasemann B., Rabillard, A., Gumiaux, C., Drufin, S. (2017). Synkinematic skarns and fluid drainage along detachments: The West Cycladic Systemon Serifos Island (Cyclades, Greece) and its related mineralization.

Economou, M. (1981). Magnetite deposits of skarn type from the Plaka area of Laurium, Greece. Chemie der Erde, 40, 241-252.

Eianudi, M.T. (1982a). Descriptions of skarns associated with porphyry copper plutons, southwestern North America, in Titley, S.R., ED., Advances in Geology of the Porphyry Copper Deposits, Southwestern North America: University of Arizona Press, p. 139-184.

Einaudi, M. T. (1997). Petrogenesis of copper-bearing skarn an the Manson Valley mine, Yerington district, Nevada: ECON. GEOL., v. 72, p. 769-795.

Einaudi, M. T., Meinert, L. D. and Newberry, R. J. (1981). Skarn Deposits: Department of Applied Earth Sciences, Stanford University, Stanford, California 94305.

Goldschmidt, V. M. (1911). Die kontakmetamorphose im Kristianiagebiet: Oslo Vidensk. Skr., I., Mat-Natur v. KI., no. 1, 483 p.

Gray, R. F., Hofmaan, V. J., Bagan, R. J., and McKinley, H. L. (1968). Bishop tungsten district, California, in Ridge, J. D., ed., Ore deposits of the United States, 1933-1967 (Graton-Sales vol.): New York, Am. Inst. Mining Metall. Petroleum Engineers, p. 1531-1554.

Greenwood, J.H.(1967). Wollastonite: Stability in - mixtures and occurrence in a contact metamorphic aureole near Salmo, British Columbia: American Mineralogist, v. 52, p. 1669-1680.

Grigoryev, N.A., Sazanov, V.N., Murzin, V.V. and Gladkovskiy, (1990). Suflides as gold carriers in skarn magnetite deposit skarns and ores: Geochemical Intermational, v. 27, p. 142-146.

Haug. J. L.(1976). Geology of the Merry Widow and Kingfisher contact metasomatic skarn-magnetite deposits, Northern Vancouver Island, British Columbia: Unpub. M.S. thesis, Univ. Calgary, 117 p.

Kerrick, D.M,( 1974). Review of Metamophic Mixed Volatile (- ) Equilibria: American Mineralogist, v. 59, p. 729-762.

Kwak, T. A. P. (1987). W-Sn skarn deposits and related metamorphic skarns and granitoids: Developments in Economic Geology, No. 24, Elsevier, Amsterdam, 451 p.

Lehman, N. E. (1978). The geology and pyrometasomatic ore deposits of the Washington Camp-Duquesne district, Santa Cruz County, Arizona: Unpub. Ph.D. thesis, Univ. Arizona, 285 p.

Lindren, W. (1902). The character and genesis of certain contact deposits: American Institute of Mining Engineers, Transactions, v. 31, p. 226-224.

Meinert, L.D. (1980b). Evolution of metasomatic fluids by transport over large distances: An example from the Paymaster zinc skarn, Esmeralda Co., Nevada [abs.]: Geol. Soc. America, Abstracts with Programs, v. 12, p. 482.

Meinert, L.D. (1992). Skarns and Skarn Deposits: Department of Geology Washington State University Pullman, Washington 99164-2812 USA.

Melfos V., Voudouris P. (2017). Cenozoic metallogeny of Greece and potential for precious, critical and rare metals exploration. Ore Geology Reviews, 89, 1030-1057.

Nerkasov, I. Y. (1971). Features of tin mineralization in carbonate deposits, as in eastern Siberia: Internat. Geology Rev., v. 13, p. 1532-1542.

Newberry, R.J. (1980a). The geology and chemistry of skarn formation and tungsten depositon in the central Sierra Nevada, California: Unpub. Ph.D. thesis, Stanford Univ., 325 p.

Newberry, R.J. (1980b). The geochemistry of tungsten deposition in skarn deposits-a field and theoretical approach [abs.]: Geol. Soc. Amerika, Abstracts with Programs, v. 12, p. 492.

Newberry, R. J., and Einaudi, M. T. (1981). Tectonic and geothermical setting of tungsten skarn deposits in the Cordillera: Symposium on Tectonics and Ore Deposits, Tucson, Ariz. March 19-20, 1981, Proc.

Newberry, R.J. (1983). The formation of sabcalcic garnet in scheelite-bearing skarns: Canadian Mineralogist, v. 21, p. 529-544.

Norton, D. (1982). Fluid and heat transport phenomena typical of copper-bearing pluton environments, southeastern Arizona: in Titley, S.R., ed., Advances in Geology of Porphyry Copper Deposits: Southwestern North America: University of Arizona Press, Tucson, p. 59-72.

Pokalov, (1977). Deposits of molybdenum, in Smirnov, V. I., ed., Ore deposits of the USSR: London, Pittman, v. 3, p. 125-179.

Salemink J. and Schuiling, R.D. (1987). A two stage, transient heat and mass transfer model for the granodiorite intrusion at Seriphos, Greece, and the associated formation of contact metasomatic skarn and Fe-ore deposits, in Helgeson, H.C., ed., Chemical transport in metasomatic processes: Department Geology and

Geophysics, University of California, Berkeley, NATO Advanced Study Institutes Series C: Mathematical and Physical Sciences 218, p. 547-575.

Schmitt, H.A. (1939). The Pewabic mine, New Mexico: Geol. Soc. America Bull., v. 50, p. 777-818.

Shimazaki, H. (1980). Characteristics of skarn deposits and related acid magmatism in Japan: ECON. GEOL., v. 75, p. 173-183.

Smirnov, V. I.(1976). Geology of mineral deposits: Moscow, MIR Pub., 520 p.

Sonnevil, R. A. (1979). Evolution of skarn at Monte Cristo, Nevada: Unpub. M. S. thesis, Stanford Univ., 83 p.

Surles, T. L. (1978). Chemical and thermal variations accompanying formation of garnet skarns near Patagonia, Arizona: Unpub. M. S. thesis, Univ. Arizona, 54 p.

Takahashi, M., Aramaki, S., and Ishihara, S. (1980). Magnetite-series/ilmenite-series vs. I-type/S-type granitoids: Soc. Mining Geologists Japan Spec. Issue 8, p. 13-28.

Taylor, B. E., and O'Neil, J. R. (1977). Stable isotope studies of metasomatic Ca-Fe-Al-Si skarns and associated metamorphic and igneous rocks, Osgood Mountains, Nevada: Contr. Mineralogy Petrology, v. 63, p. 1-49.

Taylor, R. G.(1979). Geology of tin deposits: Amsterdam, Elsevier, 543 p.

Theodoridou S., Melfos V., Voudouris P., Miskovic A. (2016). Mineralogical and Geochemical Characterization of the Kimmeria Intrusion-Related Deposit, Xanthi, NE Greece. Geophysical Research Abstracts, EGU General Assembly 2016, vol. 18, EGU2016-8933, Vienna International Center (17-22 April 2016).

Tsusue, A. (1961). Contact metamorphic iron and copper ore deposits of the Kamaishi mining district, northeastern Japan: Jour. Fac. Sci. Univ. Tokyo, sec. 2, v. 13, pt.2, p.133-179.

Umpleby, J. B. (1913). Geology and ore deposits of Lemi County, Idaho: U. S. Geol. Survey Bull. 528, 182 p.

Voudouris P., Melfos V., Spry P.G., Bonsall T., Tarkian M., Economou-Eliopoulos M. (2008). Mineralogical and fluid inclusion constraints on the evolution of the Plaka intrusion-related ore system, Lavrion, Greece. Mineralogy and Petrology, 93, 79-110.

Voudouris P.C., Melfos V., Spry P.G., Baker T. (2016) Cenozoic Porphyry-Epithermal and Other Intrusion-Related Deposits in Northeastern Greece: Geological, Mineralogical and Geochemical Constraints. Society of Economic Geologists, Guidebook Series, 54, 43-82.

Wallmach, T. and Hatton, C.J. (1989). Extreme facies of contact metamorphism developed in calc-silicate xenoliths in the eastern Bushveld complex: The Canadian Mineralogist, v. 27, p. 509-523.

Yun, S. (1979). Geology and skarn ore mineralization of the Yeonhwa-Ulchin zinc-lead mining district SE Tagbaggasan region Korea: Unpub. Ph.D. thesis, Stanford Univ., 184 p.

Zharikov, V. A. (1970). Skarns: Internat. Geology Rev., v. 12, p. 541-559, 619-647, 760-775.

Χριστοφίδης, Γ.Θ. (1977). Συμβολή εις την μελέτη των πλουτωνίων πετρωμάτων της περιοχής Ξάνθης. Διδακτορική διατριβή. Τμήμα Γεωλογίας, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης.