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Journal Article

Multivariate statistics and spatial interpretation of geochemical data for assessing soil contamination by potentially toxic elements in the mining area of Stratoni, north Greece

Akis Kelepertsis, Ariadne Argyraki, Dimitris Alexakis
Published: 01 November 2006
Geochemistry: Exploration, Environment, Analysis (2006) 6 (4): 349–355.
DOI: https://doi.org/10.1144/1467-7873/05-101
...Akis Kelepertsis; Ariadne Argyraki; Dimitris Alexakis Abstract A preliminary soil survey was undertaken in the mining region of Stratoni in Chalkidiki peninsula, north Greece. The objectives of the study were to assess the levels of soil contamination with respect to average concentrations of toxic...
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Journal Article

Origin of Au-Rich Carbonate-Hosted Replacement Deposits of the Kassandra Mining District, Northern Greece: Evidence for Late Oligocene, Structurally Controlled, and Zoned Hydrothermal Systems

Chris R. Siron, John F.H. Thompson, Tim Baker, Robert Darling, Gregory Dipple
Journal: Economic Geology
Published: 01 November 2019
Economic Geology (2019) 114 (7): 1389–1414.
DOI: https://doi.org/10.5382/econgeo.4664
...Chris R. Siron; John F.H. Thompson; Tim Baker; Robert Darling; Gregory Dipple Abstract The Au-rich polymetallic massive sulfide orebodies of the Kassandra mining district belong to the intrusion-related carbonate-hosted replacement deposit class. Marble lenses contained within the Stratoni fault...
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View PDF for article title, Origin of Au-Rich Carbonate-Hosted Replacement Deposits of the Kassandra Mining District, Northern Greece: Evidence for Late Oligocene, Structurally Controlled, and Zoned Hydrothermal Systems
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Lower hemisphere, equal-area stereographic projections of fault kinematic data from the Stratoni fault zone. Fault planes and slip vectors are represented by great circles and arrows, respectively. Kinematic strain axes are plotted as squares and numbered according to the principal extension axis (1), the principal shortening axis (3), and the orthogonal intermediate axis (2). (A) Kinematic data from semibrittle and synmineral segments of the Stratoni fault zone. (B) Late- to postmineral strand of the Stratoni fault zone (solid line) and kinematically equivalent deformation from the Gomati fault zone (dashed lines). (C) Late- to postmineral Vathilakkos fault. (D) Postmineral corrugated fault segment within the Stratoni fault zone at the Madem Lakkos deposit. Kinematic criteria from the Kerdilion (K) and Strymon Valley (SV) detachment faults (Dinter, 1998) are shown as red circles for comparison. (E) Neotectonic faults within the Stratoni fault zone from this study are plotted in black with data from Pavlides and Tranos (1991) represented in red. Note the coincident position of the kinematic strain axis for each set of data.

Lower hemisphere, equal-area stereographic projections of fault kinematic d...

Published: 01 March 2018
Fig. 12. Lower hemisphere, equal-area stereographic projections of fault kinematic data from the Stratoni fault zone. Fault planes and slip vectors are represented by great circles and arrows, respectively. Kinematic strain axes are plotted as squares and numbered according to the principal
Image
Photos of representative fault styles from the Stratoni fault zone. (A) Outcrop of the ductile-brittle Stratoni fault zone above the Mavres Petres deposit. Sense of shear is normal and top-to-the-south. (B) Drill core intercept from the Piavitsa prospect of graphite-bearing quartz-biotite gneiss crosscut by a semibrittle carbonaceous shear band bounding quartz-sericite-carbonate-pyrite alteration. (C) Foliated, semibrittle fault showing well-developed pressure solution fabrics within a silicified carbonaceous matrix intergrown with pyrite, dolomite, and crystalline hydrothermal muscovite. Sense of shear is top-to-the-left. (D) Drill core intercept from the Piavitsa prospect showing typical pale-green muscovite, dolomite, and pyrite alteration replacing graphitic quartz-biotite-garnet gneiss adjacent to a mineralized strand of the Stratoni fault zone. (E) Microshear folds contained within a major strand of the Stratoni fault zone showing normal sense of shear to the south. Image taken from an outcrop above the Mavres Petres deposit. (F) Same outcrop of Stratoni fault zone exhibiting synthetic Riedel shears that crosscut the shear fabric and demonstrate normal southward sense of shear. The pale-green mineral is hydrothermal muscovite. (G) Outcrop of the postmineral segment of the Stratoni fault zone above the Madem Lakkos deposit. Microbreccia streaks and tension fractures developed on the fault surface indicate normal sense of shear in a southwest direction. (H) Outcrop of the Vathilakkos fault showing the faulted contact between granite gneiss to the east and an early Miocene black-matrix porphyry dike to the west. Abbreviations: Dol = dolomite, Ms = muscovite, Py = pyrite, Qtz = quartz, Ser = sericite.

Photos of representative fault styles from the Stratoni fault zone. (A) Out...

Published: 01 March 2018
Fig. 11. Photos of representative fault styles from the Stratoni fault zone. (A) Outcrop of the ductile-brittle Stratoni fault zone above the Mavres Petres deposit. Sense of shear is normal and top-to-the-south. (B) Drill core intercept from the Piavitsa prospect of graphite-bearing quartz
Journal Article

Structural Controls on Porphyry Au-Cu and Au-Rich Polymetallic Carbonate-Hosted Replacement Deposits of the Kassandra Mining District, Northern Greece

Chris R. Siron, David Rhys, John F.H. Thompson, Tim Baker, Theodore Veligrakis, Alfredo Camacho, Lazaros Dalampiras
Journal: Economic Geology
Published: 01 March 2018
Economic Geology (2018) 113 (2): 309–345.
DOI: https://doi.org/10.5382/econgeo.2018.4552
...Fig. 12. Lower hemisphere, equal-area stereographic projections of fault kinematic data from the Stratoni fault zone. Fault planes and slip vectors are represented by great circles and arrows, respectively. Kinematic strain axes are plotted as squares and numbered according to the principal...
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Book Chapter

Magmatic and Metallogenic Framework of Au-Cu Porphyry and Polymetallic Carbonate-Hosted Replacement Deposits of the Kassandra Mining District, Northern Greece

Author(s)
Chris R. Siron, John F. H. Thompson, Tim Baker, Richard Friedman, Pavlos Tsitsanis, Sally Russell, Scott Randall, Jim Mortensen
Book: Tectonics and Metallogeny of the Tethyan Orogenic Belt
Series: Special Publications of the Society of Economic Geologists
Publisher: Society of Economic Geologists
Published: 01 January 2016
DOI: 10.5382/SP.19.02
EISBN: 9781629499789
..., whereas amphibole or garnet fractionation is more likely for early Miocene porphyries. Carbonate replacement mineralization is hosted in marble contained within the semibrittle Stratoni fault zone. Mineralization varies along the 12-km strike length of the fault zone from Cu-bearing skarn adjacent...
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Abstract
View PDF for content titled, Magmatic and Metallogenic Framework of Au-Cu Porphyry and Polymetallic Carbonate-Hosted Replacement Deposits of the Kassandra Mining District, Northern Greece
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Abstract The Kassandra mining district in the eastern Chalkidiki Peninsula of northern Greece contains ~12 Moz Au in porphyry and polymetallic carbonate-hosted replacement sulfide orebodies. Zircon U-Pb geochronology defines two distinct magmatic episodes in the late Oligocene (27-25 Ma) and early Miocene (20-19 Ma). Both suites are characterized by high K calc-alkaline magmas with the younger early Miocene porphyritic stocks and dikes having indications of shoshonitic geochemistry. Normalized rare earth element patterns support plagio-clase fractionation among the late Oligocene suite, whereas amphibole or garnet fractionation is more likely for early Miocene porphyries. Carbonate replacement mineralization is hosted in marble contained within the semibrittle Stratoni fault zone. Mineralization varies along the 12-km strike length of the fault zone from Cu-bearing skarn adjacent to the late Oligocene Stratoni granodiorite stock westward into Au-Ag-Pb-Zn-Cu carbonate replacement deposits at Madem Lakkos and Mavres Petres. Piavitsa, at the western end of the exposed fault zone, hosts siliceous Mn-rich replacement bodies associated with crustiform Au-rich quartz-rhodochrosite veins. Structural and alteration relationships suggest that carbonate replacement mineralization is syn- to postemplacement of the late Oligocene Stratoni granodiorite stock at 25.4 ± 0.2 Ma. The Olympias Au-Ag-Pb-Zn carbonate replacement deposit, located north of the Stratoni fault zone, is hosted in marble and associated semibrittle structures. Olympias is broadly similar to the Madem Lakkos and Mavres Petres deposits. Early Miocene Au-Cu mineralization at Skouries is associated with a narrow pipe-shaped multiphase porphyry stock emplaced into the hinge zone of a regional antiform. Late Oligocene and early Miocene magmatism overlaps spatially within the district but defines distinct petrogenetic events separated by about 5 m.y. Carbonate replacement massive sulfide deposition was largely controlled by an extensional structure and receptive host rocks within the fault zone, whereas a major regional fold axis localized the Skouries porphyry system. The change in character of mineralization with time may reflect a combination of factors including preexisting structural control, magmatic-hydrothermal processes, and the availability of reactive host rocks.

Journal Article

Genesis of the Olympias carbonate-hosted Pb-Zn (Au, Ag) sulfide ore deposit, eastern Chalkidiki Peninsula, northern Greece

S. I. Kalogeropoulos, S. P. Kilias, D. C. Bitzios, M. Nicolaou, R. A. Both
Journal: Economic Geology
Published: 01 August 1989
Economic Geology (1989) 84 (5): 1210–1234.
DOI: https://doi.org/10.2113/gsecongeo.84.5.1210
... seems to have lasted until the early Tertiary and culminated in anatexis and calc-alkaline magmatism. These phenomena are represented by deformed and undeformed varieties of pegmatites-aplites, lamprophyre dikes, and the 30-Ma Stratoni granodiorite. This stage is also characterized by contact...
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Image
Simplified geologic map of the Stratoni fault zone modified after Kockel et al. (1978a, b). The inset map is located in Figure 10A. The thick black line in the Mavres Petres area corresponds to the dip-slope exposures of the Stratoni fault zone. Coordinates are displayed in the Greek Geodetic Coordinate System (GGRS 87 Greek Grid). Abbreviations: Ksp = K-feldspar.

Simplified geologic map of the Stratoni fault zone modified after Kockel e...

Published: 01 March 2018
Fig. 9. Simplified geologic map of the Stratoni fault zone modified after Kockel et al. (1978a , b ). The inset map is located in Figure 10A . The thick black line in the Mavres Petres area corresponds to the dip-slope exposures of the Stratoni fault zone. Coordinates are displayed
Image
Longitudinal view of the Stratoni fault zone displaying drill core geochemical assay data from the Madem Lakkos and Mavres Petres deposits, illustrating (A) Pb/Zn ratio and (B) Ag/Au ratio.

Longitudinal view of the Stratoni fault zone displaying drill core geochemi...

Published: 01 November 2019
Fig. 4. Longitudinal view of the Stratoni fault zone displaying drill core geochemical assay data from the Madem Lakkos and Mavres Petres deposits, illustrating (A) Pb/Zn ratio and (B) Ag/Au ratio.
Image
Kinematic evolution model for the Stratoni fault zone presented as a distribution of the principal extensional strain axes from individual fault measurements plotted in a lower-hemisphere, equal-area stereographic projection. The principal extensional strain axes for each fault population are plotted as small symbols with the mean represented by large symbols with arrows indicating the extension direction.

Kinematic evolution model for the Stratoni fault zone presented as a distri...

Published: 01 March 2018
Fig. 16. Kinematic evolution model for the Stratoni fault zone presented as a distribution of the principal extensional strain axes from individual fault measurements plotted in a lower-hemisphere, equal-area stereographic projection. The principal extensional strain axes for each fault
Image
Topographic map of the Stratoni area with pollution sources and sample locations.

Topographic map of the Stratoni area with pollution sources and sample loca...

Published: 01 November 2006
Fig. 1 Topographic map of the Stratoni area with pollution sources and sample locations.
Image
Schematic summary diagram displaying structural data and plunge orientation of carbonate replacement orebodies plotted in a lower-hemisphere, equal-area stereographic projection. (A) Measured plunge of the Olympias orebody with the Kassandra fault plotted as a great circle and the mean plunge of F2 fold hinges and (S1, S2) L2 intersection lineations plotted as square and circle, respectively. (B) Plunge of the Madem Lakkos and Mavres Petres orebodies plotted with fault surfaces defining the Stratoni fault zone indicated by great circles. Fault-slip vectors are indicated by small circles and contoured using the method of Kamb (1959). The mean plunge of F2 fold hinges from the footwall of the Stratoni fault zone is plotted as a square.

Schematic summary diagram displaying structural data and plunge orientation...

Published: 01 March 2018
plunge of F 2 fold hinges and (S 1 , S 2 ) L 2 intersection lineations plotted as square and circle, respectively. (B) Plunge of the Madem Lakkos and Mavres Petres orebodies plotted with fault surfaces defining the Stratoni fault zone indicated by great circles. Fault-slip vectors are indicated
Journal Article

Therma–Volvi–Gomati complex of the Serbo-Macedonian Massif, northern Greece: a Middle Triassic continental margin ophiolite of Neotethyan origin

Nikolay Bonev, Robert Moritz, Maria Borisova, Petyo Filipov
Published: 12 June 2018
Journal of the Geological Society (2019) 176 (5): 931–944.
DOI: https://doi.org/10.1144/jgs2017-130
... (OIB) signatures of the high-Ti rocks, whereas the low-Ti rocks are depleted with respect to MORB, suggesting melt extraction from a mantle source. U–Pb geochronology reveals Triassic crystallization of the Volvi body at 240 Ma. Ordovician to Carboniferous xenocrystic zircons were found in the Stratoni...
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View PDF for article title, Therma–Volvi–Gomati complex of the Serbo-Macedonian Massif, northern Greece: a Middle Triassic continental margin ophiolite of Neotethyan origin
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Image
Selected CL images of dated zircons. (a, b) Volvi metagabbro sample M15; (c, d) Stratoni metagabbro sample M48. Circles represent the location of spot analyses with corresponding ages given with 1σ.

Selected CL images of dated zircons. ( a , b ) Volvi metagabbro sample M15...

Published: 12 June 2018
Fig. 4. Selected CL images of dated zircons. ( a , b ) Volvi metagabbro sample M15; ( c , d ) Stratoni metagabbro sample M48. Circles represent the location of spot analyses with corresponding ages given with 1σ.
Image
Genetic model illustrating the evolution of the carbonate replacement deposits within the Kassandra mining district: (A) long-section view of the Madem Lakkos and Mavres Petres deposits and the Piavitsa prospect within the plane of the Stratoni fault zone; (B) cross-section view of the Olympias deposit.

Genetic model illustrating the evolution of the carbonate replacement depos...

Published: 01 November 2019
Fig. 13. Genetic model illustrating the evolution of the carbonate replacement deposits within the Kassandra mining district: (A) long-section view of the Madem Lakkos and Mavres Petres deposits and the Piavitsa prospect within the plane of the Stratoni fault zone; (B) cross-section view
Image
Plots of U–Pb LA-ICP-MS zircon analyses of dated rock samples. (a, b) Concordia and mean distribution diagrams, respectively, for the Volvi metagabbro sample M15; (c, d) Terra–Wasserburg and concordia diagrams, respectively, for the Stratoni metagabbro sample M40.

Plots of U–Pb LA-ICP-MS zircon analyses of dated rock samples. ( a , b ) C...

Published: 12 June 2018
Fig. 5. Plots of U–Pb LA-ICP-MS zircon analyses of dated rock samples. ( a , b ) Concordia and mean distribution diagrams, respectively, for the Volvi metagabbro sample M15; ( c , d ) Terra–Wasserburg and concordia diagrams, respectively, for the Stratoni metagabbro sample M40.
Image
Lower-hemisphere, equal-area stereographic projections of ductile structural elements subdivided by domain in the study area. Data is contoured at 3σ significance level following the method of Kamb (1959): (A-D) S1 foliation plotted as poles from planes. Best-fit great circle, orthogonal axial distributions, and plunge of the F2 fold axis are plotted as a solid line, black squares, and π symbol respectively. (E-F) S2 cleavage plotted as poles from planes. (G-H) Axial planes of F2 folds plotted as poles from planes with corresponding orientation of F2 fold hinges from the Olympias area and Stratoni fault footwall domain. (I-J) Axial planes of F2 folds plotted as poles from planes with corresponding orientation of F2 fold hinges from the Skouries area and Stratoni fault hanging-wall domain. (K-L) S1-S2 foliation intersection. (L2) Lineations plotted as lines. (M-N) S3 foliation plotted as poles from planes. Abbreviations: FW = footwall, HW = hanging wall.

Lower-hemisphere, equal-area stereographic projections of ductile structura...

Published: 01 March 2018
the Olympias area and Stratoni fault footwall domain. (I-J) Axial planes of F 2 folds plotted as poles from planes with corresponding orientation of F 2 fold hinges from the Skouries area and Stratoni fault hanging-wall domain. (K-L) S 1 -S 2 foliation intersection. (L2) Lineations plotted as lines. (M-N) S
Image
Microphotographs of the mafic–ultamafic rocks along section 2 and between sections 1 and 2. (a) Amphibolite rimming the Nea Roda peridotite (sample 2 in the Supplementary Material and Fig. 1a), and (b) Stratoni gabbro transformed into amphibolite, showing foliation-parallel amphibole (amph), plagioclase (pl) and disseminated magnetite (mt) (sample 5 in the Supplementary Material and Fig. 1a).

Microphotographs of the mafic–ultamafic rocks along section 2 and between s...

Published: 12 June 2018
Fig. 2. Microphotographs of the mafic–ultamafic rocks along section 2 and between sections 1 and 2. ( a ) Amphibolite rimming the Nea Roda peridotite (sample 2 in the Supplementary Material and Fig. 1a ), and ( b ) Stratoni gabbro transformed into amphibolite, showing foliation-parallel
Image
(A) Detailed geologic map of the Madem Lakkos and Mavres Petres deposits. Mapping was conducted at 1:5,000 scale and based largely on surface outcrops. (B) Cross section B-B’ of the Mavres Petres deposit defined by surface mapping and underground drill core. Inferred displacement on the Stratoni fault zone is shown by offset marble as indicated by dashed lines. Coordinates are displayed in the Greek Geodetic Coordinate System (GGRS 87 Greek Grid).

(A) Detailed geologic map of the Madem Lakkos and Mavres Petres deposits. M...

Published: 01 March 2018
on the Stratoni fault zone is shown by offset marble as indicated by dashed lines. Coordinates are displayed in the Greek Geodetic Coordinate System (GGRS 87 Greek Grid).
Image
Geologic map of the Kassandra mining district, modified after Kockel et al. (1977) and Siron et al. (2018). Coordinates are displayed in the Greek Geodetic Coordinate System (GGRS 87 Greek Grid). Abbreviations are as follows: As = Aspro Lakkos porphyry stock, Fs = Fisoka stock, ML = Madem Lakkos deposit, MP = Mavres Petres deposit, OL = Olympias deposit, PV = Piavitsa prospect, SK = Skouries deposit, St = Stratoni stock, Ts = Tsikara composite stock.

Geologic map of the Kassandra mining district, modified after Kockel et al...

Published: 01 November 2019
= Madem Lakkos deposit, MP = Mavres Petres deposit, OL = Olympias deposit, PV = Piavitsa prospect, SK = Skouries deposit, St = Stratoni stock, Ts = Tsikara composite stock.