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Notes: Abstract Bismuthinites and (so far as present) coexisting pyrites and/or chalcopyrites from about 50 sulfide bearing deposits were analysed S-isotopically. The natural occurrences data are genetically interpreted and compared with experimental S-isotopic fractionation values between the correspondent synthetic phases. The practicability of the bismuthinite/pyrite and bismuthinite/chalcopyrite sulfur-isotope geothermometer is discussed using results of paragenetic, petrological and fluid inclusion studies. The S-isotope fractionation of some emplectite-chalcopyrite occurrences are treated analogously on the base of theoretical fractionation calculations.

Notes: A high-temperature Guinier camera for closed and open systems used for temperatures up to 1170 K is described. As an exemplary application the decay of Co1 − xS (jaipurite) to Co3S4 (linnaeite) and Co9S8 (Co-pentlandite) at 663 and 723 K under its own vapour pressure is presented.

Notes: Summary Isothermal solid state experiments on the diffusion of Cu, Fe, Zn and In and related effects have been carried out in sphalerite single crystals. The driving force for the diffusion and corresponding reactions are chemical potential gradients which are established by differences in sulfur fugacity, oxygen fugacity and the chemical activity between sulfide powders as metal sources and receptor crystals. Studies in the system ZnS-CuInS2 show replacement rims in sphalerite produced by the formation of solid solutions between ZnS and CuInS2. These differences reflect the extent of mutual solid solution. The composition profiles of these rims at different temperatures and sulfur fugacities are calculated to diffusion coefficients for the coupled substitution of Cu+ + In3+ versus 2 Zn2+. The interdiffusion coefficients of (Cu + In) in Fe-free sphalerite at the Fe/FeS sulfur fugacity of the sources obey to the relation: D [cm2/s] = 1 * 10−3 * exp(5.53 * N) * exp((E + 2 * N)/RT) (E = -168.6 [kJ/mole]; N = mole fraction of Cu0.5In0.5S in ZnS). The interdiffusion coefficients increase with the sulfur fugacity, the Fe-content of sphalerite and in the presence of water. If Fe-bearing sphalerite crystals are used, the diffusion experiments in the ZnS-CuInS2 system at higher fS2 additionally show “chalcopyrite disease”. Using different Cu- or (Cu + Fe)-bearing sources like CUS, Cu2S, CuFeS2, Cu5 FeS4 Fe-free sphalerite and Fe-bearing sphalerites at all fS2 show replacement rims. Fe-bearing sphalerites reveal “disease” phenomena in addition to diffusion rims and replacements depending on fS2 at corresponding metal ratios in the source. Based on the experimental studies we propose the expression “diffusion induced segregations (DIS)” instead of “disease”. The mineral phases and the texture of the DIS depend on sulfur fugacity, Cu contents of the source, annealing times and temperature. The grain sizes, forms and orientation of the DIS bodies depend on the annealing temperatures and times and the defects of the sphalerite single crystals. The DIS phases chalcopyrite and bornite are formed by reaction of the diffusing Cu with the Fe contained in sphalerite which is oxidized from 2+ to 3+ within the chemical potential gradient. If the critical Fe-content of 2–3 at % is exceeded and a minimum fS2 is reached, additionally to the occurrence of DIS, Fe decreases in the primary sphalerites. If the critical Fe-content is not reached Fe can be introduced into the sphalerite. These different phenomena can be directly correlated to natural occurrences. Following our experimental studies and descriptions of natural parageneses the “chalcopyrite disease” has to be extended to corresponding phenomena of bornite and digenite.