The study of Mineralogy, geochemistry and fluid inclusions in the Alcheh-Qeshlaq mineral occurrence, Varzaghan, East Azerbaijan Province

Document Type : Original Article

10.22128/ijcm.2025.2972.0

Abstract

The ore-bearing veins at Alcheh-Qeshlaq is located in north of Varzeghan and is a part of the Ahar-Jolfa metallogenic belt. The main rocks hosting the ore-bearing siliceous and barite veins in this area chiefly include dacite, rhyolite, rhyo-dacite, and andesite of Eocene age which were intruded by hypabyssal intrusive bodies. This system with creation of various types of alterations (silicic, argillic and propylitic) commenced its activity in the form hydrothermal breccias and followed by the formation of infiltration of siliceous and sulfide-containing fluids. Mineralization occurred in two separate stages of hypogene and supergene along the fracture zones, veins, and breccia zones in the form of replacement, dissemination, vein-veinlets. Geochemical investigations on these veins indicate the presence of gold, lead, zinc, and copper in them. Minerals like pyrite, sphalerite, galena, arsenopyrite, chalcopyrite, and tetrahedrite along with quartz and barite gangues formed during hypogene stage while the secondary minerals including chalcocite, malachite, azurite, goethite, and hematite were developed during supergene stage. Among these, gold shows high correlation with silver and arsenic. Micro-thermometric analysis in quartz, barite, and sphalerite crystals shows that the homogenization temperatures range from 140ºC to 394ºC and the salinities vary from 5 to 20.9 wt% NaCl eq. Evidences like the coexistence of mono-phase gas and liquid-rich 2-phase fluid inclusions and hydrothermal breccia textures are indicative of boiling process and pressure fall along with deposition of sulfide minerals. Mineralogical and field evidences show that the alteration and mineralization system at Alcheh-Qeshlaq are of epithermal type.

Keywords

References

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Iranian Journal of Crystallography and Mineralogy
Volume 33, Issue 4 - Serial Number 100
January 2026
Pages 633-652

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  • Receive Date: 05 April 2025
  • Revise Date: 21 April 2025
  • Accept Date: 30 April 2025

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