All Stories

  1. Supplemental Material: Co-evolution of trace elements and life in Precambrian oceans: The pyrite edition
  2. Supplemental Material: Co-evolution of trace elements and life in Precambrian oceans: The pyrite edition
  3. Atmosphere oxygen cycling through the Proterozoic and Phanerozoic
  4. Mineralogical Features of Ore Diagenites in the Urals Massive Sulfide Deposits, Russia
  5. Biotic, geochemical and environmental changes through the early Sheinwoodian (Wenlock, Silurian) carbon isotope excursion (ESCIE), Buttington Quarry, Wales
  6. Linking gold mineralization to regional-scale drivers of mineral systems using in situ U–Pb geochronology and pyrite LA-ICP-MS element mapping
  7. Metal remobilization and ore-fluid perturbation during episodic replacement of auriferous pyrite from an epizonal orogenic gold deposit
  8. Sulfide Breccias from the Semenov-3 Hydrothermal Field, Mid-Atlantic Ridge: Authigenic Mineral Formation and Trace Element Pattern
  9. Textures and trace element composition of pyrite from the Bukit Botol volcanic-hosted massive sulphide deposit, Peninsular Malaysia
  10. Role of upper-most crustal composition in the evolution of the Precambrian ocean–atmosphere system
  11. The Boring Billion, a slingshot for Complex Life on Earth
  12. Geochemistry of shale and sedimentary pyrite as a proxy for gold fertility in the Selwyn basin area, Yukon
  13. Implications of U-Pb detrital zircon geochronology analysis for the depositional age, provenance, and tectonic setting of continental Mesozoic formations in the East Malaya Terrane, Peninsular Malaysia
  14. Does Tungsten Availability Control the Presence of Tungsten In Turbidite-Hosted Orogenic Gold Mineralization? Evidence From the Meguma and Bendigo-Ballarat Terranes
  15. Whole rock and discrete pyrite geochemistry as complementary tracers of ancient ocean chemistry: An example from the Neoproterozoic Doushantuo Formation, China
  16. Discussion: Age of the Zambian Copperbelt
  17. Erratum to: “Criteria for the detection of hydrothermal ecosystem faunas in ores of massive sulfide deposits in the Urals”
  18. Secular distribution of highly metalliferous black shales corresponds with peaks in past atmosphere oxygenation
  19. Chimneys in Paleozoic massive sulfide mounds of the Urals VMS deposits: Mineral and trace element comparison with modern black, grey, white and clear smokers
  20. Criteria for the detection of hydrothermal ecosystem faunas in ores of massive sulfide deposits in the Urals
  21. Gold- and Silver-Rich Massive Sulfides from the Semenov-2 Hydrothermal Field, 13°31.13′N, Mid-Atlantic Ridge: A Case of Magmatic Contribution?
  22. Texture and chemistry of pyrite at Chah Zard epithermal gold–silver deposit, Iran
  23. Application of pyrite trace element chemistry to exploration for SEDEX style Zn-Pb deposits: McArthur Basin, Northern Territory, Australia
  24. Covellite of the Semenov-2 hydrothermal field (13°31.13′ N, Mid-Atlantic Ridge): Enrichment in trace elements according to LA ICP MS analysis
  25. New advances in trace element geochemistry of ore minerals and accessory phases
  26. Se and In minerals in the submarine oxidation zone of a massive sulfide orebody of the molodezhnoe copper–zinc massive sulfide deposit, Southern Urals
  27. Pb-isotope compositions of the Tasik Chini VHMS deposit, Peninsular Malaysia
  28. Ocean and Atmosphere Geochemical Proxies Derived from Trace Elements in Marine Pyrite: Implications for Ore Genesis in Sedimentary Basins
  29. Sulfur isotope characteristics of the Permian VHMS deposits in Tasik Chini district, Central Belt of Peninsular Malaysia
  30. Pyrite compositions from VHMS and orogenic Au deposits in the Yilgarn Craton, Western Australia: Implications for gold and copper exploration
  31. Synsedimentary, Diagenetic, and Metamorphic Pyrite, Pyrrhotite, and Marcasite at the Homestake BIF-Hosted Gold Deposit, South Dakota, USA: Insights on Au-As Ore Genesis from Textural and LA-ICP-MS Trace Element Studies
  32. A metamorphic mineral source for tungsten in the turbidite-hosted orogenic gold deposits of the Otago Schist, New Zealand
  33. Pyrite trace element chemistry of the Velkerri Formation, Roper Group, McArthur Basin: Evidence for atmospheric oxygenation during the Boring Billion
  34. Severe selenium depletion in the Phanerozoic oceans as a factor in three global mass extinction events
  35. Multi-stage enrichment processes for large gold-bearing ore deposits
  36. Trace Element Content of Pyrite from the Kapai Slate, St. Ives Gold District, Western Australia
  37. Geochemistry, geochronology, and tectonic setting of early Permian (~290 Ma) volcanic-hosted massive sulphide deposits of the Tasik Chini district, Peninsular Malaysia
  38. Cycles of nutrient trace elements in the Phanerozoic ocean
  39. Gold in the oceans through time
  40. Geochronology of the DeGrussa volcanic-hosted massive sulphide deposit and associated mineralisation of the Yerrida, Bryah and Padbury Basins, Western Australia
  41. Trace Element Content of Sedimentary Pyrite in Black Shales
  42. Synsedimentary to Early Diagenetic Gold in Black Shale-Hosted Pyrite Nodules at the Golden Mile Deposit, Kalgoorlie, Western Australia
  43. Architecture of the Neoarchaean Jaguar VHMS deposit, Western Australia: Implications for prospectivity and the presence of depositional breaks
  44. Banded sulfide-magnetite ores of Mauk copper massive sulfide deposit, Central Urals: Composition and genesis
  45. RELEASE OF TRACE ELEMENTS THROUGH THE SUB-GREENSCHIST FACIES BREAKDOWN OF DETRITAL RUTILE TO METAMORPHIC TITANITE IN THE OTAGO SCHIST, NEW ZEALAND
  46. Geochronological Constraints on the Tropicana Gold Deposit and Albany-Fraser Orogen, Western Australia
  47. Gold accumulation in the Archaean Witwatersrand Basin, South Africa — Evidence from concentrically laminated pyrite
  48. The chemical conditions of the late Archean Hamersley basin inferred from whole rock and pyrite geochemistry with Δ33S and δ34S isotope analyses
  49. Microelectronic junctions in arsenian pyrite due to impurity and mixed sulfide heterogeneity
  50. Mineralogy and trace-element geochemistry of sulfide minerals in hydrothermal chimneys from the Upper-Cretaceous VMS deposits of the eastern Pontide orogenic belt (NE Turkey)
  51. Geology, geochemistry and metallogenesis of the Selinsing gold deposit, central Malaysia
  52. Comparison of metal enrichment in pyrite framboids from a metal-enriched and metal-poor estuary
  53. Paragenesis and composition of ore minerals in the Randalls BIF-hosted gold deposits, Yilgarn Craton, Western Australia: Implications for the timing of deposit formation and constraints on gold sources
  54. Setting the stage for the genesis of the giant Bendigo ore system
  55. Barite-rich massive sulfides from the Semenov-1 hydrothermal field (Mid-Atlantic Ridge, 13°30.87′ N): Evidence for phase separation and magmatic input
  56. Trace element content of sedimentary pyrite as a new proxy for deep-time ocean–atmosphere evolution
  57. Does pyrite act as an important host for molybdenum in modern and ancient euxinic sediments?
  58. Optimisation of laser parameters for the analysis of sulphur isotopes in sulphide minerals by laser ablation ICP-MS
  59. Evidence for an Intrabasinal Source and Multiple Concentration Processes in the Formation of the Carbon Leader Reef, Witwatersrand Supergroup, South Africa
  60. Impurity heterogeneity in natural pyrite and its relation to internal electric fields mapped using remote laser beam induced current
  61. Mineralogy of metal contaminated estuarine sediments, Derwent estuary, Hobart, Australia: implications for metal mobility
  62. Age, origin and significance of nodular sulfides in 2680Ma carbonaceous black shale of the Eastern Goldfields Superterrane, Yilgarn Craton, Western Australia
  63. Tellurium-bearing minerals in zoned sulfide chimneys from Cu-Zn massive sulfide deposits of the Urals, Russia
  64. LA-ICPMS and EPMA studies of pyrite, arsenopyrite and loellingite from the Bhukia-Jagpura gold prospect, southern Rajasthan, India: Implications for ore genesis and gold remobilization
  65. Ferruginous and manganiferous haloes around massive sulphide deposits of the Urals
  66. Diagenetic pyrite as a source for metals in orogenic gold deposits, Otago Schist, New Zealand
  67. Hydrosilicate liquids in the system Na2O-SiO2-H2O with NaF, NaCl and Ta: Evaluation of their role in ore and mineral formation at high T and P
  68. Application of Nuclear Microprobes towards Understanding Complex Ore Geo-electrochemistry
  69. Sequence and carbon isotopic stratigraphy of the Neoproterozoic Roan Group strata of the Zambian copperbelt
  70. A Carbonaceous Sedimentary Source-Rock Model for Carlin-Type and Orogenic Gold Deposits
  71. Routine quantitative multi-element analysis of sulphide minerals by laser ablation ICP-MS: Standard development and consideration of matrix effects
  72. Pyrite and Pyrrhotite Textures and Composition in Sediments, Laminated Quartz Veins, and Reefs at Bendigo Gold Mine, Australia: Insights for Ore Genesis
  73. Salt as a fluid driver, and basement as a metal source, for stratiform sediment-hosted copper deposits
  74. Study of Trace Element Zonation in Vent Chimneys from the Silurian Yaman-Kasy Volcanic-Hosted Massive Sulfide Deposit (Southern Urals, Russia) Using Laser Ablation-Inductively Coupled Plasma Mass Spectrometry (LA-ICPMS)
  75. Gold and Trace Element Zonation in Pyrite Using a Laser Imaging Technique: Implications for the Timing of Gold in Orogenic and Carlin-Style Sediment-Hosted Deposits
  76. New insights into the genesis of volcanic-hosted massive sulfide deposits on the seafloor from numerical modeling studies
  77. In situ Pb-isotope analysis of pyrite by laser ablation (multi-collector and quadrupole) ICPMS
  78. Age and pyrite Pb-isotopic composition of the giant Sukhoi Log sediment-hosted gold deposit, Russia
  79. Sulfur isotopes in sediment-hosted orogenic gold deposits: Evidence for an early timing and a seawater sulfur source
  80. Multistage Sedimentary and Metamorphic Origin of Pyrite and Gold in the Giant Sukhoi Log Deposit, Lena Gold Province, Russia
  81. Syngenetic gold in western Victoria: occurrence, age and dimensions
  82. A Basin System and Fluid-Flow Analysis of the Zn-Pb-Ag Mount Isa-Type Deposits of Northern Australia: Identifying Metal Source, Basinal Brine Reservoirs, Times of Fluid Expulsion, and Organic Matter Reactions
  83. Basin-Scale Numerical Modeling to Test the Role of Buoyancy-Driven Fluid Flow and Heat Transfer in the Formation of Stratiform Zn-Pb-Ag Deposits in the Northern Mount Isa Basin
  84. Controls on Heat Flow, Fluid Migration, and Massive Sulfide Formation of an Off-axis Hydrothermal System-- the Lau Basin Perspective
  85. Numerical Heat and Fluid-Flow Modeling of the Panorama Volcanic-Hosted Massive Sulfide District, Western Australia
  86. Lewis Ponds, a hybrid carbonate and volcanic-hosted polymetallic massive sulphide deposit, New South Wales, Australia
  87. Spatial Distribution Patterns of Sulfur Isotopes, Nodular Carbonate, and Ore Textures in the McArthur River (HYC) Zn-Pb-Ag Deposit, Northern Territory, Australia
  88. Zn–Pb–Cu volcanic-hosted massive sulphide deposits: criteria for distinguishing brine pool-type from black smoker-type sulphide deposition
  89. Numerical investigation of salinity in controlling ore-forming fluid transport in sedimentary basins: example of the HYC deposit, Northern Australia
  90. Factors controlling free thermal convection in faults in sedimentary basins: implications for the formation of zinc-lead mineral deposits
  91. Facies architecture of the Lewis Ponds carbonate and volcanic-hosted massive sulfide deposits, central western New South Wales
  92. Mass flow sedimentology within the HYC Zn?Pb?Ag deposit, Northern Territory, Australia: evidence for syn-sedimentary ore genesis
  93. Formation of massive sulfide ore deposits on the seafloor —constraints from numerical heat and fluid flow modeling
  94. Processes of ore formation in the stratiform sediment-hosted ZnPbdeposits of Northern Australia: testing the Century model
  95. Microthermometry and chemical composition of fluid inclusions from the Mt Chalmers volcanic-hosted massive sulfide deposits, central Queensland, Australia: implications for ore genesis
  96. Global comparisons of volcanic-associated massive sulphide districts
  97. Hydrothermal fluid flow models of stratiform ore genesis in the McArthur Basin, Northern Territory, Australia
  98. Carbon and Oxygen Isotope Halo in Carbonates Related to the McArthur River (HYC) Zn-Pb-Ag Deposit, North Australia:Implications for Sedimentation, Ore Genesis, and Mineral Exploration
  99. Geochemical Modeling of the Zoned Footwall Alteration Pipe,Hellyer Volcanic-Hosted Massive Sulfide Deposit, Western Tasmania,Australia
  100. Hydrothermal Alteration and Volatile Element Halos for the Rosebery K Lens Volcanic-Hosted Massive Sulfide Deposit, Western Tasmania
  101. The Alteration Box Plot: A Simple Approach toUnderstanding the Relationship between Alteration Mineralogy andLithogeochemistry Associated with Volcanic-Hosted Massive Sulfide Deposits
  102. The Spectrum of Ore Deposit Types, Volcanic Environments, Alteration Halos, and Related Exploration Vectors in Submarine Volcanic Successions: Some Examples from Australia
  103. Lithogeochemical halos and geochemical vectors to stratiform sediment hosted Zn–Pb–Ag deposits
  104. The Importance of Oxidized Brines for the Formation of Australian Proterozoic Stratiform Sediment-Hosted Pb-Zn (Sedex) Deposits
  105. A chemical model for the Devonian remobilization process in the Cambrian volcanic-hosted massive sulfide Rosebery Deposit, western Tasmania
  106. A genetic model for the H.Y.C. Deposit, Australia; based on regional sedimentology, geochemistry, and sulfide-sediment relationships
  107. Lithogeochemical halos and geochemical vectors to stratiform sediment hosted Zn–Pb–Ag deposits, 1. Lady Loretta Deposit, Queensland
  108. Introduction
  109. Design, calibration and geological application of the first operational Australian laser ablation sulphur isotope microprobe
  110. Criteria for distinguishing between gold-bearing and barren ironstones at Tennant Creek, Northern Territory, Australia
  111. Gold metallogeny and the copper-gold association of the Australian Proterozoic
  112. Microthermometry and geochemistry of fluid inclusions from the Tennant Creek gold-copper deposits: implications for ore deposition and exploration
  113. Australian volcanic-hosted massive sulfide deposits; features, styles, and genetic models
  114. Cambrian microbial and silica gel textures in silica iron exhalites from the Mount Windsor volcanic belt, Australia; their petrography, chemistry, and origin
  115. Evaluation of the source-rock control on precious metal grades in volcanic-hosted massive sulfide deposits from western Tasmania
  116. Geologic and geochemical controls on gold-rich stringer mineralization in the Que River Deposit, Tasmania
  117. Stringer system and alteration zones underlying the Hellyer volcanogenic massive sulfide deposit, Tasmania, Australia
  118. The precious metal-rich, South Hercules mineralization, western Tasmania; a possible subsea-floor replacement volcanic-hosted massive sulfide deposit
  119. The gold-rich seafloor massive sulphide deposits of Tasmania
  120. Gold exploration using lead isotopes at Tennant Creek, Australia
  121. A chemical model for the concentration of gold in volcanogenic massive sulphide deposits
  122. Distribution, mineralogy, and geochemistry of gold and silver in the north end orebody, Rosebery, Tasmania
  123. A tightly folded, gold-rich, massive sulfide deposit; Que River Mine, Tasmania
  124. Gold exploration using lead isotopes at Tennant Creek, Australia
  125. Base metal exploration of the Mount Read Volcanics, western Tasmania; Pt. III, Application of lead isotopes at Elliott Bay
  126. The volcanogenic sulfide ores at Mount Chalmers, eastern Queensland
  127. Chemical evolution and zonation of massive sulfide deposits in volcanic terrains
  128. Zonation of hydrothermal minerals at the Juno Mine, Tennant Creek Goldfield, central Australia; a reply
  129. Zonation of hydrothermal minerals at the Juno Mine, Tennant Creek Goldfield, central Australia
  130. Junoite, "wittite", and related seleniferous bismuth sulfosalts from Juno Mine, Northern Territory, Australia