1 Introduction.- 1.1 Preamble: Potassic Igneous Rocks and Their Importance.- 1.2 Scope of Book.- 2 Definitions and Nomenclature.- 2.1 Historical Perspective of Potassic Igneous Rocks.- 2.2 Potassic Igneous Rocks as an Umbrella Term.- 2.3 Shoshonites.- 2.4 Shoshonitic and Alkaline Lamprophyres.- 2.5 Ultrapotassic Rocks.- 2.5.1 Introduction.- 2.5.2 Lamproites.- 2.5.3 Kamafugites.- 2.5.4 Orogenic Ultrapotassic Rocks.- 2.6 Group II Kimberlites.- 2.7 Potassic Igneous Rocks as Considered in this Book.- 2.8 Field Recognition of Potassic Igneous Rocks.- 3 Tectonic Settings of Potassic Igneous Rocks.- 3.1 Introduction.- 3.2 Tectonic Settings of Potassic Igneous Rocks.- 3.2.1 Continental Arc.- 3.2.2 Postcollisional Arc.- 3.2.3 Oceanic (Island) Arc.- 3.2.4 Within-Plate.- 3.2.5 Problems with Tectonic Classifications.- 3.3 History of Discrimination of Tectonic Setting by Geochemical Means.- 3.4 Erection of Databases SHOSH1 and SHOSH2.- 3.5 Discrimination of Tectonic Setting by Multivariate Statistical Methods.- 3.6 Discrimination via Simple Geochemical Diagrams..- 3.7 Theoretical Basis for Discrimination between Potassic Igneous Rocks in Different Tectonic Settings.- 3.8 Conclusions.- 4 Selected Type-Localities of Potassic Igneous Rocks from the Five Tectonic Settings.- 4.1 Roman Province (Italy): Example from a Continental Arc Setting.- 4.1.1 Introduction.- 4.1.2 Regional Geology.- 4.1.3 Mineralogy and Petrography of the Potassic Igneous Rocks.- 4.1.4 Geochemistry of the Potassic Igneous Rocks.- 4.2 Kreuzeck Mountains, Eastern Alps (Austria): Example from a Postcollisional Arc Setting.- 4.2.1 Introduction.- 4.2.2 Regional Geology.- 4.2.3 Mineralogy and Petrography of the Lamprophyres.- 4.2.4 Geochemistry of the Lamprophyres.- 4.3 Northern Mariana Arc (West Pacific): Example from an Initial Oceanic Arc Setting.- 4.3 1 Introduction.- 4.3.2 Regional Geology.- 4.3.3 Mineralogy and Petrography of the Potassic Igneous Rocks.- 4.3.4 Geochemistry of the Potassic Igneous Rocks.- 4.4 Vanuatu (Southwest Pacific): Example from a Late OceanicArc Setting.- 4.4.1 Introduction.- 4.4.2 Regional Geology.- 4.4.3 Mineralogy and Petrography of the Potassic Igneous Rocks.- 4.4.4 Geochemistry of the Potassic Igneous Rocks.- 4.5 African Rift Valley (Uganda, Rwanda, Zaire): Example from a Within-Plate Setting.- 4.5.1 Introduction.- 4.5.2 Regional Geology.- 4.5.3 Mineralogy and Petrography of the Potassic Igneous Rocks.- 4.5.4 Geochemistry of the Potassic Igneous Rocks.- 5 Primary Enrichment of Precious Metals in Potassic Igneous Rocks.- 5.1 Introduction.- 5.2 Theoretical Discussion.- 5.3 Case Study: Potassic Alkaline Lamprophyres with Elevated Gold Concentrations from the Karinya Syncline, South Australia.- 5 3 1 Introduction.- 5.3.2 Regional Geology and Tectonic Setting.- 5.3.3 Mineralization in the Vicinity of the Lamprophyres.- 5.3.4 Nature of the Lamprophyres.- 5.3.5 Petrology and Geochemistry of the Lamprophyres.- 5.3.6 Precious Metal Abundance and Significance.- 5.4 Comparison of Precious Metal Abundances for Lamprophyres from the Karinya Syncline and Kreuzeck Mountains.- 6 Direct Associations between Potassic Igneous Rocks and Gold-Copper Deposits.- 6.1 Direct Associations in Specific Tectonic Settings: Introduction.- 6.2 Erection of Database GOLD 1.- 6.3 Late Oceanic Arc Associations.- 6.3.1 Ladolam Gold Deposit, Lihir Island, Papua New Guinea.- 6.3.2 Emperor Gold Deposit, Viti Levu, Fiji.- 6.3.3 Goonumbla Copper-Gold Deposit, New South Wales, Australia.- 6.4 Continental Arc Associations.- 6.4.1 Bingham Copper Deposit, Utah, USA.- 6.4.2 Twin Buttes Copper Deposit, Arizona, USA.- 6.4.3 Chilean Andes.- 6.5 Postcollisional Arc Associations.- 6.5.1 Grasberg Copper-Gold Deposit, Indonesia.- 6.5.2 Porgera Gold Deposit, Papua New Guinea.- 6.6 Synthesis of Direct Genetic Associations.- 7 Indirect Associations between Lamprophyres and Gold-Copper Deposits.- 7.1 Introduction.- 7.2 Shoshonitic Lamprophyres with Elevated Gold Concentrations from the Goodall Gold Deposit, Northern Territory, Australia (Proterozoic).- 7.2.1 Introduction.- 7.2.2 Regional Geology.- 7.2.3 Nature of Mesothermal Gold Mineralization.- 7.2.4 Mineralogy of the Lamprophyres.- 7.2.5 Geochemistry of the Lamprophyres.- 7.2.6 Direct or Indirect Link between Potassic Lamprophyres and Mineralization.- 7.3 Shoshonitic Lamprophyres from the Tom's Gully Gold Deposit, Northern Territory, Australia (Proterozoic).- 7.3.1 Introduction.- 7.3.2 Regional Geology.- 7.3.3 Nature of Mesothermal Gold Mineralization.- 7.3.4 Petrology of the Lamprophyres.- 7.3.5 Indirect Link between Lamprophyres and Gold Mineralization.- 7.4 Shoshonitic Lamprophyres from the Eastern Goldfields, Yilgarn Block, Western Australia (Archaean).- 7.4.1 Introduction.- 7.4.2 Regional Geology.- 7.4.3 Nature of Mesothermal Gold Mineralization.- 7.4.4 Lamprophyres and Their Association with Mineralization.- 7.4.5 Petrology and Geochemistry of the Lamprophyres.- 7.5 Shoshonitic Lamprophyres from the Superior Province, Canada (Archaean).- 7.5.1 Introduction.- 7.5.2 Nature of Mesothermal Gold Mineralization.- 7.5.3 Lamprophyres and Their Association with Mineralization.- 7.5.4 Petrology and Geochemistry of the Lamprophyres.- 7.6 Indirect Link between Lamprophyres and Archaean Gold Mineralization.- 7.7 Synthesis of Indirect Associations.- 8 Halogen Contents of Mineralized versus Unmineralized Potassic Igneous Rocks.- 8.1 Introduction.- 8.2 Erection of Database MICA 1.- 8.3 Discussion.- 8.3.1 Behaviour of Halogens in Magmatic Hydrothermal Systems.- 8.3.2 Halogen Contents of Mica in Potassic Igneous Rocks.- 8.3.3 Significance of Halogen Contents.- 9 Implications for Mineral Exploration.- 9.1 Introduction.- 9.2 Area Selection.- 9.2.1 Composition of Host Rocks.- 9.2.2 Tectonic Setting.- 9.3 Prospect Evaluation.- 9.3.1 Favourable Tectonic Elements on the Prospect Scale.- 9.3.2 High Oxidation State of the Magmas.- 9.3.3 Elevated Halogen Contents of the Magmas.- 10 Characteristics of Gold-Copper Deposits Associated with Potassic Igneous Rocks.- 10.1 Abbreviations.- 10.2 Tables of Deposit Characteristics.- 10.2.1 Andacollo, Chile.- 10.2.2 Bingham, Utah, USA.- 10.2.3 Choquelimpie, Chile.- 10.2.4 Emperor, Vitu Levu, Fiji.- 10.2.5 Goonumbla, New South Wales, Australia.- 10.2.6 Grasberg, Indonesia.- 10.2.7 Kirkland Lake, Superior Province, Canada.- 10.2.8 Ladolam, Lihir Island, Papua New Guinea.- 10.2.9 Maricunga Belt, Chile..- 10.2.10 Mount Kare, Papua New Guinea..- 10.2.11 Mount Morgans, Eastern Goldfields, Western Australia.- 10.2.12 Porgera, Papua New Guinea.- 10.2.13 Tom's Gully, Northern Territory, Australia.- 10.2.14 Twin Buttes, Arizona, USA.- 10.2.15 Wiluna, Eastern Goldfields, Western Australia.- References.

In recent years, there has been increasing interest from geoscientists in potassic ig­ neous rocks. Academic geoscientists have been interested in their petrogenesis and their potential value in defining the tectonic setting of the terranes into which they were intruded, and exploration geoscientists have become increasingly interested in the association of these rocks with major epithermal gold and porphyry gold-copper deposits. Despite this current interest, there is no comprehensive textbook that deals with these aspects of potassic igneous rocks. This book redresses this situation by elucidating the characteristic features of potassic (high-K) igneous rocks, erecting a hierarchical scheme that allows interpre­ tation of their tectonic setting using whole-rock geochemistry, and investigating their associations with a variety of gold and copper-gold deposits, worldwide. About two­ thirds of the book is based on a PhD thesis by Dr Daniel Muller which was produced at the Key Centre for Strategic Mineral Deposits within the Department of Geology and Geophysics at The University of Western Australia under the supervision of Professor David Groves, the late Dr Nick Rock, Professor Eugen Stumpf!, Dr Wayne Taylor, and Dr Brendon Griffin. The remainder of the book has been compiled from the literature using the collective experience of the two authors. The book is dedi­ cated to the memory of Dr Rock who initiated the research project but died before its completion.