James R. Hein Joao C. Duarte Amy Gartman 2019 <p id="sp0020"><span>Mineral formation in the modern oceans can take place over millions of years as a result precipitation from ambient ocean water, or orders of magnitude more rapidly from&nbsp;hydrothermal activity&nbsp;related to magmatic and tectonic processes. Here, we review associations between&nbsp;transform faults&nbsp;and related&nbsp;fracture zones&nbsp;and marine minerals. We define&nbsp;</span><i>marine transform faults</i><span>&nbsp;as&nbsp;strike-slip or oblique faults&nbsp;that accommodate lateral offsets along&nbsp;plate boundaries&nbsp;or shifting crustal blocks, and&nbsp;</span><i>fracture zones</i><span>&nbsp;as relicts of transform faulting extending beyond&nbsp;mid-ocean ridge&nbsp;offsets. We consider specifically the modern ocean and exclude regions where the transform or fracture has clearly not generated the&nbsp;mineral deposit, such as the Clarion-Clipperton fracture zone&nbsp;manganese nodule&nbsp;field. As a result, the summarized deposits are mainly hydrothermal in origin.</span></p><p id="sp0025"><span>Oceanic transform faulting has rarely been considered of interest for the mineralization and formation of&nbsp;ore deposits; however, there are locations in the modern oceans where transform faults and fracture zones are spatially related to mineral deposits. These occurrences suggest that transform faulting and fracture zones may be linked to mineralization at (A) intersections with other&nbsp;tectonic features, (B) where transform faults begin to resemble rifts through intra-transform&nbsp;crustal thinning, spreading, and the formation of&nbsp;pull-apart basins, and (C) as a result of&nbsp;</span>serpentinization<span>&nbsp;</span>reactions due to exposure of deep-seated rocks by fracturing and faulting.</p> application/pdf 10.1016/B978-0-12-812064-4.00005-0 en Elsevier Mineralization at oceanic transform faults and fracture zones chapter